John A. Batsis, MD

Issue

Journal of Hospital Medicine - 4(8)

Publications

Page Number

E1-E9

Legacy Keywords

elderly, hip fractures, inpatient, medical complications, obesity, postoperative

Read more about BMI and Postoperative Complications

Sections

Author(s)

L. Joseph Melton, MD, MPH

Paul M. Huddleston, MD, MSc

Dirk R. Larson, MS

Rachel E. Gullerud, BS

M. Molly McMahon, MD

Author(s)

L. Joseph Melton, MD, MPH

Paul M. Huddleston, MD, MSc

Dirk R. Larson, MS

Rachel E. Gullerud, BS

M. Molly McMahon, MD

Article PDF

Article PDF

Patients and Methods

Table 1.Definitions of Postoperative Noncardiac Complications
Definition	Symptom
Abbreviations: PaCO₂, pressure of carbon dioxide; SaO₂, oxygen saturation.
Gastrointestinal
Ileus	Dilated loops of bowel on X‐ray; documented ileus with nausea, vomiting, no stool or inability to take oral intake
Gastrointestinal bleeding	Sudden appearance of frank blood on nasogastric lavage or by rectum AND a decrease in hemoglobin of 2 g/dL or greater with no other suspected source of ongoing blood loss
Infectious
Pneumonia	New infiltrate on chest x‐ray plus 2 of the following 3 findings: temperature >38C, elevated white cell count, sputum pathogen that requires antibiotic treatment
Bacteremia/sepsis	Localized infection with positive blood culture for the same pathogen AND chills, rigors, fever, elevated white cell count AND intravenous antibiotic treatment
Urinary tract infection	Pyuria symptoms
	Positive gram stain symptoms
Wound
Cellulitis	As documented in physician's note of a superficial skin infection
Neurologic
Cerebral eventhypoxia, thrombosis or hemorrhage	New neurologic dysfunction (hemiplegia, hemianesthesia, hemianopia, aphasia, or unconsciousness) postoperatively
Transient ischemic attack	Any neurologic dysfunction resolving within a 24‐hour period
Delirium	Positive Confusion Assessment Method³⁸
Renal/metabolic
Renal failure	A doubling of baseline value of creatinine; serum creatinine >3.0 mg/dL; acute need for dialysis
Dehydration	As documented in the physician's note
Electrolyte abnormalities	Any laboratory evidence of abnormal electrolytes compared to normal
Respiratory

Respiratory failure	Need for intubation and ventilation >24 hours postoperatively; need for reintubation and ventilation after 1 hour postoperatively
Respiratory depression	Respiratory arrest; PaCO₂ >60 mmHg that provider believed was associated with narcotics
Pulmonary hypoxemia	SaO₂ <90% with or without supplemental oxygen; supplemental oxygen >24 hours
Vascular
Deep vein thrombosis	Positive lower extremity venous Doppler
Pulmonary embolism	Acute onset dyspnea and tachycardia, increased central venous pressure AND (positive ventilation/perfusion scan OR positive computed tomography OR positive pulmonary angiogram)
Other
Fractures	Any in‐hospital documented fracture of any bone
Falls	Patients descending to the ground from any position unintentionally

Results

Table 2.Baseline Characteristics of 1180 Olmsted County, Minnestoa, Residents Undergoing Urgent Hip Fracture Repair, 1988‐2002, by Body Mass Index Classification
Variable	Underweight (<18.5 kg/m²) n = 184 n (%)	Normal (18.5‐24.9 kg/m²) n = 640 n (%)	Overweight (25‐29.9 kg/m²) n = 251 n (%)	Obese (30 kg/m²) n = 105 n (%)	P Value*
NOTE: Continuous variables are represented as mean standard deviations. Discrete variables are represented as number (%). Table adapted with permission from Batsis et al.15 Abbreviations: ACE, angiotensin converting enzyme inhibitor; ALC, assisted living center; ARB, angiotensin receptor blocker; ASA, American Society of Anesthesia; COPD, chronic obstructive pulmonary disease; SNF, skilled nursing facility. * P values are Kruskal‐Wallis tests for continuous variables and either Fisher Exact or Cochran‐Mantel‐Haenszel values for discrete variables. There were 2 patients with missing data. There was 1 patient with missing data. There were 5 patients with missing data.
Age (years)	84.8 8.0	85.0 7.2	83.1 7.3	80.7 7.4	<0.001
Female sex	171 (92.9)	525 (82)	177 (70.5)	76 (72.4)	<0.001
Preadmission residence
ALC/SNF	79 (42.9)	250 (39.1)	83 (33.1)	36 (34.3)	0.024
Home	105 (57.1)	390 (60.9)	168 (66.9)	69 (65.7)
Functional status
Dependent	25 (13.6)	80 (12.5)	24 (9.6)	7 (6.7)	0.044
Walking independently	159 (86.4)	560 (87.5)	226 (90.4)	97 (93.3)
History of
Hypertension	84 (45.7)	374 (58.4)	159 (63.3)	70 (66.7)	<0.001
Diabetes	9 (4.9)	71 (11.1)	30 (12)	30 (28.6)	<0.001
Cerebrovascular disease	40 (21.7)	175 (27.3)	77 (30.7)	33 (31.4)	0.028
Myocardial infarction	44 (23.9)	140 (21.9)	61 (24.3)	36 (34.3)	0.106
Congestive heart failure	48 (26.1)	150 (23.4)	76 (30.3)	44 (41.9)	0.003
Atrial fibrillation/flutter	49 (26.6)	118 (18.4)	57 (22.7)	26 (24.8)	0.985
Chronic renal insufficiency	11 (6)	64 (10)	34 (13.5)	20 (19)	<0.001
Dementia	63 (34.2)	233 (36.4)	74 (29.5)	26 (24.8)	0.031
Obstructive sleep apnea	2 (1.1)	5 (0.8)	5 (2.0)	6 (5.7)	0.005
COPD	41 (22.3)	100 (15.6)	32 (12.7)	17 (16.2)	0.032
Asthma	13 (7.1)	47 (7.3)	18 (7.2)	12 (11.4)	0.395
COPD or asthma	49 (26.6)	133 (20.8)	45 (17.9)	23 (21.9)	0.093
Pulmonary embolism or deep vein thrombosis	9 (4.9)	21 (3.3)	21 (8.4)	17 (16.2)	<0.001
Osteoporosis	77 (41.8)	253 (39.5)	73 (29.1)	31 (29.5)	<0.001
Collagen vascular diseases	10 (5.4)	29 (4.5)	9 (3.6)	12 (11.4)	0.34
Cancer	61 (33.2)	169 (26.4)	75 (29.9)	32 (30.5)	0.88
Lymphoma	2 (1.1)	3 (0.5)	2 (0.8)	2 (1.9)	0.25
Leukemia	2 (1.1)	3 (0.5)	1 (0.4)	1 (1)
Major surgery within 90 days	3 (1.6)	10 (1.6)	8 (3.2)	3 (2.9)	0.366
ASA class
I or II	19 (10.4)	93 (14.5)	46 (18.3)	12 (11.4)	0.144
III, IV, or V	164 (89.6)	547 (85.5)	205 (81.7)	93 (88.6)
Type of anesthesia
General	134 (72.8)	477 (74.5)	192 (76.5)	84 (80)
Other (spinal, epidural, local, combination)	50 (27.2)	163 (25.5)	59 (23.5)	21 (20)	0.16
Admission medications
Insulin	2 (1.1)	18 (2.8)	11 (4.4)	17 (16.2)	<0.001
Aspirin	50 (27.2)	197 (30.8)	82 (32.7)	37 (35.2)	0.126
Beta‐blockers	18 (9.8)	90 (14.1)	50 (19.9)	25 (23.8)	<0.001
ACE/ARB	32 (17.4)	95 (14.8)	55 (21.9)	28 (26.7)	0.009
Calcium‐channel blocker	26 (14.1)	104 (16.3)	39 (15.5)	21 (20)	0.38
Intensive care unit stay	63 (34.2)	154 (24.1)	61 (24.3)	30 (28.6)	0.16
Length of stay, days	10.3 (9.7)	9.7 (6.8)	10.2 (7.6)	11.1 (8.6)	0.10
Discharge destination
Home	20 (10.9)	65 (10.2)	43 (17.1)	19 (18.1)
ALC/nursing home	146 (79.8)	547 (85.5)	199 (79.3)	83 (79)	<0.001
In‐hospital death	17 (9.3)	28 (4.4)	9 (3.6)	3 (2.9)

Table 3.Univariate Unadjusted Inpatient Noncardiac Complication Rates Among 1,180 Olmsted County, Minnesota, Residents Undergoing Urgent Hip Fracture Repair, 1988‐2002
	Overall Cohort n (%)	Underweight (<18.5 kg/m²) n = 184 n (%)	Normal (18.5‐24.9 kg/m²) n = 640 n (%)	Overweight (25‐29.9 kg/m²) n = 251 n (%)	Obese (30 kg/m²) n = 105 n (%)	P Value
NOTE: All values are represented as count (proportion) for categorical variables; counts are the number of cases that fulfilled the criteria for a given inpatient complication. P values represent a Fisher Exact or Cochran‐Mantel‐Haenszel; P < 0.05 is significant.
Gastrointestinal
Ileus	38 (3.2)	1 (0.5)	21 (3.3)	12 (4.8)	4 (3.8)	0.03
Gastrointestinal bleeding	21 (1.8)	1 (0.5)	11 (1.7)	6 (2.4)	3 (2.9)	0.35
Infectious
Pneumonia	69 (5.8)	12 (6.5)	39 (6.1)	14 (5.6)	4 (3.8)	0.51
Bacteremia/sepsis	8 (0.7)	1 (0.5)	2 (0.3)	5 (2.0)	0 (0)	0.06
Urinary tract infection	84 (7.1)	12 (6.5)	47 (7.3)	15 (6)	10 (9.5)	0.78
Wound
Cellulitis
Neurological
Cerebral event‐hypoxia, thrombosis or hemorrhage	15 (1.3)	1 (0.5)	6 (0.9)	6 (2.4)	2 (1.9)	0.21
Transient ischemic attack
Delirium	199 (16.9)	40 (21.7)	106 (16.6)	36 (14.3)	17 (16.2)	0.08
Renal/metabolic
Renal failure	19 (1.6)	3 (1.6)	9 (1.4)	5 (2.0)	2 (1.9)	0.82
Dehydration
Electrolyte abnormalities
Respiratory
Respiratory failure	53 (4.5)	10 (5.4)	23 (3.6)	15 (6.0)	5 (4.8)	0.61
Respiratory depression	23 (1.9)	3 (1.6)	11 (1.7)	8 (3.2)	1 (1.0)	0.50
Pulmonary hypoxemia	157 (13.3)	33 (17.9)	78 (12.2)	34 (13.5)	12 (11.4)	0.22
Vascular
Deep vein thrombosis	5 (0.4)	0 (0)	2 (0.3)	3 (1.2)	0 (0)	0.24
Pulmonary embolism	16 (1.4)	3 (1.6)	7 (1.1)	5 (2.0)	1 (1.0)	0.65
Other
Fractures	6 (0.5)	1 (0.5)	5 (0.8)	0 (0)	0 (0)	0.57
Falls

Table 4.Multivariable Analysis for Inpatient Medical Complications Among 1,180 Olmsted County, Minnesota, Residents Undergoing Urgent Hip Fracture Repair, 1988‐2002
	Underweight <18.5 kg/m² n = 184* n (%)	Normal 18.5‐24.9 kg/m² n = 640* n (%)	Overweight 25‐29.9 kg/m² n = 251* n (%)	Obese 30 kg/m² n = 105* n (%)	Age	Male Sex	Surgical Year	ASA Score, III‐V vs. I/II	COPD/ Asthma
NOTE: Each row represents a separate multivariable logistic regression analysis. All values are listed as hazard ratios (95% confidence intervals). Abbreviations: ASA, American Society of Anesthesia; BMI, body mass index; COPD, chronic obstructive pulmonary disease. * The number of observed number of fractures in this category. Model 1: Effect of BMI category (underweight, normal, overweight, and obese) on overall noncardiac inpatient complication rate adjusted, a priori individually, for age, sex, surgical year, and ASA score univariately. P < 0.05. Model 2: Effect of BMI category (underweight, normal, overweight, and obese) on overall noncardiac inpatient complication rate, after adjusting for age, sex, surgical year, and ASA class. ∥ Model 3: Model evaluating other potential risk factors, including baseline demographic and baseline clinical variables that were significant (P < 0.05) univariately using stepwise selection. Model includes BMI as a categorical variable (underweight, normal, overweight, and obese), adjusted for age, sex, surgical year, and ASA class. Model 4: Model evaluating other potential risk factors, including baseline demographic and baseline clinical variables that were significant (P < 0.05) univariately using stepwise selection. Model 3 is similar to this, but does not force BMI in.
Model 1a	1.25 (0.89‐1.74)	Referent	0.97 (0.72‐1.31)	1.16 (0.76‐1.76)
Model 1b	1.26 (0.90‐1.77)	Referent	1.05 (0.77‐1.43)	1.38 (0.90‐2.13)	1.04 (1.02‐1.06)
Model 1c	1.30 (0.93‐1.83)	Referent	0.93 (0.68‐1.26)	1.12 (0.73‐1.71)		1.47 (1.09‐1.98)
Model 1d	1.28 (0.91‐1.79)	Referent	0.97 (0.71‐1.31)	1.13 (0.74‐1.73)			1.03 (1.00‐1.06)
Model 1e	1.23 (0.88‐1.72)	Referent	1.00 (0.73‐1.36)	1.13 (0.74‐1.73)				2.22 (1.52‐3.24)
Model 2	1.33 (0.95‐1.88)	Referent	1.01 (0.74‐1.38)	1.28 (0.82‐1.98)	1.04 (1.02‐1.06)	1.59 (1.17‐2.17)	1.02 (0.99‐1.05)	1.89 (1.28‐2.79)
Model 3∥	1.30 (0.92‐1.84)	Referent	1.04 (0.76‐1.42)	1.30 (0.84‐2.02)	1.05 (1.03‐1.06)	1.52 (1.11‐2.07)	1.02 (0.99‐1.05)	1.77 (1.20‐2.62)	1.58 (1.17‐2.12)
Model 4					1.05 (1.03‐1.06)	1.49 (1.10‐2.02)		1.84 (1.25‐2.71)	1.58 (1.18‐2.12)

Discussion

Conclusions

Acknowledgements

The authors thank Donna K. Lawson, LPN, Kathy Wolfert, and Cherie Dolliver, for their assistance in data collection and management.

Patients and Methods

Table 1.Definitions of Postoperative Noncardiac Complications
Definition	Symptom
Abbreviations: PaCO₂, pressure of carbon dioxide; SaO₂, oxygen saturation.
Gastrointestinal
Ileus	Dilated loops of bowel on X‐ray; documented ileus with nausea, vomiting, no stool or inability to take oral intake
Gastrointestinal bleeding	Sudden appearance of frank blood on nasogastric lavage or by rectum AND a decrease in hemoglobin of 2 g/dL or greater with no other suspected source of ongoing blood loss
Infectious
Pneumonia	New infiltrate on chest x‐ray plus 2 of the following 3 findings: temperature >38C, elevated white cell count, sputum pathogen that requires antibiotic treatment
Bacteremia/sepsis	Localized infection with positive blood culture for the same pathogen AND chills, rigors, fever, elevated white cell count AND intravenous antibiotic treatment
Urinary tract infection	Pyuria symptoms
	Positive gram stain symptoms
Wound
Cellulitis	As documented in physician's note of a superficial skin infection
Neurologic
Cerebral eventhypoxia, thrombosis or hemorrhage	New neurologic dysfunction (hemiplegia, hemianesthesia, hemianopia, aphasia, or unconsciousness) postoperatively
Transient ischemic attack	Any neurologic dysfunction resolving within a 24‐hour period
Delirium	Positive Confusion Assessment Method³⁸
Renal/metabolic
Renal failure	A doubling of baseline value of creatinine; serum creatinine >3.0 mg/dL; acute need for dialysis
Dehydration	As documented in the physician's note
Electrolyte abnormalities	Any laboratory evidence of abnormal electrolytes compared to normal
Respiratory

Respiratory failure	Need for intubation and ventilation >24 hours postoperatively; need for reintubation and ventilation after 1 hour postoperatively
Respiratory depression	Respiratory arrest; PaCO₂ >60 mmHg that provider believed was associated with narcotics
Pulmonary hypoxemia	SaO₂ <90% with or without supplemental oxygen; supplemental oxygen >24 hours
Vascular
Deep vein thrombosis	Positive lower extremity venous Doppler
Pulmonary embolism	Acute onset dyspnea and tachycardia, increased central venous pressure AND (positive ventilation/perfusion scan OR positive computed tomography OR positive pulmonary angiogram)
Other
Fractures	Any in‐hospital documented fracture of any bone
Falls	Patients descending to the ground from any position unintentionally

Results

Table 2.Baseline Characteristics of 1180 Olmsted County, Minnestoa, Residents Undergoing Urgent Hip Fracture Repair, 1988‐2002, by Body Mass Index Classification
Variable	Underweight (<18.5 kg/m²) n = 184 n (%)	Normal (18.5‐24.9 kg/m²) n = 640 n (%)	Overweight (25‐29.9 kg/m²) n = 251 n (%)	Obese (30 kg/m²) n = 105 n (%)	P Value*
NOTE: Continuous variables are represented as mean standard deviations. Discrete variables are represented as number (%). Table adapted with permission from Batsis et al.15 Abbreviations: ACE, angiotensin converting enzyme inhibitor; ALC, assisted living center; ARB, angiotensin receptor blocker; ASA, American Society of Anesthesia; COPD, chronic obstructive pulmonary disease; SNF, skilled nursing facility. * P values are Kruskal‐Wallis tests for continuous variables and either Fisher Exact or Cochran‐Mantel‐Haenszel values for discrete variables. There were 2 patients with missing data. There was 1 patient with missing data. There were 5 patients with missing data.
Age (years)	84.8 8.0	85.0 7.2	83.1 7.3	80.7 7.4	<0.001
Female sex	171 (92.9)	525 (82)	177 (70.5)	76 (72.4)	<0.001
Preadmission residence
ALC/SNF	79 (42.9)	250 (39.1)	83 (33.1)	36 (34.3)	0.024
Home	105 (57.1)	390 (60.9)	168 (66.9)	69 (65.7)
Functional status
Dependent	25 (13.6)	80 (12.5)	24 (9.6)	7 (6.7)	0.044
Walking independently	159 (86.4)	560 (87.5)	226 (90.4)	97 (93.3)
History of
Hypertension	84 (45.7)	374 (58.4)	159 (63.3)	70 (66.7)	<0.001
Diabetes	9 (4.9)	71 (11.1)	30 (12)	30 (28.6)	<0.001
Cerebrovascular disease	40 (21.7)	175 (27.3)	77 (30.7)	33 (31.4)	0.028
Myocardial infarction	44 (23.9)	140 (21.9)	61 (24.3)	36 (34.3)	0.106
Congestive heart failure	48 (26.1)	150 (23.4)	76 (30.3)	44 (41.9)	0.003
Atrial fibrillation/flutter	49 (26.6)	118 (18.4)	57 (22.7)	26 (24.8)	0.985
Chronic renal insufficiency	11 (6)	64 (10)	34 (13.5)	20 (19)	<0.001
Dementia	63 (34.2)	233 (36.4)	74 (29.5)	26 (24.8)	0.031
Obstructive sleep apnea	2 (1.1)	5 (0.8)	5 (2.0)	6 (5.7)	0.005
COPD	41 (22.3)	100 (15.6)	32 (12.7)	17 (16.2)	0.032
Asthma	13 (7.1)	47 (7.3)	18 (7.2)	12 (11.4)	0.395
COPD or asthma	49 (26.6)	133 (20.8)	45 (17.9)	23 (21.9)	0.093
Pulmonary embolism or deep vein thrombosis	9 (4.9)	21 (3.3)	21 (8.4)	17 (16.2)	<0.001
Osteoporosis	77 (41.8)	253 (39.5)	73 (29.1)	31 (29.5)	<0.001
Collagen vascular diseases	10 (5.4)	29 (4.5)	9 (3.6)	12 (11.4)	0.34
Cancer	61 (33.2)	169 (26.4)	75 (29.9)	32 (30.5)	0.88
Lymphoma	2 (1.1)	3 (0.5)	2 (0.8)	2 (1.9)	0.25
Leukemia	2 (1.1)	3 (0.5)	1 (0.4)	1 (1)
Major surgery within 90 days	3 (1.6)	10 (1.6)	8 (3.2)	3 (2.9)	0.366
ASA class
I or II	19 (10.4)	93 (14.5)	46 (18.3)	12 (11.4)	0.144
III, IV, or V	164 (89.6)	547 (85.5)	205 (81.7)	93 (88.6)
Type of anesthesia
General	134 (72.8)	477 (74.5)	192 (76.5)	84 (80)
Other (spinal, epidural, local, combination)	50 (27.2)	163 (25.5)	59 (23.5)	21 (20)	0.16
Admission medications
Insulin	2 (1.1)	18 (2.8)	11 (4.4)	17 (16.2)	<0.001
Aspirin	50 (27.2)	197 (30.8)	82 (32.7)	37 (35.2)	0.126
Beta‐blockers	18 (9.8)	90 (14.1)	50 (19.9)	25 (23.8)	<0.001
ACE/ARB	32 (17.4)	95 (14.8)	55 (21.9)	28 (26.7)	0.009
Calcium‐channel blocker	26 (14.1)	104 (16.3)	39 (15.5)	21 (20)	0.38
Intensive care unit stay	63 (34.2)	154 (24.1)	61 (24.3)	30 (28.6)	0.16
Length of stay, days	10.3 (9.7)	9.7 (6.8)	10.2 (7.6)	11.1 (8.6)	0.10
Discharge destination
Home	20 (10.9)	65 (10.2)	43 (17.1)	19 (18.1)
ALC/nursing home	146 (79.8)	547 (85.5)	199 (79.3)	83 (79)	<0.001
In‐hospital death	17 (9.3)	28 (4.4)	9 (3.6)	3 (2.9)

Table 3.Univariate Unadjusted Inpatient Noncardiac Complication Rates Among 1,180 Olmsted County, Minnesota, Residents Undergoing Urgent Hip Fracture Repair, 1988‐2002
	Overall Cohort n (%)	Underweight (<18.5 kg/m²) n = 184 n (%)	Normal (18.5‐24.9 kg/m²) n = 640 n (%)	Overweight (25‐29.9 kg/m²) n = 251 n (%)	Obese (30 kg/m²) n = 105 n (%)	P Value
NOTE: All values are represented as count (proportion) for categorical variables; counts are the number of cases that fulfilled the criteria for a given inpatient complication. P values represent a Fisher Exact or Cochran‐Mantel‐Haenszel; P < 0.05 is significant.
Gastrointestinal
Ileus	38 (3.2)	1 (0.5)	21 (3.3)	12 (4.8)	4 (3.8)	0.03
Gastrointestinal bleeding	21 (1.8)	1 (0.5)	11 (1.7)	6 (2.4)	3 (2.9)	0.35
Infectious
Pneumonia	69 (5.8)	12 (6.5)	39 (6.1)	14 (5.6)	4 (3.8)	0.51
Bacteremia/sepsis	8 (0.7)	1 (0.5)	2 (0.3)	5 (2.0)	0 (0)	0.06
Urinary tract infection	84 (7.1)	12 (6.5)	47 (7.3)	15 (6)	10 (9.5)	0.78
Wound
Cellulitis
Neurological
Cerebral event‐hypoxia, thrombosis or hemorrhage	15 (1.3)	1 (0.5)	6 (0.9)	6 (2.4)	2 (1.9)	0.21
Transient ischemic attack
Delirium	199 (16.9)	40 (21.7)	106 (16.6)	36 (14.3)	17 (16.2)	0.08
Renal/metabolic
Renal failure	19 (1.6)	3 (1.6)	9 (1.4)	5 (2.0)	2 (1.9)	0.82
Dehydration
Electrolyte abnormalities
Respiratory
Respiratory failure	53 (4.5)	10 (5.4)	23 (3.6)	15 (6.0)	5 (4.8)	0.61
Respiratory depression	23 (1.9)	3 (1.6)	11 (1.7)	8 (3.2)	1 (1.0)	0.50
Pulmonary hypoxemia	157 (13.3)	33 (17.9)	78 (12.2)	34 (13.5)	12 (11.4)	0.22
Vascular
Deep vein thrombosis	5 (0.4)	0 (0)	2 (0.3)	3 (1.2)	0 (0)	0.24
Pulmonary embolism	16 (1.4)	3 (1.6)	7 (1.1)	5 (2.0)	1 (1.0)	0.65
Other
Fractures	6 (0.5)	1 (0.5)	5 (0.8)	0 (0)	0 (0)	0.57
Falls

Table 4.Multivariable Analysis for Inpatient Medical Complications Among 1,180 Olmsted County, Minnesota, Residents Undergoing Urgent Hip Fracture Repair, 1988‐2002
	Underweight <18.5 kg/m² n = 184* n (%)	Normal 18.5‐24.9 kg/m² n = 640* n (%)	Overweight 25‐29.9 kg/m² n = 251* n (%)	Obese 30 kg/m² n = 105* n (%)	Age	Male Sex	Surgical Year	ASA Score, III‐V vs. I/II	COPD/ Asthma
NOTE: Each row represents a separate multivariable logistic regression analysis. All values are listed as hazard ratios (95% confidence intervals). Abbreviations: ASA, American Society of Anesthesia; BMI, body mass index; COPD, chronic obstructive pulmonary disease. * The number of observed number of fractures in this category. Model 1: Effect of BMI category (underweight, normal, overweight, and obese) on overall noncardiac inpatient complication rate adjusted, a priori individually, for age, sex, surgical year, and ASA score univariately. P < 0.05. Model 2: Effect of BMI category (underweight, normal, overweight, and obese) on overall noncardiac inpatient complication rate, after adjusting for age, sex, surgical year, and ASA class. ∥ Model 3: Model evaluating other potential risk factors, including baseline demographic and baseline clinical variables that were significant (P < 0.05) univariately using stepwise selection. Model includes BMI as a categorical variable (underweight, normal, overweight, and obese), adjusted for age, sex, surgical year, and ASA class. Model 4: Model evaluating other potential risk factors, including baseline demographic and baseline clinical variables that were significant (P < 0.05) univariately using stepwise selection. Model 3 is similar to this, but does not force BMI in.
Model 1a	1.25 (0.89‐1.74)	Referent	0.97 (0.72‐1.31)	1.16 (0.76‐1.76)
Model 1b	1.26 (0.90‐1.77)	Referent	1.05 (0.77‐1.43)	1.38 (0.90‐2.13)	1.04 (1.02‐1.06)
Model 1c	1.30 (0.93‐1.83)	Referent	0.93 (0.68‐1.26)	1.12 (0.73‐1.71)		1.47 (1.09‐1.98)
Model 1d	1.28 (0.91‐1.79)	Referent	0.97 (0.71‐1.31)	1.13 (0.74‐1.73)			1.03 (1.00‐1.06)
Model 1e	1.23 (0.88‐1.72)	Referent	1.00 (0.73‐1.36)	1.13 (0.74‐1.73)				2.22 (1.52‐3.24)
Model 2	1.33 (0.95‐1.88)	Referent	1.01 (0.74‐1.38)	1.28 (0.82‐1.98)	1.04 (1.02‐1.06)	1.59 (1.17‐2.17)	1.02 (0.99‐1.05)	1.89 (1.28‐2.79)
Model 3∥	1.30 (0.92‐1.84)	Referent	1.04 (0.76‐1.42)	1.30 (0.84‐2.02)	1.05 (1.03‐1.06)	1.52 (1.11‐2.07)	1.02 (0.99‐1.05)	1.77 (1.20‐2.62)	1.58 (1.17‐2.12)
Model 4					1.05 (1.03‐1.06)	1.49 (1.10‐2.02)		1.84 (1.25‐2.71)	1.58 (1.18‐2.12)

Discussion

Conclusions

Acknowledgements

The authors thank Donna K. Lawson, LPN, Kathy Wolfert, and Cherie Dolliver, for their assistance in data collection and management.

References

Spillman BC, Lubitz J.The effect of longevity on spending for acute and long‐term care.N Engl J Med.2000;342(19):1409–1415.
Flegal KM, Graubard BI, Williamson DF, Gail MH.Excess deaths associated with underweight, overweight, and obesity.JAMA.2005;293(15):1861–1867.
Melton LJ.Adverse outcomes of osteoporotic fractures in the general population.J Bone Miner Res.2003;18(6):1139–1141.
Burge R, Dawson‐Hughes B, Solomon DH, Wong JB, King A, Tosteson A.Incidence and economic burden of osteoporosis‐related fractures in the United States, 2005–2025.J Bone Miner Res.2007;22(3):465–475.
Huddleston JM, Whitford KJ.Medical care of elderly patients with hip fractures.Mayo Clin Proc.2001;76(3):295–298.
Phy MP, Vanness DJ, Melton LJ, et al.Effects of a hospitalist model on elderly patients with hip fracture.Arch Intern Med.2005;165(7):796–801.
De Laet C, Kanis JA, Oden A, et al.Body mass index as a predictor of fracture risk: a meta‐analysis.Osteoporos Int.2005;16(11):1330–1338.
Chang SS, Jacobs B, Wells N, Smith JA, Cookson MS.Increased body mass index predicts increased blood loss during radical cystectomy.J Urol.2004;171(3):1077–1079.
Schwandner O, Farke S, Schiedeck TH, Bruch HP.Laparoscopic colorectal surgery in obese and nonobese patients: do differences in body mass indices lead to different outcomes?Surg Endosc.2004;18(10):1452–1456.
Shubair MM, Prabhakaran P, Pavlova V, Velianou JL, Sharma AM, Natarajan MK.The relationship of body mass index to outcomes after percutaneous coronary intervention.J Interv Cardiol.2006;19(5):388–395.
Wigfield CH, Lindsey JD, Munoz A, Chopra PS, Edwards NM, Love RB.Is extreme obesity a risk factor for cardiac surgery? An analysis of patients with a BMI ≥40.Eur J Cardiothorac Surg.2006;29(4):434–440.
Miric A, Lim M, Kahn B, Rozenthal T, Bombick D, Sculco TP.Perioperative morbidity following total knee arthroplasty among obese patients.J Knee Surg.2002;15(2):77–83.
Patel N, Bagan B, Vadera S, et al.Obesity and spine surgery: relation to perioperative complications.J Neurosurg Spine.2007;6(4):291–297.
Perka C, Labs K, Muschik M, Buttgereit F.The influence of obesity on perioperative morbidity and mortality in revision total hip arthroplasty.Arch Orthop Trauma Surg.2000;120(5–6):267–271.
Batsis JA, Huddleston JM, Melton LJ, et al.Body mass index and risk of adverse cardiac events in elderly hip fracture patients: a population‐based study.J Am Geriatr Soc.2009;57(3):419–426.
Melton L.History of the Rochester Epidemiology Project.Mayo Clin Proc.1996;71(3):266–274.
Melton LJ.The threat to medical‐records research.N Engl J Med.1997;337(20):1466–170.
Quetelet L.A Treatise on Man and the Development of His Faculties.Brussels:Musquardt;1871.
Lawrence VA, Hilsenbeck SG, Noveck H, Poses RM, Carson JL.Medical complications and outcomes after hip fracture repair.Arch Intern Med.2002;162(18):2053–2057.
Akinnusi ME, Pineda LA, El Solh AA.Effect of obesity on intensive care morbidity and mortality: a meta‐analysis.Crit Care Med.2008;36(1):151–158.
Patel AD, Albrizio M.Relationship of body mass index to early complications in knee replacement surgery.Arch Orthop Trauma Surg.2008;128(1):5–9.
Andrew JG, Palan J, Kurup HV, Gibson P, Murray DW, Beard DJ.Obesity in total hip replacement.J Bone Joint Surg Br.2008;90(4):424–429.
Hardy DC, Descamps PY, Krallis P, et al.Use of an intramedullary hip‐screw compared with a compression hip‐screw with a plate for intertrochanteric femoral fractures. A prospective, randomized study of one hundred patients.J Bone Joint Surg Am.1998;80(5):618–630.
Levi N.Blood transfusion requirements in intracapsular femoral neck fractures.Injury.1996;27(10):709–711.
Miller K, Atzenhofer K, Gerber G, Reichel M.Risk prediction in operatively treated fractures of the hip.Clin Orthop Relat Res.1993(293):148–152.
Parker MJ.Internal fixation or arthroplasty for displaced subcapital fractures in the elderly?Injury.1992;23(8):521–524.
Engelman DT, Adams DH, Byrne JG, et al.Impact of body mass index and albumin on morbidity and mortality after cardiac surgery.J Thorac Cardiovasc Surg.1999;118(5):866–873.
Klasen J, Junger A, Hartmann B, et al.Increased body mass index and peri‐operative risk in patients undergoing non‐cardiac surgery.Obes Surg.2004;14(2):275–281.
Schwann TA, Habib RH, Zacharias A, et al.Effects of body size on operative, intermediate, and long‐term outcomes after coronary artery bypass operation.Ann Thorac Surg.2001;71(2):521–530; discussion 530–531.
Dindo D, Muller MK, Weber M, Clavien PA.Obesity in general elective surgery.Lancet.2003;361(9374):2032–2035.
Batsis JA, Phy MP, Joseph Melton L, et al.Effects of a hospitalist care model on mortality of elderly patients with hip fractures.J Hosp Med.2007;2(4):219–225.
Gdalevich M, Cohen D, Yosef D, Tauber C.Morbidity and mortality after hip fracture: the impact of operative delay.Arch Orthop Trauma Surg.2004;124(5):334–340.
Shah MR, Aharonoff GB, Wolinsky P, Zuckerman JD, Koval KJ.Outcome after hip fracture in individuals ninety years of age and older.J Orthop Trauma.2001;15(1):34–39.
Jiang HX, Majumdar SR, Dick DA, et al.Development and initial validation of a risk score for predicting in‐hospital and 1‐year mortality in patients with hip fractures.J Bone Miner Res.2005;20(3):494–500.
Gallagher D, Visser M, Sepulveda D, Pierson RN, Harris T, Heymsfield SB.How useful is body mass index for comparison of body fatness across age, sex, and ethnic groups?Am J Epidemiol.1996;143(3):228–239.
Smalley KJ, Knerr AN, Kendrick ZV, Colliver JA, Owen OE.Reassessment of body mass indices.Am J Clin Nutr.1990;52(3):405–408.
Romero‐Corral A, Somers VK, Sierra‐Johnson J, et al.Accuracy of body mass index in diagnosing obesity in the adult general population.Int J Obes (Lond).2008;32(6):959–966.
Inouye SK, van Dyck CH, Alessi CA, Balkin S, Siegal AP, Horwitz RI.Clarifying confusion: the confusion assessment method. A new method for detection of delirium.Ann Intern Med.1990;113(12):941–948.

References

Spillman BC, Lubitz J.The effect of longevity on spending for acute and long‐term care.N Engl J Med.2000;342(19):1409–1415.
Flegal KM, Graubard BI, Williamson DF, Gail MH.Excess deaths associated with underweight, overweight, and obesity.JAMA.2005;293(15):1861–1867.
Melton LJ.Adverse outcomes of osteoporotic fractures in the general population.J Bone Miner Res.2003;18(6):1139–1141.
Burge R, Dawson‐Hughes B, Solomon DH, Wong JB, King A, Tosteson A.Incidence and economic burden of osteoporosis‐related fractures in the United States, 2005–2025.J Bone Miner Res.2007;22(3):465–475.
Huddleston JM, Whitford KJ.Medical care of elderly patients with hip fractures.Mayo Clin Proc.2001;76(3):295–298.
Phy MP, Vanness DJ, Melton LJ, et al.Effects of a hospitalist model on elderly patients with hip fracture.Arch Intern Med.2005;165(7):796–801.
De Laet C, Kanis JA, Oden A, et al.Body mass index as a predictor of fracture risk: a meta‐analysis.Osteoporos Int.2005;16(11):1330–1338.
Chang SS, Jacobs B, Wells N, Smith JA, Cookson MS.Increased body mass index predicts increased blood loss during radical cystectomy.J Urol.2004;171(3):1077–1079.
Schwandner O, Farke S, Schiedeck TH, Bruch HP.Laparoscopic colorectal surgery in obese and nonobese patients: do differences in body mass indices lead to different outcomes?Surg Endosc.2004;18(10):1452–1456.
Shubair MM, Prabhakaran P, Pavlova V, Velianou JL, Sharma AM, Natarajan MK.The relationship of body mass index to outcomes after percutaneous coronary intervention.J Interv Cardiol.2006;19(5):388–395.
Wigfield CH, Lindsey JD, Munoz A, Chopra PS, Edwards NM, Love RB.Is extreme obesity a risk factor for cardiac surgery? An analysis of patients with a BMI ≥40.Eur J Cardiothorac Surg.2006;29(4):434–440.
Miric A, Lim M, Kahn B, Rozenthal T, Bombick D, Sculco TP.Perioperative morbidity following total knee arthroplasty among obese patients.J Knee Surg.2002;15(2):77–83.
Patel N, Bagan B, Vadera S, et al.Obesity and spine surgery: relation to perioperative complications.J Neurosurg Spine.2007;6(4):291–297.
Perka C, Labs K, Muschik M, Buttgereit F.The influence of obesity on perioperative morbidity and mortality in revision total hip arthroplasty.Arch Orthop Trauma Surg.2000;120(5–6):267–271.
Batsis JA, Huddleston JM, Melton LJ, et al.Body mass index and risk of adverse cardiac events in elderly hip fracture patients: a population‐based study.J Am Geriatr Soc.2009;57(3):419–426.
Melton L.History of the Rochester Epidemiology Project.Mayo Clin Proc.1996;71(3):266–274.
Melton LJ.The threat to medical‐records research.N Engl J Med.1997;337(20):1466–170.
Quetelet L.A Treatise on Man and the Development of His Faculties.Brussels:Musquardt;1871.
Lawrence VA, Hilsenbeck SG, Noveck H, Poses RM, Carson JL.Medical complications and outcomes after hip fracture repair.Arch Intern Med.2002;162(18):2053–2057.
Akinnusi ME, Pineda LA, El Solh AA.Effect of obesity on intensive care morbidity and mortality: a meta‐analysis.Crit Care Med.2008;36(1):151–158.
Patel AD, Albrizio M.Relationship of body mass index to early complications in knee replacement surgery.Arch Orthop Trauma Surg.2008;128(1):5–9.
Andrew JG, Palan J, Kurup HV, Gibson P, Murray DW, Beard DJ.Obesity in total hip replacement.J Bone Joint Surg Br.2008;90(4):424–429.
Hardy DC, Descamps PY, Krallis P, et al.Use of an intramedullary hip‐screw compared with a compression hip‐screw with a plate for intertrochanteric femoral fractures. A prospective, randomized study of one hundred patients.J Bone Joint Surg Am.1998;80(5):618–630.
Levi N.Blood transfusion requirements in intracapsular femoral neck fractures.Injury.1996;27(10):709–711.
Miller K, Atzenhofer K, Gerber G, Reichel M.Risk prediction in operatively treated fractures of the hip.Clin Orthop Relat Res.1993(293):148–152.
Parker MJ.Internal fixation or arthroplasty for displaced subcapital fractures in the elderly?Injury.1992;23(8):521–524.
Engelman DT, Adams DH, Byrne JG, et al.Impact of body mass index and albumin on morbidity and mortality after cardiac surgery.J Thorac Cardiovasc Surg.1999;118(5):866–873.
Klasen J, Junger A, Hartmann B, et al.Increased body mass index and peri‐operative risk in patients undergoing non‐cardiac surgery.Obes Surg.2004;14(2):275–281.
Schwann TA, Habib RH, Zacharias A, et al.Effects of body size on operative, intermediate, and long‐term outcomes after coronary artery bypass operation.Ann Thorac Surg.2001;71(2):521–530; discussion 530–531.
Dindo D, Muller MK, Weber M, Clavien PA.Obesity in general elective surgery.Lancet.2003;361(9374):2032–2035.
Batsis JA, Phy MP, Joseph Melton L, et al.Effects of a hospitalist care model on mortality of elderly patients with hip fractures.J Hosp Med.2007;2(4):219–225.
Gdalevich M, Cohen D, Yosef D, Tauber C.Morbidity and mortality after hip fracture: the impact of operative delay.Arch Orthop Trauma Surg.2004;124(5):334–340.
Shah MR, Aharonoff GB, Wolinsky P, Zuckerman JD, Koval KJ.Outcome after hip fracture in individuals ninety years of age and older.J Orthop Trauma.2001;15(1):34–39.
Jiang HX, Majumdar SR, Dick DA, et al.Development and initial validation of a risk score for predicting in‐hospital and 1‐year mortality in patients with hip fractures.J Bone Miner Res.2005;20(3):494–500.
Gallagher D, Visser M, Sepulveda D, Pierson RN, Harris T, Heymsfield SB.How useful is body mass index for comparison of body fatness across age, sex, and ethnic groups?Am J Epidemiol.1996;143(3):228–239.
Smalley KJ, Knerr AN, Kendrick ZV, Colliver JA, Owen OE.Reassessment of body mass indices.Am J Clin Nutr.1990;52(3):405–408.
Romero‐Corral A, Somers VK, Sierra‐Johnson J, et al.Accuracy of body mass index in diagnosing obesity in the adult general population.Int J Obes (Lond).2008;32(6):959–966.
Inouye SK, van Dyck CH, Alessi CA, Balkin S, Siegal AP, Horwitz RI.Clarifying confusion: the confusion assessment method. A new method for detection of delirium.Ann Intern Med.1990;113(12):941–948.

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Journal of Hospital Medicine - 4(8)

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Body mass index (BMI) and risk of noncardiac postoperative medical complications in elderly hip fracture patients: A population‐based study

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Body mass index (BMI) and risk of noncardiac postoperative medical complications in elderly hip fracture patients: A population‐based study

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elderly, hip fractures, inpatient, medical complications, obesity, postoperative

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elderly, hip fractures, inpatient, medical complications, obesity, postoperative

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John A. Batsis, Section of General Internal Medicine, Dartmouth‐Hitchcock Medical Center, 1 Medical Center Drive, Lebanon, NH 03755
Jeanne M. Huddleston, Division of Hospital Internal Medicine, Mayo Clinic, 200 First Street SW, Rochester, MN 55905

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Costs and Arthroplasty

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Resource utilization of total knee arthroplasty patients cared for on specialty orthopedic surgery units

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James M. Naessens, ScD, MPH

Mark T. Keegan, MD

Amy E. Wagie, BS

Hospital practices are increasingly responsible for ensuring enhanced patient safety, satisfaction, and cost containment. Recently developed models of care have achieved the necessary efficiency to attain these measures, not only in the use of hospitalists managing general medical1, 2 and postoperative orthopedic patients,3, 4 but also in the use of midlevel providers in busy primary care settings.5 In addition, stroke units6 and geriatric evaluation and management units7, 8 worldwide have demonstrated reduced disability and improved survival and importantly have been proven to provide cost‐effective care. Specialized orthopedic surgery (SOS) units may be a means to reproduce the results observed in these other models.

The economic potential of SOS units will become more significant with changing demographics. The percentage of patients greater than 65 years old will increase, from 12.3% in 2002 to 20% by 2030, with a parallel increase in the prevalence of osteoarthritis (OA).9 The World Health Organization has declared 2000‐2010 the Bone and Joint Decade,10, 11 reflecting that OA affects some 43 million people, with more than 60 million projected to be affected by 2020.12, 13 The National Center for Health Statistics reported that more than 280,000 total knee arthroplasties (TKAs) are performed annually in the United States, which marks an increase in frequency in the last decade that is likely to continue.1419

Approximately 75% of all TKAs are reimbursed under Medicare,17 whereas elective TKA continues to be one of the most common surgeries in the Medicare‐age patient population,20 foreshadowing the prominent cost burden of osteoarthritis in the aging population. The concomitant decreasing reimbursement for arthroplasty in general supports an examination of what constitutes efficient, high‐quality, and cost‐effective care21 for TKA. At our institution, patients undergoing TKA are preferentially triaged to an SOS nursing unit for postoperative care. As hospital bed capacity continues to decline, patients may be triaged to open beds at locations that may not be the optimal choice for nursing care. The primary purpose of this study was to determine the impact of SOS units versus nonorthopedic nursing (NON) units on resource utilization for and outcomes of patients undergoing elective knee arthroplasty. We hypothesized that length of stay would be shorter and cost of inpatient care would be lower for patients cared for on SOS units.

MATERIALS AND METHODS

Study Design and Setting

We conducted a retrospective observational cohort study of all patients undergoing elective primary TKA from January 1, 1996, to December 31, 2004, comparing outcomes of patients assigned to SOS units with those of patients assigned to NON units. Patients were admitted to Rochester Methodist Hospital, Mayo Clinic, a tertiary‐care primary surgical teaching hospital that has 794 beds and more than 15,000 admissions annually. There were 13 faculty orthopedic surgeons performing elective nontraumatic lower‐extremity joint procedures during the study period, each with orthopedic residents rotating as part of the patient care team.

Study Population

All patients at Mayo Clinic who had undergone a joint replacement were followed prospectively, and data were collected using standardized forms and protocols, the methodologies of which have been described previously.22 Follow‐up was greater than 95% complete. Using the joint registry, patients who had undergone a TKA were identified (n = 9798). Postoperative patients initially transferred from the postanesthesia care unit to a general care floor were included. We excluded patients who required urgent, revision, or bilateral arthroplasties; who had been treated at or transferred from another institution; and whose primary surgical indication was trauma or septic arthritis. Subjects admitted to the hospital on the day prior to the procedure and subjects initially transferred directly from the postanesthesia care unit to the intensive care unit (ICU) were excluded, including patients requiring immediate postoperative cardiac monitoring. All primary surgical interventions were performed between Monday and Friday. The study authors identified 5883 eligible patients.

Patient clinical and demographic data including surgical indication; age; sex; height and weight at surgery; and dates of admission, surgery, death, discharge, and last follow‐up were abstracted from the registry. Type of anesthesia (general, regional, combined), American Society of Anesthesiologists (ASA) physical status class, and date and time of ICU admission and discharge were abstracted from individual departmental databases. The Decision Support System (DSS) administrative database (Eclipsys, Boca Raton, FL) was utilized to abstract relevant clinical variables, including major comorbid conditions such as cancer, cerebrovascular disease, chronic pulmonary disease, congestive heart failure, dementia, diabetes, hemiplegia, HIV/AIDS, metastatic solid tumors, myocardial infarction, peripheral vascular disease, renal disease, rheumatologic disease, and ulcers. A composite Charlson comorbidity score was computed as previously described.23, 24 Administrative variables regarding patient encounters including inpatient stay variableslength of stay, costs, patient location, nursing care units, admission times, discharge disposition and datewere also obtained from the DSS database.

Variables and Definitions

Length of stay was defined as the number of days from time of admission for the surgical episode to time of discharge. All costs were based on a provider perspective using standardized 2005 costs based on inflation‐adjusted estimates as previously described.3, 25, 26 We assessed resource utilization among patients who received care on an SOS unit by determining length of stay and total, hospital, and physician costs for the specified surgical episode. We also assessed blood bank, ICU, laboratory, pharmacy, physical therapy, occupational therapy, respiratory therapy, radiology, and room‐and‐board costs. Blood bank costs consisted of the costs of storing, processing, and administering the transfusion. Surgical procedure, anesthesia, and preoperative service costs were excluded from our cost analyses, as our aim was to examine hospital flow and resource utilization from time of transfer from the postanesthesia care unit to hospital discharge in order to specifically examine the impact of an SOS unit. We compared unexpected ICU admissions and stays and the resources utilized of patients in these 2 groups.

State and federal death registries confirmed patient expiration and primary cause of death. In‐hospital mortality was defined as death during the same hospital admission as the indexed surgical episode. Thirty‐day mortality was defined as death occurring within 30 days of the surgical procedure. Readmission at 30 days was defined as any admission to our institutions within a 30‐day period whose purpose was possibly related to the initial surgical episode and not a result of an elective admission. A priori we were aware of the small number of these events in the elective joint population. Therefore, we combined inpatient 30‐day mortality, 30‐day reoperation, and 30‐day readmission rates as a composite endpoint.

Specialized Orthopedic Surgery Units

An SOS unit was defined as a general care nursing unit where patients receive all their postoperative care after elective TKA. Such a unit has a multidisciplinary staff that has orthopedic expertise. The differences between an SOS unit and a NON unit are described in Table 1. Bed availability at the time of discharge from the postanesthesia care unit was the exclusive factor for admission to this unit. Bed availability was dependent on staff availability or whether there was an excess number of operative cases. The number and severity of patient medical comorbidities or complications, the time of discharge from the postanesthesia care unit, and patient room preference had no impact on which unit patients were admitted to. Patients were allocated to the SOS group or the NON unit group according to their physical location the evening of admission. Monitored beds at this facility are solely located in the ICU, and neither SOS nor NON units have this capability. Any patient requiring a monitored bed at any time, regardless of the reason, would be transferred directly to the ICU. Daily rounds were performed on either unit by the primary orthopedic team. The need for either medical or pain service consultation was at the discretion of the primary orthopedic team and not dependent on the patient's physical location.

Table 1.Characteristics of Specialized Orthopedic Surgical Units and Nonorthopedic Nursing Units
	Specialized orthopedic surgical unit (SOS)	Nonorthopedic nursing unit (NON)
* RN, registered nurse.
Type of unit	Orthopedic general care unit.	General surgical care unit.
Patient type	Postoperative elective orthopedic only.	Any patientmedical or surgical.
Determinants of physical location for orthopedic patient	Primary bed assignment.	Admitted only if SOS units have reached full bed capacity.
Orthopedic‐trained nursing staff	Yesrequired to have additional post‐RN* training in orthopedics. These RNs rarely float to nonorthopedic units.	Nomay have additional training or experience in an unrelated medical or surgical discipline. Floating to other units may occur.
Orthopedic‐specific physical + occupational therapy	Provided by certified physical therapists trained in lower‐extremity joint procedures. Site‐based therapy available to all patients on SOS units.	Provided by certified physical therapists who do not necessarily have postoperative orthopedic lower‐extremity specialization. Site‐based therapy on NON unit available to all patients.
Licensed social workers	Dedicated to postoperative needs of orthopedic patients physically located on SOS units.	Not specifically dedicated to the postoperative elective orthopedic joint patient and not physically located on these units.
Interdisciplinary team meetings	Patient care addressed in a interdisciplinary team meeting 3 times weeklyconsists of an RN, physical and occupational therapists, social worker, and physician.	No care team meetings, as patients are off‐service.
Physician postoperative order set	Orthopedic‐specific order set that is available hospitalwide. Nursing staff on these units is familiar with these order sets.	Orthopedic‐specific order set available hospitalwide. Nursing staff on these units may not be entirely familiar with these order sets.
Rehabilitation protocols	Orthopedic specific.	Not orthopedic specific.
Patient‐care instructions	Orthopedic diagnosis‐specific instructions readily available	Orthopedic diagnosis‐specific instructions available but requires staff to obtain information and forms from the SOS inits.
Discharge protocol	Specifically targeted to the postarthroplasty patient	Generic hospitalwide protocol.
Hospital discharge summary	Yescowritten by primary orthopedic team and primary orthopedic RN.	Yescowritten by primary orthopedic team and nonorthopedic RN.
Orthopedic‐specific discharge instructions	Yescowritten by primary orthopedic team and primary orthopedic RN.	No.

All data were subsequently combined into a single database to facilitate data analysis. We further excluded 44 patients because no cost information was available, 9 patients who had multiple joint replacements performed during the specified surgical hospitalization, 69 patients because they had not authorized their medical records to be used for the purposes of research; 163 patients admitted directly to the ICU, 63 patients admitted the day prior to surgery, and 1 patient whose billing data suggested an outpatient encounter. A final patient cohort of 5534 patients was in the analysis. With the observed sample size and the overall variability, our study had 80% power to detect a difference between the 2 groups as small as 0.22 days in length of stay and $761 in hospital costs. The study was approved by our institutional review board. All study patients had authorized the use of their medical records for the purposes of research. Funding was obtained through an intramurally sponsored Small Grants Program by the Division of General Internal Medicine, which had no impact on the design of the study, reporting, or decision to submit an article on the study for publication.

Statistical Analysis

The statistical analysis compared baseline health and demographic characteristics of the patients cared for on SOS units with those cared for on NON units using chi‐square tests for nominal factors and the 2‐sample Wilcoxon rank sum tests for continuous variables. We used the chi‐square test to test for unadjusted differences in sex, patient residence (local or referred), race, individual Charlson comorbid conditions, anesthesia type, admitting diagnosis, 30‐day readmission rate, and discharge location. The 2‐sample Wilcoxon rank sum test assessed unadjusted differences in length of stay, costs, age, ICU days of stay, number of reoperations, total Charlson score and ASA class. Thirty‐day mortality rates were tested using the Fisher exact test.

Differences between patients in SOS and NON units in length of stay (LOS) and costs were the study's primary outcomes. We adjusted for baseline and surgical covariates using generalized linear regression models for these outcomes. The effect of the nursing unit was based on regression coefficients for age, sex, ASA class, anesthesia type, Charlson comorbidities, and surgical year. Age was analyzed using 5 categories: <55; 55‐64; 70‐74; 54‐69, and >75 years, with 65‐69 years used as the reference group. Each Charlson comorbid condition was treated as an indicator variable. Indicator variables were also assigned to surgical year, with 2004 used as the reference. These variables were subsequently entered into the model to calculate the differences between patients on an SOS unit and those on a NON unit.

Our secondary outcomes included ICU utilization and 30‐day outcomes of mortality, reoperations, and readmissions. We then assessed the effect of treatment on the SOS unit using the entire cohort (n = 5534) for unplanned postoperative ICU stay (yes or no) and on our combined endpoint after adjusting for the variables listed previously, using logistic regression models. A P value < 0.05 was considered statistically significant. All analyses were performed using statistical software (SAS, version 9.1; SAS Institute Inc, Cary, NC).

RESULTS

Baseline patient characteristics are represented in Table 2. Five thousand and eighty‐two patients were admitted to an SOS unit, and 452 patients were admitted to a NON unit. The annual number of patients undergoing TKA increased during our study period, as did the number of patients cared for on NON units. There were no differences between groups in the number of local county patients or in the number of patients primarily referred by other providers for elective arthroplasty. Mean length of stay was 4.9 days in both groups. After adjusting for the specified covariates, including age, sex, year of surgery, Charlson comorbidities, ASA class, and type of anesthesia, LOS was 0.234 days shorter in the SOS group (95% confidence interval [CI]: 0.08, 0.39; P = .002). Overall and hospital costs were significantly lower in the SOS group, as outlined with the other costs in Table 3. Room‐and‐board costs were 5.3% lower for SOS patients than for patients on NON units, representing a per‐patient difference of $244 $87 (95% CI: $72, $415; P = .005).

Table 2.Baseline Characteristics of Patients Undergoing Unilateral Primary Total Knee Arthroplasty (n = 5534)
	Specialized orthopedic surgery unit (n = 5082)		Nonorthopedic nursing unit (n = 452)		P value
	n	%	n	%	P value
All numbers are expressed as number of patients followed by percentage of patients, unless otherwise indicated. * Includes African American, Native American, and Asian. Includes patients who were unable to provide or refused to disclose this information. SD, standard deviation; AIDS, acquired immunodeficiency syndrome; ‖ ASA, American Society of Anesthesiologists.
Age (years)
<55	534	10.5%	57	12.6%
55‐64	1148	22.6%	101	22.4%
65‐69	802	15.8%	66	14.6%
70‐74	1106	21.8%	91	20.1%
>75	1492	29.4%	137	30.3%
Mean age ( SD*)	68.3 10.75		67.9 11.5		.50
Sex					.70
Male	2173	42.8%	189	41.8%
Female	2909	57.2%	263	58.2%
Race					.28
White	4731	93.1%	420	92.9%
Other*	51	1.0%	8	1.8%
Unknown	300	5.9%	24		5.3%
Local Olmsted County patients	772	15.2%	58	12.8%	.18
Indication for surgery					.03
Osteoarthritis	4778	94%	430	95.1%
Rheumatologic disease	184	3.6%	6	1.3%
Avascular necrosis	62	1.2%	5	1.1%
Congenital	6	0.1%	1	0.2%
Cancer	22	0.4%	5	1.1%
Other	30	0.6%	5	1.1%
Year of surgery					< .001
1996	497	98.8%	6	1.19%
1997	571	99.7%	2	0.35%
1998	479	98.8%	6	1.24%
1999	487	94.8%	27	5.25%
2000	458	92.7%	36	7.29%
2001	502	86.7%	77	13.3%
2002	593	89.2%	72	10.8%
2003	639	87.1%	95	12.9%
2004	856	86.7%	131	13.3%
Charlson score (mean SD)	0.256 0.536		0.288 0.593		.23
AIDS	0	0%	1	0.22%	1.00
Cancer	85	1.68%	7	1.55%	.84
Cerebrovascular disease	32	0.63%	0	0%	.09
Chronic pulmonary disease	28	5.63%	23	5.09%	.63
Congestive heart failure	89	1.75%	22	4.87%	< .001
Dementia	10	0.2%	2	0.44%	.28
Diabetes	603	11.9%	58	12.8%	.54
Hemiplegia	9	0.18%	0	0%	.37
Metastatic solid tumor	11	0.22%	2	0.44%	.34
Myocardial infarction	29	0.57%	4	0.88%	.4
Peripheral vascular disease	67	1.32%	4	0.88%	.43
Renal disease	52	1.02%	5	1.11%	.87
Rheumatologic disease	12	0.24%	2	0.44%	.40
Ulcers	15	0.3%	0	0%	.25
ASA class‖
I	99	2.0%	12	2.7%
II	2891	56.9%	255	56.4%
III	2084	41.0%	183	40.5%
IV	8	0.2%	2	0.4%
Average ASA class ( SD)	2.39 0.53		2.39 0.55		.80
Anesthesia type					.02
General	1644	32.4%	143	31.6%
Regional	2742	54%	226	50%
Combined	696	13.7%	83	18.4%

Table 3.Unadjusted and Adjusted Differences in Costs between Specialty Orthopedic Surgery Units and Nonorthopedic Surgery Units
	Unadjusted values					Adjusted values
	SOS*	SD	NON	SD	P value	Difference	SD	P value	95% CI
All cost data are represented as mean costs, representing costs from the time of discharge from the postanesthesia care unit to the time of hospital discharge. Adjusted data represent differences between the specialized orthopedic surgery unit (SOS) and the nonorthopedic nursing (NON) unit, after adjustment for age, sex, anesthesia, ASA class, and Charlson comorbidity. A positive adjusted dollar amount represents a cost savings relative to the NON unit. All values were rounded to the nearest dollar. P value < .05 is statistically significant. * SOS, specialty orthopedic surgery unit; NON, nonorthopedic nursing unit; SD, standard deviation; ICU, intensive care unit; ‖ E&M costs, evaluation and management; PT, physical therapy; ** OT, occupational therapy; RT, respiratory therapy; CI, confidence interval.
Total cost	$9989	$5392	$10,067	$5075	.77	$600	$244	.01	$122, $1079
Hospital costs	$9789	$5123	$ 9805	$4647	.23	$594	$231	.01	$141, $1047
Room & board	$4399	$1825	$ 4577	$1579	.04	$244	$ 87	.005	$ 72, $ 415
ICU costs	$ 58	$1094	$ 107	$ 682	.35	$ 11	$ 51	.82	$111, $ 88
Pharmacy	$ 851	$1701	$ 931	$1823	.34	$ 87	$ 85	.30	$ 79, $253
Laboratory costs	$ 386	$ 438	$ 395	$ 405	.65	$ 27	$ 20	.18	$ 12, $ 65
Radiology costs	$ 98	$ 205	$ 103	$ 183	.61	$ 1	$ 10	.93	$ 20, $ 19
PT/OT**/RT	$ 739	$ 505	$ 682	$ 394	.004	$ 15	$ 19	.45	$ 23, $ 52
Blood bank	$ 159	$ 306	$ 178	$3023	.22	$ 6	$ 15	.69	$ 35, $ 23
Physician costs	$ 207	$ 464	$ 258	$ 628	.09	$ 20	$ 22	.386	$ 24, $ 63
E&M costs‖	$ 89	$ 211	$ 109	$ 238	.09	$ 4	$ 9	.658	$ 23, $ 14
Physician radiology	$ 63	$ 158	$ 38	$ 192	.49	$ 2	$ 8	.78	$ 13, $ 18
Other costs	$ 34	$ 138	$ 37	$ 160	.61	$0.64	$ 6	.92	$ 13, $ 12

There were 83 patients (1.63%) transferred from SOS units to the ICU, compared with 14 patients (3.1%) transferred from NON units (P = .02), but no differences in the mean number of ICU days or associated costs between groups. A priori, the authors were aware of the small number of postoperative medical events in this population. In examining the combined endpoint of reoperations, readmissions, and mortality, there were no differences observed in our regression analysis between SOS patients and NON unit patients (0.03 events, standard error: 0.1859; odds ratio: 0.976). Table 4 demonstrates a higher percentage of patients discharged with home health on the NON units than on the SOS units (8.41% vs. 4.62%; P < .001).

Table 4.Patient Disposition at Time of Discharge
	Specialized orthopedic surgery unit		Nonorthopedic nursing unit		P value
	n*	%	n	%	P value
* There were 5 in‐hospital deaths in the specialized orthopedic surgery unit group.
Home	3812	75%	328	72.6%	.252
Home health	235	4.62%	38	8.41%	< .001
Transferred to skilled nursing facility	1030	20.3%	86	19%	.529

DISCUSSION

To the best of our knowledge, this is the first study to examine the impact of specialized orthopedic surgery units on resource utilization in elective knee arthroplasty patients. Our findings demonstrate that patients admitted following elective TKA to SOS units will have a reduced length of stay, lower overall and hospital costs, and fewer unexpected transfers to higher levels of care (ICUs). We believe that these findings are a result in part of the specialized expertise allied health care providers develop by taking care of and focusing on a large volume of patients over time with the same group and type of surgeons. This multidisciplinary setting in which care providers are familiar not only with each other but with this specific population of patients creates the environment necessary for adherence to specialized clinical pathways.27

Patient LOS is an important determinant of resource utilization. In a study by Husted et al., the mean length of stay in Danish hospitals following TKA was 8.6 days in 2003.28 An epidemiological study using the Nationwide Inpatient Sample database of patients in the United States showed that from 1998 to 2000, the mean LOS was 4.3 days.18 In our study, the mean LOS was slightly higher (4.9 days), potentially reflecting referral bias. Achieving additional savings and improved outcomes by further reducing LOS in an environment in which care pathways are already in place is often difficult; hence, alternative approaches and strategies are often necessary.29, 30 Our results suggest that in TKA patients, after adjusting for other factors, there is a decrease in the length of stay of 0.234 days among those cared for on SOS units. However, we cannot state that the existence of the clinical pathway alone is responsible for our data differences because certain components of the care pathway for elective TKA patients are used throughout the hospital regardless of type of postoperative nursing unit. We believe that the interdisciplinary specialty care provided to orthopedic patients on SOS units is a critical component of a successfully implemented care pathway and not just a convenience or practice preference. The same surgeons admitting patients to the same nursing unit, with the same nurses, physical therapists and pharmacists providing care to the same type of patient population over time, leverages the collective experience of all care providers. This integrated, multidisciplinary teamwork may optimize timeliness, achieve incremental cost savings, and improve safety (including a decreased number of unanticipated transfers to an ICU setting).

Clinical pathways are known to reduce overall costs, normally by reducing LOS,29, 3133 and our results suggest approximately an incremental 6% cost reduction with the use of improving patient logistics by using SOS units. An economic evaluation study by Healy et al. suggests that focusing on nursing units may be a means of reducing total costs.29 Our cost savings were slightly lower than the reported savings by other practice assessments; however, we excluded operative and anesthesia costs, both significant contributors to overall and hospital costs. By eliminating these variables, our costs were specifically limited to the postoperative course, which is highly dependent on specialized interdisciplinary care.29

Providing specialized care has a significant impact on society. Although there is a per‐patient savings of only $600 when elective TKA patients are cared for on SOS units, this could be the difference between a positive and negative margin in the setting of fixed reimbursement. With a current average of 90 patients annually triaged postoperatively to NON units, there is a potential loss of $54,000 annually at our institution in just this single patient population with the current mechanisms of perioperative hospital flow. Multiply this potential savings to a national level, and the total is significant. With an aging population, the number of arthroplasties and concomitantly the number of hospitalizations in general are likely to increase, suggesting that changes in hospital flow are required to ensure optimal, cost‐effective care in the best setting available for patients. Such care is often related to surgical volume, and our institution observes such volume. Our results indicate that SOS units are one possible means of achieving this objective of fiscal sustainability, but further studies are needed to determine the indirect and hidden costs of sustaining such units in order to observe the actual cost savings.34 It could be argued that for elective TKA patients to have the most optimal outcomes and most efficient care, the surgical procedure should be performed only if beds are available on the nursing units whose staff has the most specific training.

Thirty‐Day Outcomes

We elected to combine 30‐day mortality, reoperations, and readmissions pertaining to the joint procedure as a composite endpoint and found no differences in outcomes between groups. These results suggest that these longer‐term patient‐specific outcomes are likely not related to the specialty nursing care. We used a 30‐day endpoint assuming that a longer period may have led to the inclusion of deaths that were not directly attributable to the surgical intervention. In addition, a previous study advocated using 30 days as an endpoint for follow‐up, as it adequately accounts for adverse events.35 Our institution is also a referral center; hence, we would likely be unable to capture all events if we were to use the standard 90‐day period used for payment for this procedure, as these data are not canvassed by the joint registry.

Discharge Disposition

NON unit patients tended to have a higher degree of home health arranged at discharge. The NON unit nursing staff cares for other nonorthopedic surgical patients daily and may transfer their patterns of care utilization to the orthopedic patients despite different postoperative needs. In addition, if NON unit nursing staff members care for TKA patients only intermittently, they may not have as clear a working understanding of the particular postoperative requirements of TKA patients and consequently request unnecessary home health services and general community resources. Alternatively, patients cared for on NON units may actually have needed more assistance and more services on discharge. Although purely speculative, patients cared for by dedicated orthopedic surgery staff may develop added confidence from the experience of the allied care staff and feel less of a need for postdismissal services.

Role of Hospitalists in Specialized Care Pathways

Hospitalists are known to improve efficiency without reducing patient satisfaction. Their role has been demonstrated in different patient populations.1, 2, 3638 In a study of hip fracture patients, a hospitalist care model demonstrated a reduction in length of stay and time to surgery, without compromising long‐term outcomes.4, 39 Utilizing a hospitalist/midlevel care provider team approach to reduce LOS in units with a static number of beds can possibly increase bed turnover and prevent triaging of patients onto NON units. This is but one example of how a medical‐surgical partnership can improve outcomes. However, in an era where cost‐effective and regulatory practices require optimal resource allocation, hospitalists are in a key position to foster quality improvement projects, promote patient safety measures, and enhance systems care delivery. Becoming involved in designing specialized clinical units, with an emphasis on a multidisciplinary care approach, and developing their relationships with hospital administrators and nursing staff should be among their priorities. The Society of Hospital Medicine has also been committed to the care of the elderly through its core competencies40 and the orthopedic population that will benefit from such process changes and care pathways. Hospital innovations such as the implementation of SOS‐type units not only for other medical‐surgical partnerships but also for site‐based units caring for geriatric patients can be top priorities for hospitalists.

Strengths and Applicability

Our results are important in that they can likely be applied to both large tertiary‐care centers and smaller community‐based centers that perform specialized orthopedic surgeries. Nurses on specialized orthopedic units are very familiar with this postoperative population and have developed expertise in the care of these patients. These experienced nurses can likely be found on orthopedic units in tertiary‐care centers or surgical units in smaller facilities. Furthermore, our results support the benefits of interdisciplinary advanced teamwork. When an interdisciplinary group of health care providers works together on a daily basis, certain habits and patterns inevitably develop that often are unplanned and may be difficult to measure. This enhanced patient flow may not occur if these patients are cared for by providers unfamiliar with each other's work patterns. The importance of optimized teamwork is not hospital‐size dependent. Only primary elective knee arthroplasties were included to minimize confounding bias by bilateral or revision surgeries or indications such as septic arthritis, which are known to lead to increased length of stay, costs and complications.41

Limitations

Our study has the limitations of its retrospective nonrandomized study design, and only a prospective, randomized investigation could definitively address our aims. By excluding sicker patients, such as those referred with complicated health issues or high‐risk patients who required admission in advance of the proposed surgery for monitoring of perioperative anticoagulation issues, our estimates of possible differences between our comparison groups may have been conservative. We are unaware of how these sicker patients would fare on either nursing unit. Furthermore, what occurs in the hospital setting may not only have an impact on the hospital stay but may also influence long‐term outcomes. This is impossible to assess with analysis of administrative databases.

We relied on the complete and accurate recording of data from various databases, depending on the validity of data entry and collection. With a large cohort of patients, any errors in documentation or abstraction would be expected to be similar in both groups. Furthermore, confounding variables such as patient comorbidities are extracted from administrative data sets whose personnel might not be as familiar with the medical aspects of patient care. We used linear and logistic regression analyses to account for known differences in baseline characteristics despite the sample sizes being proportionally larger in the SOS group. Although we attribute the shortened length of stay in the SOS group to the interdisciplinary team approach, we were unable to determine to what extent this was a result of nursing staff or discharge planning. By using administrative databases, we were unable to abstract the consensus time and date of discharge, when all hospital staff deemed the patient ready for discharge, and hence relied on the actual time of discharge, which can be heavily reliant on availability at skilled nursing facilities. In addition, it was unknown whether patients discharged from SOS units were, by matter of protocol, discharged earlier in the day. Nevertheless, this small difference in length of stay can improve patient flow by opening up postoperative patient beds. Furthermore, such data sets are unable to provide information on patient satisfaction or quality‐of‐life measures, both of which are important determinants in specialized care pathways.42 The patient population served by our institution is generally ethnically homogeneous, thereby limiting potential generalizations to tertiary‐care centers or geographical areas with a population similar to ours. Our study also was not intended as a formal cost‐effectiveness analysis; hence, the impact of possible startup costs to begin a similar nursing unit was not explored. Although differences in practice management can be considered a limitation of not only operative but also perioperative care, we neither expected nor encountered any significant or drastic alterations during the study period, and year of surgery was adjusted for in our analysis. However, prospective randomized controlled studies testing specific clinical pathways and practice‐related innovations are needed to better examine these outcomes.

CONCLUSIONS

In conclusion, postoperative patients after elective knee arthroplasty cared for on specialized orthopedic surgery units have shorter length of stays and cost hospitals less than patients admitted to nonspecialized orthopedic nursing units. In an era in which quality indicators and external reviews are forcing practitioners and health care organizations to become increasingly responsible for their own practices, more research is required to better address specific questions pertaining to different processes of care. Our study is meant to increase the attention paid to patient flow and postoperative logistics in the elective TKA population. SOS units, as a unique model of care, may become an additional step toward ensuring quality care and improved resource utilization.

Acknowledgements

The authors thank Donna K. Lawson, LPN, for her assistance in data collection and management.

References

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Article PDF

Issue

Journal of Hospital Medicine - 3(3)

Publications

Page Number

218-227

Legacy Keywords

resource utilization, total knee arthroplasty, length of stay, hospital flow, multidisciplinary care

Read more about Costs and Arthroplasty

Sections

Author(s)

James M. Naessens, ScD, MPH

Mark T. Keegan, MD

Amy E. Wagie, BS

Author(s)

James M. Naessens, ScD, MPH

Mark T. Keegan, MD

Amy E. Wagie, BS

Article PDF

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MATERIALS AND METHODS

Study Design and Setting

Study Population

Variables and Definitions

Specialized Orthopedic Surgery Units

Table 1.Characteristics of Specialized Orthopedic Surgical Units and Nonorthopedic Nursing Units
	Specialized orthopedic surgical unit (SOS)	Nonorthopedic nursing unit (NON)
* RN, registered nurse.
Type of unit	Orthopedic general care unit.	General surgical care unit.
Patient type	Postoperative elective orthopedic only.	Any patientmedical or surgical.
Determinants of physical location for orthopedic patient	Primary bed assignment.	Admitted only if SOS units have reached full bed capacity.
Orthopedic‐trained nursing staff	Yesrequired to have additional post‐RN* training in orthopedics. These RNs rarely float to nonorthopedic units.	Nomay have additional training or experience in an unrelated medical or surgical discipline. Floating to other units may occur.
Orthopedic‐specific physical + occupational therapy	Provided by certified physical therapists trained in lower‐extremity joint procedures. Site‐based therapy available to all patients on SOS units.	Provided by certified physical therapists who do not necessarily have postoperative orthopedic lower‐extremity specialization. Site‐based therapy on NON unit available to all patients.
Licensed social workers	Dedicated to postoperative needs of orthopedic patients physically located on SOS units.	Not specifically dedicated to the postoperative elective orthopedic joint patient and not physically located on these units.
Interdisciplinary team meetings	Patient care addressed in a interdisciplinary team meeting 3 times weeklyconsists of an RN, physical and occupational therapists, social worker, and physician.	No care team meetings, as patients are off‐service.
Physician postoperative order set	Orthopedic‐specific order set that is available hospitalwide. Nursing staff on these units is familiar with these order sets.	Orthopedic‐specific order set available hospitalwide. Nursing staff on these units may not be entirely familiar with these order sets.
Rehabilitation protocols	Orthopedic specific.	Not orthopedic specific.
Patient‐care instructions	Orthopedic diagnosis‐specific instructions readily available	Orthopedic diagnosis‐specific instructions available but requires staff to obtain information and forms from the SOS inits.
Discharge protocol	Specifically targeted to the postarthroplasty patient	Generic hospitalwide protocol.
Hospital discharge summary	Yescowritten by primary orthopedic team and primary orthopedic RN.	Yescowritten by primary orthopedic team and nonorthopedic RN.
Orthopedic‐specific discharge instructions	Yescowritten by primary orthopedic team and primary orthopedic RN.	No.

Statistical Analysis

RESULTS

Table 2.Baseline Characteristics of Patients Undergoing Unilateral Primary Total Knee Arthroplasty (n = 5534)
	Specialized orthopedic surgery unit (n = 5082)		Nonorthopedic nursing unit (n = 452)		P value
	n	%	n	%	P value
All numbers are expressed as number of patients followed by percentage of patients, unless otherwise indicated. * Includes African American, Native American, and Asian. Includes patients who were unable to provide or refused to disclose this information. SD, standard deviation; AIDS, acquired immunodeficiency syndrome; ‖ ASA, American Society of Anesthesiologists.
Age (years)
<55	534	10.5%	57	12.6%
55‐64	1148	22.6%	101	22.4%
65‐69	802	15.8%	66	14.6%
70‐74	1106	21.8%	91	20.1%
>75	1492	29.4%	137	30.3%
Mean age ( SD*)	68.3 10.75		67.9 11.5		.50
Sex					.70
Male	2173	42.8%	189	41.8%
Female	2909	57.2%	263	58.2%
Race					.28
White	4731	93.1%	420	92.9%
Other*	51	1.0%	8	1.8%
Unknown	300	5.9%	24		5.3%
Local Olmsted County patients	772	15.2%	58	12.8%	.18
Indication for surgery					.03
Osteoarthritis	4778	94%	430	95.1%
Rheumatologic disease	184	3.6%	6	1.3%
Avascular necrosis	62	1.2%	5	1.1%
Congenital	6	0.1%	1	0.2%
Cancer	22	0.4%	5	1.1%
Other	30	0.6%	5	1.1%
Year of surgery					< .001
1996	497	98.8%	6	1.19%
1997	571	99.7%	2	0.35%
1998	479	98.8%	6	1.24%
1999	487	94.8%	27	5.25%
2000	458	92.7%	36	7.29%
2001	502	86.7%	77	13.3%
2002	593	89.2%	72	10.8%
2003	639	87.1%	95	12.9%
2004	856	86.7%	131	13.3%
Charlson score (mean SD)	0.256 0.536		0.288 0.593		.23
AIDS	0	0%	1	0.22%	1.00
Cancer	85	1.68%	7	1.55%	.84
Cerebrovascular disease	32	0.63%	0	0%	.09
Chronic pulmonary disease	28	5.63%	23	5.09%	.63
Congestive heart failure	89	1.75%	22	4.87%	< .001
Dementia	10	0.2%	2	0.44%	.28
Diabetes	603	11.9%	58	12.8%	.54
Hemiplegia	9	0.18%	0	0%	.37
Metastatic solid tumor	11	0.22%	2	0.44%	.34
Myocardial infarction	29	0.57%	4	0.88%	.4
Peripheral vascular disease	67	1.32%	4	0.88%	.43
Renal disease	52	1.02%	5	1.11%	.87
Rheumatologic disease	12	0.24%	2	0.44%	.40
Ulcers	15	0.3%	0	0%	.25
ASA class‖
I	99	2.0%	12	2.7%
II	2891	56.9%	255	56.4%
III	2084	41.0%	183	40.5%
IV	8	0.2%	2	0.4%
Average ASA class ( SD)	2.39 0.53		2.39 0.55		.80
Anesthesia type					.02
General	1644	32.4%	143	31.6%
Regional	2742	54%	226	50%
Combined	696	13.7%	83	18.4%

Table 3.Unadjusted and Adjusted Differences in Costs between Specialty Orthopedic Surgery Units and Nonorthopedic Surgery Units
	Unadjusted values					Adjusted values
	SOS*	SD	NON	SD	P value	Difference	SD	P value	95% CI
All cost data are represented as mean costs, representing costs from the time of discharge from the postanesthesia care unit to the time of hospital discharge. Adjusted data represent differences between the specialized orthopedic surgery unit (SOS) and the nonorthopedic nursing (NON) unit, after adjustment for age, sex, anesthesia, ASA class, and Charlson comorbidity. A positive adjusted dollar amount represents a cost savings relative to the NON unit. All values were rounded to the nearest dollar. P value < .05 is statistically significant. * SOS, specialty orthopedic surgery unit; NON, nonorthopedic nursing unit; SD, standard deviation; ICU, intensive care unit; ‖ E&M costs, evaluation and management; PT, physical therapy; ** OT, occupational therapy; RT, respiratory therapy; CI, confidence interval.
Total cost	$9989	$5392	$10,067	$5075	.77	$600	$244	.01	$122, $1079
Hospital costs	$9789	$5123	$ 9805	$4647	.23	$594	$231	.01	$141, $1047
Room & board	$4399	$1825	$ 4577	$1579	.04	$244	$ 87	.005	$ 72, $ 415
ICU costs	$ 58	$1094	$ 107	$ 682	.35	$ 11	$ 51	.82	$111, $ 88
Pharmacy	$ 851	$1701	$ 931	$1823	.34	$ 87	$ 85	.30	$ 79, $253
Laboratory costs	$ 386	$ 438	$ 395	$ 405	.65	$ 27	$ 20	.18	$ 12, $ 65
Radiology costs	$ 98	$ 205	$ 103	$ 183	.61	$ 1	$ 10	.93	$ 20, $ 19
PT/OT**/RT	$ 739	$ 505	$ 682	$ 394	.004	$ 15	$ 19	.45	$ 23, $ 52
Blood bank	$ 159	$ 306	$ 178	$3023	.22	$ 6	$ 15	.69	$ 35, $ 23
Physician costs	$ 207	$ 464	$ 258	$ 628	.09	$ 20	$ 22	.386	$ 24, $ 63
E&M costs‖	$ 89	$ 211	$ 109	$ 238	.09	$ 4	$ 9	.658	$ 23, $ 14
Physician radiology	$ 63	$ 158	$ 38	$ 192	.49	$ 2	$ 8	.78	$ 13, $ 18
Other costs	$ 34	$ 138	$ 37	$ 160	.61	$0.64	$ 6	.92	$ 13, $ 12

Table 4.Patient Disposition at Time of Discharge
	Specialized orthopedic surgery unit		Nonorthopedic nursing unit		P value
	n*	%	n	%	P value
* There were 5 in‐hospital deaths in the specialized orthopedic surgery unit group.
Home	3812	75%	328	72.6%	.252
Home health	235	4.62%	38	8.41%	< .001
Transferred to skilled nursing facility	1030	20.3%	86	19%	.529

DISCUSSION

Thirty‐Day Outcomes

Discharge Disposition

Role of Hospitalists in Specialized Care Pathways

Strengths and Applicability

Limitations

CONCLUSIONS

Acknowledgements

The authors thank Donna K. Lawson, LPN, for her assistance in data collection and management.

MATERIALS AND METHODS

Study Design and Setting

Study Population

Variables and Definitions

Specialized Orthopedic Surgery Units

Table 1.Characteristics of Specialized Orthopedic Surgical Units and Nonorthopedic Nursing Units
	Specialized orthopedic surgical unit (SOS)	Nonorthopedic nursing unit (NON)
* RN, registered nurse.
Type of unit	Orthopedic general care unit.	General surgical care unit.
Patient type	Postoperative elective orthopedic only.	Any patientmedical or surgical.
Determinants of physical location for orthopedic patient	Primary bed assignment.	Admitted only if SOS units have reached full bed capacity.
Orthopedic‐trained nursing staff	Yesrequired to have additional post‐RN* training in orthopedics. These RNs rarely float to nonorthopedic units.	Nomay have additional training or experience in an unrelated medical or surgical discipline. Floating to other units may occur.
Orthopedic‐specific physical + occupational therapy	Provided by certified physical therapists trained in lower‐extremity joint procedures. Site‐based therapy available to all patients on SOS units.	Provided by certified physical therapists who do not necessarily have postoperative orthopedic lower‐extremity specialization. Site‐based therapy on NON unit available to all patients.
Licensed social workers	Dedicated to postoperative needs of orthopedic patients physically located on SOS units.	Not specifically dedicated to the postoperative elective orthopedic joint patient and not physically located on these units.
Interdisciplinary team meetings	Patient care addressed in a interdisciplinary team meeting 3 times weeklyconsists of an RN, physical and occupational therapists, social worker, and physician.	No care team meetings, as patients are off‐service.
Physician postoperative order set	Orthopedic‐specific order set that is available hospitalwide. Nursing staff on these units is familiar with these order sets.	Orthopedic‐specific order set available hospitalwide. Nursing staff on these units may not be entirely familiar with these order sets.
Rehabilitation protocols	Orthopedic specific.	Not orthopedic specific.
Patient‐care instructions	Orthopedic diagnosis‐specific instructions readily available	Orthopedic diagnosis‐specific instructions available but requires staff to obtain information and forms from the SOS inits.
Discharge protocol	Specifically targeted to the postarthroplasty patient	Generic hospitalwide protocol.
Hospital discharge summary	Yescowritten by primary orthopedic team and primary orthopedic RN.	Yescowritten by primary orthopedic team and nonorthopedic RN.
Orthopedic‐specific discharge instructions	Yescowritten by primary orthopedic team and primary orthopedic RN.	No.

Statistical Analysis

RESULTS

Table 2.Baseline Characteristics of Patients Undergoing Unilateral Primary Total Knee Arthroplasty (n = 5534)
	Specialized orthopedic surgery unit (n = 5082)		Nonorthopedic nursing unit (n = 452)		P value
	n	%	n	%	P value
All numbers are expressed as number of patients followed by percentage of patients, unless otherwise indicated. * Includes African American, Native American, and Asian. Includes patients who were unable to provide or refused to disclose this information. SD, standard deviation; AIDS, acquired immunodeficiency syndrome; ‖ ASA, American Society of Anesthesiologists.
Age (years)
<55	534	10.5%	57	12.6%
55‐64	1148	22.6%	101	22.4%
65‐69	802	15.8%	66	14.6%
70‐74	1106	21.8%	91	20.1%
>75	1492	29.4%	137	30.3%
Mean age ( SD*)	68.3 10.75		67.9 11.5		.50
Sex					.70
Male	2173	42.8%	189	41.8%
Female	2909	57.2%	263	58.2%
Race					.28
White	4731	93.1%	420	92.9%
Other*	51	1.0%	8	1.8%
Unknown	300	5.9%	24		5.3%
Local Olmsted County patients	772	15.2%	58	12.8%	.18
Indication for surgery					.03
Osteoarthritis	4778	94%	430	95.1%
Rheumatologic disease	184	3.6%	6	1.3%
Avascular necrosis	62	1.2%	5	1.1%
Congenital	6	0.1%	1	0.2%
Cancer	22	0.4%	5	1.1%
Other	30	0.6%	5	1.1%
Year of surgery					< .001
1996	497	98.8%	6	1.19%
1997	571	99.7%	2	0.35%
1998	479	98.8%	6	1.24%
1999	487	94.8%	27	5.25%
2000	458	92.7%	36	7.29%
2001	502	86.7%	77	13.3%
2002	593	89.2%	72	10.8%
2003	639	87.1%	95	12.9%
2004	856	86.7%	131	13.3%
Charlson score (mean SD)	0.256 0.536		0.288 0.593		.23
AIDS	0	0%	1	0.22%	1.00
Cancer	85	1.68%	7	1.55%	.84
Cerebrovascular disease	32	0.63%	0	0%	.09
Chronic pulmonary disease	28	5.63%	23	5.09%	.63
Congestive heart failure	89	1.75%	22	4.87%	< .001
Dementia	10	0.2%	2	0.44%	.28
Diabetes	603	11.9%	58	12.8%	.54
Hemiplegia	9	0.18%	0	0%	.37
Metastatic solid tumor	11	0.22%	2	0.44%	.34
Myocardial infarction	29	0.57%	4	0.88%	.4
Peripheral vascular disease	67	1.32%	4	0.88%	.43
Renal disease	52	1.02%	5	1.11%	.87
Rheumatologic disease	12	0.24%	2	0.44%	.40
Ulcers	15	0.3%	0	0%	.25
ASA class‖
I	99	2.0%	12	2.7%
II	2891	56.9%	255	56.4%
III	2084	41.0%	183	40.5%
IV	8	0.2%	2	0.4%
Average ASA class ( SD)	2.39 0.53		2.39 0.55		.80
Anesthesia type					.02
General	1644	32.4%	143	31.6%
Regional	2742	54%	226	50%
Combined	696	13.7%	83	18.4%

Table 3.Unadjusted and Adjusted Differences in Costs between Specialty Orthopedic Surgery Units and Nonorthopedic Surgery Units
	Unadjusted values					Adjusted values
	SOS*	SD	NON	SD	P value	Difference	SD	P value	95% CI
All cost data are represented as mean costs, representing costs from the time of discharge from the postanesthesia care unit to the time of hospital discharge. Adjusted data represent differences between the specialized orthopedic surgery unit (SOS) and the nonorthopedic nursing (NON) unit, after adjustment for age, sex, anesthesia, ASA class, and Charlson comorbidity. A positive adjusted dollar amount represents a cost savings relative to the NON unit. All values were rounded to the nearest dollar. P value < .05 is statistically significant. * SOS, specialty orthopedic surgery unit; NON, nonorthopedic nursing unit; SD, standard deviation; ICU, intensive care unit; ‖ E&M costs, evaluation and management; PT, physical therapy; ** OT, occupational therapy; RT, respiratory therapy; CI, confidence interval.
Total cost	$9989	$5392	$10,067	$5075	.77	$600	$244	.01	$122, $1079
Hospital costs	$9789	$5123	$ 9805	$4647	.23	$594	$231	.01	$141, $1047
Room & board	$4399	$1825	$ 4577	$1579	.04	$244	$ 87	.005	$ 72, $ 415
ICU costs	$ 58	$1094	$ 107	$ 682	.35	$ 11	$ 51	.82	$111, $ 88
Pharmacy	$ 851	$1701	$ 931	$1823	.34	$ 87	$ 85	.30	$ 79, $253
Laboratory costs	$ 386	$ 438	$ 395	$ 405	.65	$ 27	$ 20	.18	$ 12, $ 65
Radiology costs	$ 98	$ 205	$ 103	$ 183	.61	$ 1	$ 10	.93	$ 20, $ 19
PT/OT**/RT	$ 739	$ 505	$ 682	$ 394	.004	$ 15	$ 19	.45	$ 23, $ 52
Blood bank	$ 159	$ 306	$ 178	$3023	.22	$ 6	$ 15	.69	$ 35, $ 23
Physician costs	$ 207	$ 464	$ 258	$ 628	.09	$ 20	$ 22	.386	$ 24, $ 63
E&M costs‖	$ 89	$ 211	$ 109	$ 238	.09	$ 4	$ 9	.658	$ 23, $ 14
Physician radiology	$ 63	$ 158	$ 38	$ 192	.49	$ 2	$ 8	.78	$ 13, $ 18
Other costs	$ 34	$ 138	$ 37	$ 160	.61	$0.64	$ 6	.92	$ 13, $ 12

Table 4.Patient Disposition at Time of Discharge
	Specialized orthopedic surgery unit		Nonorthopedic nursing unit		P value
	n*	%	n	%	P value
* There were 5 in‐hospital deaths in the specialized orthopedic surgery unit group.
Home	3812	75%	328	72.6%	.252
Home health	235	4.62%	38	8.41%	< .001
Transferred to skilled nursing facility	1030	20.3%	86	19%	.529

DISCUSSION

Thirty‐Day Outcomes

Discharge Disposition

Role of Hospitalists in Specialized Care Pathways

Strengths and Applicability

Limitations

CONCLUSIONS

Acknowledgements

The authors thank Donna K. Lawson, LPN, for her assistance in data collection and management.

References

Auerbach AD,Wachter RM,Katz P,Showstack J,Baron RB,Goldman L.Implementation of a voluntary hospitalist service at a community teaching hospital: improved clinical efficiency and patient outcomes.Ann Intern Med.2002;137:859–865.
Meltzer D,Manning WG,Morrison J, et al.Effects of physician experience on costs and outcomes on an academic general medicine service: results of a trial of hospitalists.Ann Intern Med.2002;137:866–874.
Huddleston JM,Long KH,Naessens JM, et al.Medical and surgical comanagement after elective hip and knee arthroplasty: a randomized, controlled trial.Ann Intern Med.2004;141:28–38.
Phy MP,Vanness DJ,Melton LJ, et al.Effects of a hospitalist model on elderly patients with hip fracture.Arch Intern Med.2005;165:796–801.
Grzybicki DM,Sullivan PJ,Oppy JM,Bethke AM,Raab SS.The economic benefit for family/general medicine practices employing physician assistants.Am J Manag Care.2002;8:613–620.
Moodie M,Cadilhac D,Pearce D, et al.Economic evaluation of Australian stroke services: a prospective, multicenter study comparing dedicated stroke units with other care modalities.Stroke.2006;37:2790–2795.
Rao AV,Hsieh F,Feussner JR,Cohen HJ.Geriatric evaluation and management units in the care of the frail elderly cancer patient.J Gerontol A Biol Sci Med Sci.2005;60:798–803.
Applegate WB,Miller ST,Graney MJ,Elam JT,Burns R,Akins DE.A randomized, controlled trial of a geriatric assessment unit in a community rehabilitation hospital.N Engl J Med.1990;322:1572–1578.
Spillman BC,Lubitz J.The effect of longevity on spending for acute and long‐term care.N Engl J Med.2000;342:1409–1415.
Heinegard D,Johnell O,Lidgren L, et al.The Bone and Joint Decade 2000‐2010.Acta Orthop Scand.1998;69:219–220.
Lohmander S.The Bone and Joint Decade 2000‐2010— for prevention and treatment of musculoskeletal disease.Osteoarthr Cartil.1998;7:1–4.
Prevalence of self‐reported arthritis or chronic joint symptoms among adults—United States, 2001.MMWR Morb Mortal Wkly Rep.2002;51:948–950.
Lawrence RC,Helmick CG,Arnett FC, et al.Estimates of the prevalence of arthritis and selected musculoskeletal disorders in the United States.Arthritis Rheum.1998;41:778–799.
HCUPnet, Healthcare Cost and Utilization Project. Agency for Healthcare Research and Quality, 2002. Available at: http://www.ahrq.gov. Accessed January 25,2005.
Rissanen P,Aro S,Sintonen H,Asikainen K,Slatis P,Paavolainen P.Costs and cost‐effectiveness in hip and knee replacements. A prospective study.Int J Technol Assess Health Care.1997;13:575–588.
Mehrotra C,Remington PL,Naimi TS,Washington W,Miller R.Trends in total knee replacement surgeries and implications for public health, 1990‐2000.Public Health Rep.2005;120:278–282.
Katz BP,Freund DA,Heck DA, et al.Demographic variation in the rate of knee replacement: a multi‐year analysis.Health Serv Res.1996;31:125–140.
Jain NB,Higgins LD,Guller U,Pietrobon R,Katz JN.Trends in the epidemiology of total shoulder arthroplasty in the United States from 1990‐2000.Arthritis Rheum.2006;55:591–597.
Hall M,DeFrances C.2001 National Hospital Discharge Survey.Adv Data.2003;332.
DeFrances CJ,Hall MJ.2002 National Hospital Discharge Survey.Adv Data.2004:1–29.
Woolhandler S,Campbell T,Himmelstein DU.Costs of health care administration in the United States and Canada.N Engl J Med2003;349:768–775.
Berry DJ,Kessler M,Morrey BF.Maintaining a hip registry for 25 years. Mayo Clinic experience.Clin Orthop Relat Res.1997:61–68.
Charlson M,Szatrowski TP,Peterson J,Gold J.Validation of a combined comorbidity index.J Clin Epidemiol.1994;47:1245–1251.
Charlson ME,Pompei P,Ales KL,MacKenzie CR.A new method of classifying prognostic comorbidity in longitudinal studies: development and validation.J Chronic Dis.1987;40:373–383.
Long KH,Bannon MP,Zietlow SP, et al.A prospective randomized comparison of laparoscopic appendectomy with open appendectomy: Clinical and economic analyses.Surgery.2001;129:390–400.
Wagner JL,Alberts SR,Sloan JA, et al.Incremental costs of enrolling cancer patients in clinical trials: a population‐based study.J Natl Cancer Inst.1999;91:847–853.
Barach P,Johnson JK.Understanding the complexity of redesigning care around the clinical microsystem.Qual Saf Health Care.2006;15(Suppl 1):i10–i16.
Husted H,Holm G,Rud K, et al.Length of stay after primary total hip and knee arthroplasty in Denmark, 2001‐2003.Ugeskr Laeger.2006;168:276–279.
Healy WL,Iorio R,Richards JA,Lucchesi C.Opportunities for control of hospital costs for total joint arthroplasty after initial cost containment.J Arthroplasty.1998;13:504–507.
Kim S,Losina E,Solomon DH,Wright J,Katz JN.Effectiveness of clinical pathways for total knee and total hip arthroplasty: literature review.J Arthroplasty.2003;18:69–74.
Macario A,Horne M,Goodman S, et al.The effect of a perioperative clinical pathway for knee replacement surgery on hospital costs.Anesth Analg.1998;86:978–984.
Scranton PEThe cost effectiveness of streamlined care pathways and product standardization in total knee arthroplasty.J Arthroplasty.1999;14:182–186.
Healy WL,Iorio R,Ko J,Appleby D,Lemos DW.Impact of cost reduction programs on short‐term patient outcome and hospital cost of total knee arthroplasty.J Bone Joint Surg Am.2002;84‐A:348–353.
Walter FL,Bass N,Bock G,Markel DC.Success of clinical pathways for total joint arthroplasty in a community hospital.Clin Orthop Relat Res.2007;457:133–137.
Fong Soohoo N,Zingmond DS,Lieberman JR,Ko CY.Optimal timeframe for reporting short‐term complication rates after total knee arthroplasty.J Arthroplasty.2006;21:705–711.
Kaboli PJ,Barnett MJ,Rosenthal GE.Associations with reduced length of stay and costs on an academic hospitalist service.Am J Manag Care.2004;10:561–568.
Wald H,Huddleston J,Kramer A.Is there a geriatrician in the house? Geriatric care approaches in hospitalist programs.J Hosp Med.2006;1:29–35.
Landefeld CS.Care of hospitalized older patients: opportunities for hospital‐based physicians.J Hosp Med.2006;1:42–47.
Batsis JA,Phy MP,Joseph Melton L, et al.Effects of a hospitalist care model on mortality of elderly patients with hip fractures.J Hosp Med.2007;2:219–225.
Dressler DD,Pistoria MJ,Budnitz TL,McKean SC,Amin AN.Core competencies in hospital medicine: development and methodology.J Hosp Med.2006;1:48–56.
Amadio PC,Naessens JM,Rice RL,Ilstrup DM,Evans RW,Morrey BF.Effect of feedback on resource use and morbidity in hip and knee arthroplasty in an integrated group practice setting.Mayo Clin Proc.1996;71:127–133.
Campbell H,Hotchkiss R,Bradshaw N,Porteous M.Integrated care pathways.BMJ.1998;316:133–137.

References

Auerbach AD,Wachter RM,Katz P,Showstack J,Baron RB,Goldman L.Implementation of a voluntary hospitalist service at a community teaching hospital: improved clinical efficiency and patient outcomes.Ann Intern Med.2002;137:859–865.
Meltzer D,Manning WG,Morrison J, et al.Effects of physician experience on costs and outcomes on an academic general medicine service: results of a trial of hospitalists.Ann Intern Med.2002;137:866–874.
Huddleston JM,Long KH,Naessens JM, et al.Medical and surgical comanagement after elective hip and knee arthroplasty: a randomized, controlled trial.Ann Intern Med.2004;141:28–38.
Phy MP,Vanness DJ,Melton LJ, et al.Effects of a hospitalist model on elderly patients with hip fracture.Arch Intern Med.2005;165:796–801.
Grzybicki DM,Sullivan PJ,Oppy JM,Bethke AM,Raab SS.The economic benefit for family/general medicine practices employing physician assistants.Am J Manag Care.2002;8:613–620.
Moodie M,Cadilhac D,Pearce D, et al.Economic evaluation of Australian stroke services: a prospective, multicenter study comparing dedicated stroke units with other care modalities.Stroke.2006;37:2790–2795.
Rao AV,Hsieh F,Feussner JR,Cohen HJ.Geriatric evaluation and management units in the care of the frail elderly cancer patient.J Gerontol A Biol Sci Med Sci.2005;60:798–803.
Applegate WB,Miller ST,Graney MJ,Elam JT,Burns R,Akins DE.A randomized, controlled trial of a geriatric assessment unit in a community rehabilitation hospital.N Engl J Med.1990;322:1572–1578.
Spillman BC,Lubitz J.The effect of longevity on spending for acute and long‐term care.N Engl J Med.2000;342:1409–1415.
Heinegard D,Johnell O,Lidgren L, et al.The Bone and Joint Decade 2000‐2010.Acta Orthop Scand.1998;69:219–220.
Lohmander S.The Bone and Joint Decade 2000‐2010— for prevention and treatment of musculoskeletal disease.Osteoarthr Cartil.1998;7:1–4.
Prevalence of self‐reported arthritis or chronic joint symptoms among adults—United States, 2001.MMWR Morb Mortal Wkly Rep.2002;51:948–950.
Lawrence RC,Helmick CG,Arnett FC, et al.Estimates of the prevalence of arthritis and selected musculoskeletal disorders in the United States.Arthritis Rheum.1998;41:778–799.
HCUPnet, Healthcare Cost and Utilization Project. Agency for Healthcare Research and Quality, 2002. Available at: http://www.ahrq.gov. Accessed January 25,2005.
Rissanen P,Aro S,Sintonen H,Asikainen K,Slatis P,Paavolainen P.Costs and cost‐effectiveness in hip and knee replacements. A prospective study.Int J Technol Assess Health Care.1997;13:575–588.
Mehrotra C,Remington PL,Naimi TS,Washington W,Miller R.Trends in total knee replacement surgeries and implications for public health, 1990‐2000.Public Health Rep.2005;120:278–282.
Katz BP,Freund DA,Heck DA, et al.Demographic variation in the rate of knee replacement: a multi‐year analysis.Health Serv Res.1996;31:125–140.
Jain NB,Higgins LD,Guller U,Pietrobon R,Katz JN.Trends in the epidemiology of total shoulder arthroplasty in the United States from 1990‐2000.Arthritis Rheum.2006;55:591–597.
Hall M,DeFrances C.2001 National Hospital Discharge Survey.Adv Data.2003;332.
DeFrances CJ,Hall MJ.2002 National Hospital Discharge Survey.Adv Data.2004:1–29.
Woolhandler S,Campbell T,Himmelstein DU.Costs of health care administration in the United States and Canada.N Engl J Med2003;349:768–775.
Berry DJ,Kessler M,Morrey BF.Maintaining a hip registry for 25 years. Mayo Clinic experience.Clin Orthop Relat Res.1997:61–68.
Charlson M,Szatrowski TP,Peterson J,Gold J.Validation of a combined comorbidity index.J Clin Epidemiol.1994;47:1245–1251.
Charlson ME,Pompei P,Ales KL,MacKenzie CR.A new method of classifying prognostic comorbidity in longitudinal studies: development and validation.J Chronic Dis.1987;40:373–383.
Long KH,Bannon MP,Zietlow SP, et al.A prospective randomized comparison of laparoscopic appendectomy with open appendectomy: Clinical and economic analyses.Surgery.2001;129:390–400.
Wagner JL,Alberts SR,Sloan JA, et al.Incremental costs of enrolling cancer patients in clinical trials: a population‐based study.J Natl Cancer Inst.1999;91:847–853.
Barach P,Johnson JK.Understanding the complexity of redesigning care around the clinical microsystem.Qual Saf Health Care.2006;15(Suppl 1):i10–i16.
Husted H,Holm G,Rud K, et al.Length of stay after primary total hip and knee arthroplasty in Denmark, 2001‐2003.Ugeskr Laeger.2006;168:276–279.
Healy WL,Iorio R,Richards JA,Lucchesi C.Opportunities for control of hospital costs for total joint arthroplasty after initial cost containment.J Arthroplasty.1998;13:504–507.
Kim S,Losina E,Solomon DH,Wright J,Katz JN.Effectiveness of clinical pathways for total knee and total hip arthroplasty: literature review.J Arthroplasty.2003;18:69–74.
Macario A,Horne M,Goodman S, et al.The effect of a perioperative clinical pathway for knee replacement surgery on hospital costs.Anesth Analg.1998;86:978–984.
Scranton PEThe cost effectiveness of streamlined care pathways and product standardization in total knee arthroplasty.J Arthroplasty.1999;14:182–186.
Healy WL,Iorio R,Ko J,Appleby D,Lemos DW.Impact of cost reduction programs on short‐term patient outcome and hospital cost of total knee arthroplasty.J Bone Joint Surg Am.2002;84‐A:348–353.
Walter FL,Bass N,Bock G,Markel DC.Success of clinical pathways for total joint arthroplasty in a community hospital.Clin Orthop Relat Res.2007;457:133–137.
Fong Soohoo N,Zingmond DS,Lieberman JR,Ko CY.Optimal timeframe for reporting short‐term complication rates after total knee arthroplasty.J Arthroplasty.2006;21:705–711.
Kaboli PJ,Barnett MJ,Rosenthal GE.Associations with reduced length of stay and costs on an academic hospitalist service.Am J Manag Care.2004;10:561–568.
Wald H,Huddleston J,Kramer A.Is there a geriatrician in the house? Geriatric care approaches in hospitalist programs.J Hosp Med.2006;1:29–35.
Landefeld CS.Care of hospitalized older patients: opportunities for hospital‐based physicians.J Hosp Med.2006;1:42–47.
Batsis JA,Phy MP,Joseph Melton L, et al.Effects of a hospitalist care model on mortality of elderly patients with hip fractures.J Hosp Med.2007;2:219–225.
Dressler DD,Pistoria MJ,Budnitz TL,McKean SC,Amin AN.Core competencies in hospital medicine: development and methodology.J Hosp Med.2006;1:48–56.
Amadio PC,Naessens JM,Rice RL,Ilstrup DM,Evans RW,Morrey BF.Effect of feedback on resource use and morbidity in hip and knee arthroplasty in an integrated group practice setting.Mayo Clin Proc.1996;71:127–133.
Campbell H,Hotchkiss R,Bradshaw N,Porteous M.Integrated care pathways.BMJ.1998;316:133–137.

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Journal of Hospital Medicine - 3(3)

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Journal of Hospital Medicine - 3(3)

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218-227

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218-227

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Resource utilization of total knee arthroplasty patients cared for on specialty orthopedic surgery units

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Resource utilization of total knee arthroplasty patients cared for on specialty orthopedic surgery units

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resource utilization, total knee arthroplasty, length of stay, hospital flow, multidisciplinary care

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resource utilization, total knee arthroplasty, length of stay, hospital flow, multidisciplinary care

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Effects of a hospitalist care model on mortality of elderly patients with hip fractures

Author(s)

Because the incidence of hip fracture increases dramatically with age and the elderly are the fastest‐growing portion of the United States population, the number of hip fractures is expected to triple by 2040.1 With the associated increase in postoperative morbidity and mortality, the costs will likely exceed $16‐$20 billion annually.15 Already by 2002, the number of patients with hip fractures exceeded 340,000 in this country, resulting in $8.6 billion in health care expenditures from in‐hospital and posthospital costs.68 This makes hip fracture a serious public health concern and triggers a need to devise an efficient means of caring for these patients. We previously reported that a hospitalist service can decrease time to surgery and shorten length of stay without affecting the number of inpatient deaths or 30‐day readmissions of patients undergoing hip fracture surgery.9 However, one concern with reducing length of stay and time to surgery in the high‐risk hip fracture patient population is the effect on long‐term mortality because the death rate following hip fracture repair may be as high as 43% after 1 year.10 To evaluate this important issue, we assessed mortality over a 1‐year period in the same cohort of patients previously described.9 We also identified predictors associated with mortality. We hypothesized that the expedited surgical treatment and decreased length of stay of a hospitalist‐managed group would not have an adverse effect on 1‐year mortality.

METHODS

Patient Selection

Following approval by the Mayo Clinic Institutional Review Board, we used the Mayo Clinic Surgical Index to identify patients admitted between July 1, 2000, and June 30, 2002, who matched International Classification of Diseases (9th Edition) hip fracture codes.11 These patients were cross‐referenced with those having a primary surgical indication of hip fracture. Patients transferred to our facility more than 72 hours after fracture were excluded from our study. Study patients provided authorization to use their medical records for the purposes of research.

A cohort of 466 patients was identified. For purposes of comparison, patients admitted between July 1, 2000, and June 30, 2001, were deemed to belong to the standard care service, and patients admitted between July 1, 2001, and June 30, 2002, were deemed part of the hospitalist service.

Intervention

Prior to July 2001, Mayo Clinic patients aged 65 and older having surgical repair of a hip fracture were triaged directly to a surgical orthopedic or general medical teaching service. Patients with multiple medical diagnoses were managed initially on a medical teaching service prior to transfer to the operating room. The primary team (medical or surgical) was responsible for the postoperative care of the patient and any orders or consultations required.

After July 1, 2001, these patients were admitted by the orthopedic surgery service and medically comanaged by a hospitalist service, which consisted of a hospitalist physician and 2 allied‐health practitioners. Twelve hospitalists and 12 allied health care professionals cared for patients during the study period. All preoperative and postoperative evaluations, inpatient management decisions, and coordination of outpatient care were performed by the hospitalists. This model of care is similar to one previously studied and published elsewhere.12 A census cap of 20 patients limited the number of patients managed by the hospitalist service. Any overflow of hip fracture patients was triaged directly to a non‐hospitalist‐based primary medical or surgical service as before. Thus, 23 hip fracture patients (10%) admitted after July 1, 2001, were not managed by the hospitalists but are included in this group for an intent‐to‐treat analysis.

Data Collection

Study nurses abstracted all data including admitting diagnoses, demographic features, type and mechanism of hip fracture, admission date and time, American Society of Anesthesia (ASA) class, comorbid medical conditions, medications, all clinical data, and readmission rates. Date of last follow‐up was confirmed using the Mayo Clinic medical record, whereas date and cause of death were obtained from death certificates obtained from state and national sources. Length of stay was defined as the number of days between admission and discharge. Time to surgery was defined in hours as the time from hospital admission to the start of the surgery. Finally, time from surgery to dismissal was defined as the number of days from the initiation of the surgical procedure to the time of dismissal. Thirty‐day readmission was defined as readmission to our hospital within 30 days of discharge date.

Statistical Considerations

Power

The power analysis was based on the end point of survival following surgical repair of hip fracture and primary comparison of patients in the standard care group with those in the hospitalist group. With 236 patients in the standard care group, 230 in the hospitalist group, and 274 observed deaths during the follow‐up period, there was 80% power to detect a hazard ratio of 1.4 or greater as being statistically significant (alpha = 0.05, beta = 0.2).

Analysis

The analysis focused on the end point of survival following surgical repair of hip fracture. In addition to the hospitalist versus standard care service, demographic, baseline clinical, and in‐hospital data were evaluated as potential predictors of survival. Survival rates were estimated using the method of Kaplan and Meier, and relative differences in survival were evaluated using the Cox proportional hazards regression models.13, 14 Potential predictors were analyzed both univariately and in a multivariable model. For the multivariable model, initial variable selection was accomplished using stepwise selection, backward elimination, and recursive partitioning.15 Each method yielded similar results. Bootstrap resampling was then used to confirm the variables selected for each model.16, 17 The threshold of statistical significance was set at P = .05 for all tests. All analyses were conducted in SAS version 8.2 (SAS Institute Inc., Cary, NC) and Splus version 6.2.1 (Insightful Corporation, Seattle, WA).

RESULTS

There were 236 patients with hip fractures (50.6%) admitted to the standard care service, and 230 patients (49.4%) admitted to the hospitalist service. As shown in Table 1, the baseline characteristics of the patients admitted to the 2 services did not differ significantly except that a greater proportion of patients with hypoxia were admitted to the hospitalist service (11.3% vs. 5.5%; P = .02). However, time to surgery, postsurgery stay, and overall length of hospitalization of the hospitalist‐treated patients were all significantly shorter.

Table 1.Characteristics of 466 Hip Fracture Patients at Time of Admission
Patient characteristic	Standard care n = 236		Hospitalist care n = 230		P value
* American Society of Anesthesia. 18 Inpatient deaths were excluded. From Phy MP, Vanness DJ, Melton LJ 3rd, et al. Effects of a hospitalist care model on elderly patients with hip fractures. Arch Intern Med. 2005;165:796‐801. Permission obtained from American Medical Association/Copyright 2005. All rights reserved.
Age (years)	82		83		.34
Female sex	171	72.5%	163	70.9%	.70
Comorbidity
Coronary artery disease	69	29.2%	77	33.5%	.32
Congestive heart failure	41	17.4%	49	21.3%	.28
Chronic obstructive pulmonary disease	36	15.3%	38	16.5%	.71
Cerebral vascular accident or transient ischemic attack	36	15.3%	50	21.7%	.07
Dementia	54	22.9%	62	27.0%	.31
Diabetes	45	19.1%	46	20.0%	.80
Renal insufficiency	17	7.2%	17	7.4%	.94
Residence at time of admission					.07
Home	149	63.1%	138	60.0%
Assisted living	32	13.6%	42	18.3%
Nursing home	55	23.3%	50	21.7%
Ambulatory status at time of admission					.14
Independent	114	48.3%	89	38.7%
Assistive device	99	41.9%	115	50.0%
Personal help	9	3.8%	16	7.0%
Transfer to bed or chair	9	3.8%	7	3.0%
Nonambulatory	5	2.1%	3	1.3%
Signs at time of admission
Hypotension	4	1.7%	3	1.3%	> .99
Hypoxia	13	5.5%	26	11.3%	.02
Pulmonary edema	37	15.7%	29	12.6%	.34
Tachycardia	19	8.1%	25	10.9%	.3
Fracture type					.78
Femoral neck	118	50.0%	118	51.3%
Intertrochanteric	118	50.0%	112	48.7%
Mechanism of fracture					.82
Fall	219	92.8%	212	92.2%
Trauma	1	0.4%	3	1.3%
Pathologic	7	3.0%	6	2.6%
Unknown	9	3.8%	7	3.0%
ASA* class					.38
I or II	33	14.0%	23	10.0%
III	166	70.3%	166	72.2%
IV	37	15.7%	41	17.8%
Location discharged to					.07
Home or assisted living	24	10.5%	13	5.9%
Nursing home	196	86.0%	192	87.3%
Another hospital or hospice	8	3.5%	15	6.8%
Time to surgery (hours)	38		25		.001
Time from surgery to discharge (days)	9		7		.04
Length of stay	10.6		8.4		< .00
Readmission rate	25	10.6%	20	8.7%	.49

Patients were followed for a median of 4.0 years (range 5 days to 5.6 years), and 192 patients were still alive at the end of follow‐up (April 2006). As illustrated in Figure 1, survival did not differ between the 2 treatment groups (P = .36). Overall survival at 1 year was 70.6% (95% confidence interval [CI]: 66.5%, 74.9%). Survival at 1 year in the standard care group was 70.6% (95% CI: 64.9%, 76.8%), whereas in the hospitalist group, it was 70.5% (95% CI: 64.8%, 76.7%). As delineated in Table 2, cardiovascular causes accounted for 34 deaths (25.6%), with 14 of these in the standard care group and 20 in the hospitalist group; 29 deaths (21.8%) had respiratory causes, 20 in the standard care group and 9 in the hospitalist group; and 17 (12.8%) were due to cancer, with 7 and 10 in the standard care and hospitalist groups, respectively. Unknown causes accounted for 21 cases, or 15.8% of total deaths.

Survival following original hip fracture repair of 230 patients receiving hospitalist care and 236 patients receiving standard care. [Color figure can be viewed in the online issue, which is available at www.interscience.wiley.com]

Table 2.Certified Underlying Cause of Death as Recorded on Death Certificates after 1 Year of Following Patients with Hip Fractures
	Standard care	Hospitalist care	Total No. of deaths	%
Cancer	7	10	17	12.8%
Cardiovascular	14	20	34	25.6%
Infectious	5	4	9	6.8%
Neurological	5	10	15	11.3%
Other	0	2	2	1.5%
Renal	4	2	6	4.5%
Respiratory	20	9	29	21.8%
Unknown	11	10	21	15.8%
Total	66	67	133	100.0%

In the univariate analysis, we found 29 variables that were significant predictors of survival (Table 3). A hospitalist model of care was not significantly associated with patient survival, despite the shorter length of stay (8.4 days vs. 10.6 days; P < .001) or expedited time to surgery (25 vs. 38 hours; P < .001), when compared with the standard care group, as previously reported by Phy et al.9 In the multivariable analysis (Table 4), however, the independent predictors of mortality were ASA class III or IV versus class II (hazard ratio [HR] 4.20; 95% CI: 2.21, 7.99), admission from a nursing home versus from home or assisted living (HR 2.24; 95% CI: 1.73, 2.90), and inpatient complications, which included patients requiring admission to the intensive care unit (ICU) and those who had a myocardial infarction or acute renal failure as an inpatient (HR 1.85; 95% CI: 1.45, 2.35). Even after adjusting for these factors, survival following hip fracture did not differ significantly between the hospitalist care patients and the standard care patients (HR 1.16; 95% CI: 0.91, 1.48).

Table 3.Univariate Predictors of Mortality 1 year after Surgical Repair of Hip Fracture
Variable	Hazard ratio (95% CI)	P value
* American Society of Anesthesia; confidence interval.
Age on admission per 10 years	1.41 (1.20, 1.65)	< .001
ASA* II	1.0 (referent)
ASA* III	5.27 (2.79, 9.96)	< .001
ASA* IV	11.7 (5.97, 22.9)	< .001
History of chronic obstructive pulmonary disease	1.82 (1.35, 2.43)	< .001
History of renal insufficiency	2.40 (1.62,3.55)	< .001
History of stroke/transient ischemic attack	1.46 (1.10, 1.95)	.01
History of diabetes	1.70 (1.29,2.25)	< .001
History of congestive heart failure	2.26 (1.73, 2.96)	< .001
History of coronary artery disease	1.53 (1.20, 1.97)	< .001
History of dementia	2.02 (1.57, 2.59)	< .001
Admission from home	1.0 (referent)
Admission from assisted living	1.47 (1.06, 2.04)	.02
Admission from nursing home	3.04 (2.33, 3.98)	< .001
Independent	1.0 (referent)
Use of assistive device	1.81 (1.39, 2.36)	< .001
Personal help	3.49 (2.16, 5.64)	< .001
Nonambulatory	3.96 (2.47, 6.35)	< .001
Crackles on admission	2.03 (1.50, 2.74)	< .001
Hypoxia on admission	1.56 (1.04, 2.32)	.03
Hypotension on admission	6.21 (2.72, 14.2)	< .001
Tachycardia on admission	1.66 (1.15, 2.41)	.007
Coumadin on admission	1.57 (1.13, 2.18)	.007
Confusion/unconsciousness on admission	2.23 (1.74, 2.87)	< .001
Fever on admission	1.98 (1.16, 3.40)	.01
Tachypnea on admission	1.95 (1.39, 2.72)	< .001
Inpatient myocardial Infarction	3.59 (2.35, 5.48)	< .001
Inpatient atrial fibrillation	2.00 (1.37, 2.92)	< .001
Inpatient congestive heart failure	2.62 (1.79, 3.84)	< .0001
Inpatient delirium	1.46 (1.13, 1.90)	< .005
Inpatient lung infection	2.52 (1.85, 3.42)	< .001
Inpatient respiratory failure	2.76 (1.64, 4.66)	< .001
Inpatient mechanical ventilation	2.56 (1.43, 4.57)	.002
Inpatient renal failure	3.60 (1.97, 6.61)	< .001
Days from admission to surgery	1.06 (1.005, 1.12)	.03
Intensive care unit stay	1.93 (1.51, 2.47)	< .001

Table 4.Multivariable Predictors of Survival Following Surgical Repair of Hip Fracture
Variable	Hazard ratio (95% CI)	P value
* American Society of Anesthesia; Confidence interval.
Age on admission per 10 years	1.17 (0.99, 1.38)	.07
ASA* class III or IV	4.20 (2.21, 7.99)	< .001
ASA* class II	1.0 (referent)
Admission from nursing home	2.24 (1.73, 2.90)	< .001
Admission from home or assisted living	1.0 (referent)
Inpatient myocardial infarction, inpatient acute renal failure, or intensive care unit stay	1.85 (1.45, 2.35)	< .001
No inpatient myocardial infarction, no inpatient acute renal failure, and no intensive care unit stay	1.0 (referent)

DISCUSSION

In our previous study, length of stay and time to surgery were significantly lower in a hospitalist care model.9 The present study shows that neither the reduced length of stay nor the shortened time to surgery of patients managed by the hospitalist group was associated with a difference in mortality compared with a standard care group, despite significantly improved efficiency and processes of care. Thus, our results refute initial concerns of increased mortality in a hospitalist model of care.

Delivery of perioperative medical care to hip fracture patients by hospitalists is associated with significant decreases in time to surgery and length of stay compared with standard care, with no differences in short‐term mortality.9, 18 Although there have been conflicting reports on the impact of length of stay and time to surgery on long‐term outcomes, our findings support previous results that decreased time to surgery was not associated with an observable effect on mortality.1923 A recent study by Orosz et al. that evaluated 1178 patients showed that earlier hip fracture surgery (performed less than 24 hours after admission) was not associated with reduced mortality, although it was associated with shorter length of stay.19 Our study also corroborates the results of an examination of 8383 hip fracture patients by Grimes et al., who found that time to surgery between 24 and 48 hours after admission had no effect on either 30‐day or long‐term mortality compared with that of those who underwent surgery between 48 and 72 hours, between 72 and 96 hours, or more than 96 hours after admission.20 However, both these results and our own are contrary to those of Gdalevich, whose study of 651 patients found that 1‐year mortality was 1.6‐fold higher for those whose hip fracture repair was postponed more than 48 hours.21 However, time to surgery in both the standard care and hospitalist model in our study was well below the 48‐hour cutoff, suggesting that operating anywhere within the normally accepted 48‐hour time frame may not influence long‐term mortality.

Because of the small number of events in both groups, we were unable to specifically compare whether a hospitalist model of care has any specific impact on long‐term cause of death. Although causes of death of patients with hip fracture were consistent with those of previous studies,10, 24 our death rate at 1 year, 29.4%, was higher than that seen among similar population groups at tertiary referral centers.19, 20, 2429 This is most likely a result of the cohort having a high proportion of nursing home patients (22%)19, 24, 26 transferred for evaluation to St. Mary's Hospital, which serves most of Olmsted County, Minnesota. This hospital also has some characteristics of a community‐based hospital, as it is where greater than 95% of all county patients receive care for surgical repair of hip fracture. Mortality rates are often higher at these types of hospitals.30 Previous studies using patients from Olmsted County indicate results can also be extrapolated to a large part of the U.S. population.31 In Pitto et al.'s study, the risk of death was 31% lower in those admitted from home than for those admitted from a nursing home.32 The latter patients normally have a higher number of comorbid conditions and tend to be less ambulatory than those in a community home‐dwelling setting. Our study also demonstrated that admission from a nursing home was a strong predictor of mortality for up to 1 year in the geriatric population. This may reflect the inherent decreased survival in this patient group, which is in agreement with the findings of other studies that showed inactivity and decreased ambulation prior to fracture were associated with increased mortality.3335

Multiple comorbidities, commonly seen in a geriatric population, translate into a higher ASA class and an increased risk of significant in‐hospital complications. Our study confirmed the findings of previous studies that a higher ASA class is a strong predictor of mortality,21, 26, 30, 3537 independent of decreased time to surgery.38 We also noted that significant in‐hospital complications, including renal failure, respiratory failure, and myocardial infarction, are documented predictors of mortality after hip fracture.27 Although mortality may vary depending on fracture type (femoral neck vs. intertrochanteric),3941 these differences were not observed in our study, in line with the results of previous published studies.37, 42 Controlling for age and comorbidities may be why an association was not found between fracture type and mortality. Finally, in a model containing comorbidity, ASA class, and nursing home residence prior to fracture, age was not a significant predictor of mortality.

Our study had a number of limitations. First, this was a retrospective cohort study based on chart review, so some data may have been subject to recording bias, and this might have differed between the serial models. Because of the retrospective nature of the study and referral of some of the patients from outside the community, our 1‐year follow‐up was not complete, but approached a respectable 93%. Other studies have described the benefits derived by a hospitalist practice only following the first year of its implementation, likely because of the hospitalist learning curve.43, 44 This may be why there was no difference in mortality between the standard care and hospitalist groups, as the latter was only in its first year of existence. Additional longitudinal study is required to find out if mortality differences emerge between the treatment groups. Furthermore, although in‐hospital care may influence short‐term outcomes, its effect on long‐term mortality has been unclear. Our data demonstrate that even though a hospitalist service can shorten length of stay and time to surgery, there were no appreciable intermediate differences in mortality at 1 year. Further prospective studies are needed to determine whether this medical‐surgical partnership in caring for these patients provides more favorable outcomes of reducing mortality and intercurrent complications.

Acknowledgements

We thank Donna K. Lawson for her assistance in data collection and management.

References

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Journal of Hospital Medicine - 2(4)

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Page Number

219-225

Legacy Keywords

hospitalist as consultant, geriatric patient, osteoporosis, post‐operative evaluation

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METHODS

Patient Selection

Intervention

Data Collection

Statistical Considerations

Power

Analysis

RESULTS

Table 1.Characteristics of 466 Hip Fracture Patients at Time of Admission
Patient characteristic	Standard care n = 236		Hospitalist care n = 230		P value
* American Society of Anesthesia. 18 Inpatient deaths were excluded. From Phy MP, Vanness DJ, Melton LJ 3rd, et al. Effects of a hospitalist care model on elderly patients with hip fractures. Arch Intern Med. 2005;165:796‐801. Permission obtained from American Medical Association/Copyright 2005. All rights reserved.
Age (years)	82		83		.34
Female sex	171	72.5%	163	70.9%	.70
Comorbidity
Coronary artery disease	69	29.2%	77	33.5%	.32
Congestive heart failure	41	17.4%	49	21.3%	.28
Chronic obstructive pulmonary disease	36	15.3%	38	16.5%	.71
Cerebral vascular accident or transient ischemic attack	36	15.3%	50	21.7%	.07
Dementia	54	22.9%	62	27.0%	.31
Diabetes	45	19.1%	46	20.0%	.80
Renal insufficiency	17	7.2%	17	7.4%	.94
Residence at time of admission					.07
Home	149	63.1%	138	60.0%
Assisted living	32	13.6%	42	18.3%
Nursing home	55	23.3%	50	21.7%
Ambulatory status at time of admission					.14
Independent	114	48.3%	89	38.7%
Assistive device	99	41.9%	115	50.0%
Personal help	9	3.8%	16	7.0%
Transfer to bed or chair	9	3.8%	7	3.0%
Nonambulatory	5	2.1%	3	1.3%
Signs at time of admission
Hypotension	4	1.7%	3	1.3%	> .99
Hypoxia	13	5.5%	26	11.3%	.02
Pulmonary edema	37	15.7%	29	12.6%	.34
Tachycardia	19	8.1%	25	10.9%	.3
Fracture type					.78
Femoral neck	118	50.0%	118	51.3%
Intertrochanteric	118	50.0%	112	48.7%
Mechanism of fracture					.82
Fall	219	92.8%	212	92.2%
Trauma	1	0.4%	3	1.3%
Pathologic	7	3.0%	6	2.6%
Unknown	9	3.8%	7	3.0%
ASA* class					.38
I or II	33	14.0%	23	10.0%
III	166	70.3%	166	72.2%
IV	37	15.7%	41	17.8%
Location discharged to					.07
Home or assisted living	24	10.5%	13	5.9%
Nursing home	196	86.0%	192	87.3%
Another hospital or hospice	8	3.5%	15	6.8%
Time to surgery (hours)	38		25		.001
Time from surgery to discharge (days)	9		7		.04
Length of stay	10.6		8.4		< .00
Readmission rate	25	10.6%	20	8.7%	.49

Table 2.Certified Underlying Cause of Death as Recorded on Death Certificates after 1 Year of Following Patients with Hip Fractures
	Standard care	Hospitalist care	Total No. of deaths	%
Cancer	7	10	17	12.8%
Cardiovascular	14	20	34	25.6%
Infectious	5	4	9	6.8%
Neurological	5	10	15	11.3%
Other	0	2	2	1.5%
Renal	4	2	6	4.5%
Respiratory	20	9	29	21.8%
Unknown	11	10	21	15.8%
Total	66	67	133	100.0%

Table 3.Univariate Predictors of Mortality 1 year after Surgical Repair of Hip Fracture
Variable	Hazard ratio (95% CI)	P value
* American Society of Anesthesia; confidence interval.
Age on admission per 10 years	1.41 (1.20, 1.65)	< .001
ASA* II	1.0 (referent)
ASA* III	5.27 (2.79, 9.96)	< .001
ASA* IV	11.7 (5.97, 22.9)	< .001
History of chronic obstructive pulmonary disease	1.82 (1.35, 2.43)	< .001
History of renal insufficiency	2.40 (1.62,3.55)	< .001
History of stroke/transient ischemic attack	1.46 (1.10, 1.95)	.01
History of diabetes	1.70 (1.29,2.25)	< .001
History of congestive heart failure	2.26 (1.73, 2.96)	< .001
History of coronary artery disease	1.53 (1.20, 1.97)	< .001
History of dementia	2.02 (1.57, 2.59)	< .001
Admission from home	1.0 (referent)
Admission from assisted living	1.47 (1.06, 2.04)	.02
Admission from nursing home	3.04 (2.33, 3.98)	< .001
Independent	1.0 (referent)
Use of assistive device	1.81 (1.39, 2.36)	< .001
Personal help	3.49 (2.16, 5.64)	< .001
Nonambulatory	3.96 (2.47, 6.35)	< .001
Crackles on admission	2.03 (1.50, 2.74)	< .001
Hypoxia on admission	1.56 (1.04, 2.32)	.03
Hypotension on admission	6.21 (2.72, 14.2)	< .001
Tachycardia on admission	1.66 (1.15, 2.41)	.007
Coumadin on admission	1.57 (1.13, 2.18)	.007
Confusion/unconsciousness on admission	2.23 (1.74, 2.87)	< .001
Fever on admission	1.98 (1.16, 3.40)	.01
Tachypnea on admission	1.95 (1.39, 2.72)	< .001
Inpatient myocardial Infarction	3.59 (2.35, 5.48)	< .001
Inpatient atrial fibrillation	2.00 (1.37, 2.92)	< .001
Inpatient congestive heart failure	2.62 (1.79, 3.84)	< .0001
Inpatient delirium	1.46 (1.13, 1.90)	< .005
Inpatient lung infection	2.52 (1.85, 3.42)	< .001
Inpatient respiratory failure	2.76 (1.64, 4.66)	< .001
Inpatient mechanical ventilation	2.56 (1.43, 4.57)	.002
Inpatient renal failure	3.60 (1.97, 6.61)	< .001
Days from admission to surgery	1.06 (1.005, 1.12)	.03
Intensive care unit stay	1.93 (1.51, 2.47)	< .001

Table 4.Multivariable Predictors of Survival Following Surgical Repair of Hip Fracture
Variable	Hazard ratio (95% CI)	P value
* American Society of Anesthesia; Confidence interval.
Age on admission per 10 years	1.17 (0.99, 1.38)	.07
ASA* class III or IV	4.20 (2.21, 7.99)	< .001
ASA* class II	1.0 (referent)
Admission from nursing home	2.24 (1.73, 2.90)	< .001
Admission from home or assisted living	1.0 (referent)
Inpatient myocardial infarction, inpatient acute renal failure, or intensive care unit stay	1.85 (1.45, 2.35)	< .001
No inpatient myocardial infarction, no inpatient acute renal failure, and no intensive care unit stay	1.0 (referent)

DISCUSSION

Acknowledgements

We thank Donna K. Lawson for her assistance in data collection and management.

METHODS

Patient Selection

Intervention

Data Collection

Statistical Considerations

Power

Analysis

RESULTS

Table 1.Characteristics of 466 Hip Fracture Patients at Time of Admission
Patient characteristic	Standard care n = 236		Hospitalist care n = 230		P value
* American Society of Anesthesia. 18 Inpatient deaths were excluded. From Phy MP, Vanness DJ, Melton LJ 3rd, et al. Effects of a hospitalist care model on elderly patients with hip fractures. Arch Intern Med. 2005;165:796‐801. Permission obtained from American Medical Association/Copyright 2005. All rights reserved.
Age (years)	82		83		.34
Female sex	171	72.5%	163	70.9%	.70
Comorbidity
Coronary artery disease	69	29.2%	77	33.5%	.32
Congestive heart failure	41	17.4%	49	21.3%	.28
Chronic obstructive pulmonary disease	36	15.3%	38	16.5%	.71
Cerebral vascular accident or transient ischemic attack	36	15.3%	50	21.7%	.07
Dementia	54	22.9%	62	27.0%	.31
Diabetes	45	19.1%	46	20.0%	.80
Renal insufficiency	17	7.2%	17	7.4%	.94
Residence at time of admission					.07
Home	149	63.1%	138	60.0%
Assisted living	32	13.6%	42	18.3%
Nursing home	55	23.3%	50	21.7%
Ambulatory status at time of admission					.14
Independent	114	48.3%	89	38.7%
Assistive device	99	41.9%	115	50.0%
Personal help	9	3.8%	16	7.0%
Transfer to bed or chair	9	3.8%	7	3.0%
Nonambulatory	5	2.1%	3	1.3%
Signs at time of admission
Hypotension	4	1.7%	3	1.3%	> .99
Hypoxia	13	5.5%	26	11.3%	.02
Pulmonary edema	37	15.7%	29	12.6%	.34
Tachycardia	19	8.1%	25	10.9%	.3
Fracture type					.78
Femoral neck	118	50.0%	118	51.3%
Intertrochanteric	118	50.0%	112	48.7%
Mechanism of fracture					.82
Fall	219	92.8%	212	92.2%
Trauma	1	0.4%	3	1.3%
Pathologic	7	3.0%	6	2.6%
Unknown	9	3.8%	7	3.0%
ASA* class					.38
I or II	33	14.0%	23	10.0%
III	166	70.3%	166	72.2%
IV	37	15.7%	41	17.8%
Location discharged to					.07
Home or assisted living	24	10.5%	13	5.9%
Nursing home	196	86.0%	192	87.3%
Another hospital or hospice	8	3.5%	15	6.8%
Time to surgery (hours)	38		25		.001
Time from surgery to discharge (days)	9		7		.04
Length of stay	10.6		8.4		< .00
Readmission rate	25	10.6%	20	8.7%	.49

Table 2.Certified Underlying Cause of Death as Recorded on Death Certificates after 1 Year of Following Patients with Hip Fractures
	Standard care	Hospitalist care	Total No. of deaths	%
Cancer	7	10	17	12.8%
Cardiovascular	14	20	34	25.6%
Infectious	5	4	9	6.8%
Neurological	5	10	15	11.3%
Other	0	2	2	1.5%
Renal	4	2	6	4.5%
Respiratory	20	9	29	21.8%
Unknown	11	10	21	15.8%
Total	66	67	133	100.0%

Table 3.Univariate Predictors of Mortality 1 year after Surgical Repair of Hip Fracture
Variable	Hazard ratio (95% CI)	P value
* American Society of Anesthesia; confidence interval.
Age on admission per 10 years	1.41 (1.20, 1.65)	< .001
ASA* II	1.0 (referent)
ASA* III	5.27 (2.79, 9.96)	< .001
ASA* IV	11.7 (5.97, 22.9)	< .001
History of chronic obstructive pulmonary disease	1.82 (1.35, 2.43)	< .001
History of renal insufficiency	2.40 (1.62,3.55)	< .001
History of stroke/transient ischemic attack	1.46 (1.10, 1.95)	.01
History of diabetes	1.70 (1.29,2.25)	< .001
History of congestive heart failure	2.26 (1.73, 2.96)	< .001
History of coronary artery disease	1.53 (1.20, 1.97)	< .001
History of dementia	2.02 (1.57, 2.59)	< .001
Admission from home	1.0 (referent)
Admission from assisted living	1.47 (1.06, 2.04)	.02
Admission from nursing home	3.04 (2.33, 3.98)	< .001
Independent	1.0 (referent)
Use of assistive device	1.81 (1.39, 2.36)	< .001
Personal help	3.49 (2.16, 5.64)	< .001
Nonambulatory	3.96 (2.47, 6.35)	< .001
Crackles on admission	2.03 (1.50, 2.74)	< .001
Hypoxia on admission	1.56 (1.04, 2.32)	.03
Hypotension on admission	6.21 (2.72, 14.2)	< .001
Tachycardia on admission	1.66 (1.15, 2.41)	.007
Coumadin on admission	1.57 (1.13, 2.18)	.007
Confusion/unconsciousness on admission	2.23 (1.74, 2.87)	< .001
Fever on admission	1.98 (1.16, 3.40)	.01
Tachypnea on admission	1.95 (1.39, 2.72)	< .001
Inpatient myocardial Infarction	3.59 (2.35, 5.48)	< .001
Inpatient atrial fibrillation	2.00 (1.37, 2.92)	< .001
Inpatient congestive heart failure	2.62 (1.79, 3.84)	< .0001
Inpatient delirium	1.46 (1.13, 1.90)	< .005
Inpatient lung infection	2.52 (1.85, 3.42)	< .001
Inpatient respiratory failure	2.76 (1.64, 4.66)	< .001
Inpatient mechanical ventilation	2.56 (1.43, 4.57)	.002
Inpatient renal failure	3.60 (1.97, 6.61)	< .001
Days from admission to surgery	1.06 (1.005, 1.12)	.03
Intensive care unit stay	1.93 (1.51, 2.47)	< .001

Table 4.Multivariable Predictors of Survival Following Surgical Repair of Hip Fracture
Variable	Hazard ratio (95% CI)	P value
* American Society of Anesthesia; Confidence interval.
Age on admission per 10 years	1.17 (0.99, 1.38)	.07
ASA* class III or IV	4.20 (2.21, 7.99)	< .001
ASA* class II	1.0 (referent)
Admission from nursing home	2.24 (1.73, 2.90)	< .001
Admission from home or assisted living	1.0 (referent)
Inpatient myocardial infarction, inpatient acute renal failure, or intensive care unit stay	1.85 (1.45, 2.35)	< .001
No inpatient myocardial infarction, no inpatient acute renal failure, and no intensive care unit stay	1.0 (referent)

DISCUSSION

Acknowledgements

We thank Donna K. Lawson for her assistance in data collection and management.

References

Cummings SR,Rubin SM,Black D.The future of hip fractures in the United States. Numbers, costs, and potential effects of postmenopausal estrogen.Clin Orthop Relat Res1990 (252):163–166.
Cooper C,Campion G,Melton LJ.Hip fractures in the elderly: a world‐wide projection.Osteoporos Int.1992;2:285–289.
Haentjens P,Autier P,Barette M,Boonen S.The economic cost of hip fractures among elderly women. A one‐year, prospective, observational cohort study with matched‐pair analysis.Belgian Hip Fracture Study Group.J Bone Joint Surg Am.2001;83‐A:493–500.
Braithwaite RS,Col NF,Wong JB.Estimating hip fracture morbidity, mortality and costs.J Am Geriatr Soc.2003;51:364–370.
Schneider EL,Guralnik JM.The aging of America. Impact on health care costs.JAMA.1990;263:2335–2340.
Ray NF,Chan JK,Thamer M,Melton LJ.Medical expenditures for the treatment of osteoporotic fractures in the United States in 1995: report from the National Osteoporosis Foundation.J Bone Miner Res.1997;12(1):24–35.
US Department of Health and Human Services.Surveillance for selected public health indicators affecting older adults —United States.MMWR Morb Mortal Wkly Rep1999;48:33–34.
Cummings SR,Melton LJ.Epidemiology and outcomes of osteoporotic fractures.Lancet.2002;359:1761–1767.
Phy MP,Vanness DJ,Melton LJ, et al.Effects of a hospitalist model on elderly patients with hip fracture.Arch Intern Med.2005;165:796–801.
Heikkinen T,Parker M,Jalovaara P.Hip fractures in Finland and Great Britain—a comparison of patient characteristics and outcomes.Int Orthop.2001;25:349–354.
WHO.International Classification of Disease, Ninth Revision (ICD‐9).Geneva, Switzerland:World Health Organization;1977.
Huddleston JM,Long KH,Naessens JM, et al.Medical and surgical comanagement after elective hip and knee arthroplasty: a randomized, controlled trial.Ann Intern Med.2004;141(1):28–38.
Cox D.Regression models and life‐tables (with discussion).J R Stat Soc Ser B.1972;34:187–220.
Kaplan E,Meier P.Nonparametric estimation from incomplete observations.J Am Statistical Assoc.1958;53:457–481.
Therneau TM,Atkinson E.An Introduction to Recursive Partitioning using the RPART Routines: Section of Biostatistics, Mayo Clinic;1997.
Urban H.Computer Intensive Statistical Methods, Validation, Model Selection, and Bootstrap.London:Chapman and Hall;1994.
Sauerbrei W,Schumacher M.A bootstrap resampling procedure for model building: application to the Cox regression model.Stat Med.1992;11:2093–2109.
Roy A,Heckman MG,Roy V.Associations between the hospitalist model of care and quality‐of‐care‐related outcomes in patients undergoing hip fracture surgery.Mayo Clin Proc.2006;81(1):28–31.
Orosz GM,Magaziner J,Hannan EL, et al.Association of timing of surgery for hip fracture and patient outcomes.JAMA.2004;291:1738–1743.
Grimes JP,Gregory PM,Noveck H,Butler MS,Carson JL.The effects of time‐to‐surgery on mortality and morbidity in patients following hip fracture.Am J Med.2002;112:702–709.
Gdalevich M,Cohen D,Yosef D,Tauber C.Morbidity and mortality after hip fracture: the impact of operative delay.Arch Orthop Trauma Surg.2004;124:334–340.
Siegmeth AW,Gurusamy K,Parker MJ.Delay to surgery prolongs hospital stay in patients with fractures of the proximal femur.J Bone Joint Surg Br.2005;87:1123–1126.
Parker MJ,Pryor GA.The timing of surgery for proximal femoral fractures.J Bone Joint Surg Br.1992;74(2):203–205.
Boockvar KS,Halm EA,Litke A, et al.Hospital readmissions after hospital discharge for hip fracture: surgical and nonsurgical causes and effect on outcomes.J Am Geriatr Soc.2003;51:399–403.
Jensen JS,Tondevold E.Mortality after hip fractures.Acta Orthop Scand1979;50(2):161–167.
Lawrence VA,Hilsenbeck SG,Noveck H,Poses RM,Carson JL.Medical complications and outcomes after hip fracture repair.Arch Intern Med.2002;162:2053–2057.
Jiang HX,Majumdar SR,Dick DA, et al.Development and initial validation of a risk score for predicting in‐hospital and 1‐year mortality in patients with hip fractures.J Bone Miner Res.2005;20:494–500.
Shah MR,Aharonoff GB,Wolinsky P,Zuckerman JD,Koval KJ.Outcome after hip fracture in individuals ninety years of age and older.J Orthop Trauma.2001;15(1):34–39.
Aharonoff GB,Koval KJ,Skovron ML,Zuckerman JD.Hip fractures in the elderly: predictors of one year mortality.J Orthop Trauma.1997;11(3):162–165.
Weller I,Wai EK,Jaglal S,Kreder HJ.The effect of hospital type and surgical delay on mortality after surgery for hip fracture.J Bone Joint Surg Br.2005;87:361–366.
Melton LJ.History of the Rochester Epidemiology Project.Mayo Clin Proc.1996;71:266–274.
Pitto RP.The mortality and social prognosis of hip fractures. A prospective multifactorial study.Int Orthop.1994;18(2):109–113.
Rosell PA,Parker MJ.Functional outcome after hip fracture. A 1‐year prospective outcome study of 275 patients.Injury.2003;34:529–532.
White BL,Fisher WD,Laurin CA.Rate of mortality for elderly patients after fracture of the hip in the 1980's.J Bone Joint Surg Am.1987;69:1335–1340.
Broos PL,Van Haaften KI,Stappaerts KH,Gruwez JA.Hip fractures in the elderly. Mortality, functional results and social readaptation.Int Surg.1989;74(3):191–194.
Swain DG,Nightingale PG,Patel JV.Blood transfusion requirements in femoral neck fracture.Injury.2000;31(1):7–10.
Boereboom FT,Raymakers JA,Duursma SA.Mortality and causes of death after hip fractures in The Netherlands.Neth J Med.1992;41(1–2):4–10.
Stoddart J,Horne G,Devane P.Influence of preoperative medical status and delay to surgery on death following a hip fracture.ANZ J Surg.2002;72:405–407.
Marottoli RA,Berkman LF,Leo‐Summers L,Cooney LMPredictors of mortality and institutionalization after hip fracture: the New Haven EPESE cohort. Established Populations for Epidemiologic Studies of the Elderly.Am J Public Health.1994;84:1807–1812.
Richmond J,Aharonoff GB,Zuckerman JD,Koval KJ.Mortality risk after hip fracture.J Orthop Trauma.2003;17(1):53–56.
Parvizi J,Ereth MH,Lewallen DG.Thirty‐day mortality following hip arthroplasty for acute fracture.J Bone Joint Surg Am.2004;86‐A:1983–1988.
Cornwall R,Gilbert MS,Koval KJ,Strauss E,Siu AL.Functional outcomes and mortality vary among different types of hip fractures: a function of patient characteristics.Clin Orthop Relat Res.2004:64–71.
Auerbach AD,Wachter RM,Katz P,Showstack J,Baron RB,Goldman L.Implementation of a voluntary hospitalist service at a community teaching hospital: improved clinical efficiency and patient outcomes.Ann Intern Med.2002;137:859–865.
Meltzer D,Manning WG,Morrison J, et al.Effects of physician experience on costs and outcomes on an academic general medicine service: results of a trial of hospitalists.Ann Intern Med.2002;137:866–874.

References

Cummings SR,Rubin SM,Black D.The future of hip fractures in the United States. Numbers, costs, and potential effects of postmenopausal estrogen.Clin Orthop Relat Res1990 (252):163–166.
Cooper C,Campion G,Melton LJ.Hip fractures in the elderly: a world‐wide projection.Osteoporos Int.1992;2:285–289.
Haentjens P,Autier P,Barette M,Boonen S.The economic cost of hip fractures among elderly women. A one‐year, prospective, observational cohort study with matched‐pair analysis.Belgian Hip Fracture Study Group.J Bone Joint Surg Am.2001;83‐A:493–500.
Braithwaite RS,Col NF,Wong JB.Estimating hip fracture morbidity, mortality and costs.J Am Geriatr Soc.2003;51:364–370.
Schneider EL,Guralnik JM.The aging of America. Impact on health care costs.JAMA.1990;263:2335–2340.
Ray NF,Chan JK,Thamer M,Melton LJ.Medical expenditures for the treatment of osteoporotic fractures in the United States in 1995: report from the National Osteoporosis Foundation.J Bone Miner Res.1997;12(1):24–35.
US Department of Health and Human Services.Surveillance for selected public health indicators affecting older adults —United States.MMWR Morb Mortal Wkly Rep1999;48:33–34.
Cummings SR,Melton LJ.Epidemiology and outcomes of osteoporotic fractures.Lancet.2002;359:1761–1767.
Phy MP,Vanness DJ,Melton LJ, et al.Effects of a hospitalist model on elderly patients with hip fracture.Arch Intern Med.2005;165:796–801.
Heikkinen T,Parker M,Jalovaara P.Hip fractures in Finland and Great Britain—a comparison of patient characteristics and outcomes.Int Orthop.2001;25:349–354.
WHO.International Classification of Disease, Ninth Revision (ICD‐9).Geneva, Switzerland:World Health Organization;1977.
Huddleston JM,Long KH,Naessens JM, et al.Medical and surgical comanagement after elective hip and knee arthroplasty: a randomized, controlled trial.Ann Intern Med.2004;141(1):28–38.
Cox D.Regression models and life‐tables (with discussion).J R Stat Soc Ser B.1972;34:187–220.
Kaplan E,Meier P.Nonparametric estimation from incomplete observations.J Am Statistical Assoc.1958;53:457–481.
Therneau TM,Atkinson E.An Introduction to Recursive Partitioning using the RPART Routines: Section of Biostatistics, Mayo Clinic;1997.
Urban H.Computer Intensive Statistical Methods, Validation, Model Selection, and Bootstrap.London:Chapman and Hall;1994.
Sauerbrei W,Schumacher M.A bootstrap resampling procedure for model building: application to the Cox regression model.Stat Med.1992;11:2093–2109.
Roy A,Heckman MG,Roy V.Associations between the hospitalist model of care and quality‐of‐care‐related outcomes in patients undergoing hip fracture surgery.Mayo Clin Proc.2006;81(1):28–31.
Orosz GM,Magaziner J,Hannan EL, et al.Association of timing of surgery for hip fracture and patient outcomes.JAMA.2004;291:1738–1743.
Grimes JP,Gregory PM,Noveck H,Butler MS,Carson JL.The effects of time‐to‐surgery on mortality and morbidity in patients following hip fracture.Am J Med.2002;112:702–709.
Gdalevich M,Cohen D,Yosef D,Tauber C.Morbidity and mortality after hip fracture: the impact of operative delay.Arch Orthop Trauma Surg.2004;124:334–340.
Siegmeth AW,Gurusamy K,Parker MJ.Delay to surgery prolongs hospital stay in patients with fractures of the proximal femur.J Bone Joint Surg Br.2005;87:1123–1126.
Parker MJ,Pryor GA.The timing of surgery for proximal femoral fractures.J Bone Joint Surg Br.1992;74(2):203–205.
Boockvar KS,Halm EA,Litke A, et al.Hospital readmissions after hospital discharge for hip fracture: surgical and nonsurgical causes and effect on outcomes.J Am Geriatr Soc.2003;51:399–403.
Jensen JS,Tondevold E.Mortality after hip fractures.Acta Orthop Scand1979;50(2):161–167.
Lawrence VA,Hilsenbeck SG,Noveck H,Poses RM,Carson JL.Medical complications and outcomes after hip fracture repair.Arch Intern Med.2002;162:2053–2057.
Jiang HX,Majumdar SR,Dick DA, et al.Development and initial validation of a risk score for predicting in‐hospital and 1‐year mortality in patients with hip fractures.J Bone Miner Res.2005;20:494–500.
Shah MR,Aharonoff GB,Wolinsky P,Zuckerman JD,Koval KJ.Outcome after hip fracture in individuals ninety years of age and older.J Orthop Trauma.2001;15(1):34–39.
Aharonoff GB,Koval KJ,Skovron ML,Zuckerman JD.Hip fractures in the elderly: predictors of one year mortality.J Orthop Trauma.1997;11(3):162–165.
Weller I,Wai EK,Jaglal S,Kreder HJ.The effect of hospital type and surgical delay on mortality after surgery for hip fracture.J Bone Joint Surg Br.2005;87:361–366.
Melton LJ.History of the Rochester Epidemiology Project.Mayo Clin Proc.1996;71:266–274.
Pitto RP.The mortality and social prognosis of hip fractures. A prospective multifactorial study.Int Orthop.1994;18(2):109–113.
Rosell PA,Parker MJ.Functional outcome after hip fracture. A 1‐year prospective outcome study of 275 patients.Injury.2003;34:529–532.
White BL,Fisher WD,Laurin CA.Rate of mortality for elderly patients after fracture of the hip in the 1980's.J Bone Joint Surg Am.1987;69:1335–1340.
Broos PL,Van Haaften KI,Stappaerts KH,Gruwez JA.Hip fractures in the elderly. Mortality, functional results and social readaptation.Int Surg.1989;74(3):191–194.
Swain DG,Nightingale PG,Patel JV.Blood transfusion requirements in femoral neck fracture.Injury.2000;31(1):7–10.
Boereboom FT,Raymakers JA,Duursma SA.Mortality and causes of death after hip fractures in The Netherlands.Neth J Med.1992;41(1–2):4–10.
Stoddart J,Horne G,Devane P.Influence of preoperative medical status and delay to surgery on death following a hip fracture.ANZ J Surg.2002;72:405–407.
Marottoli RA,Berkman LF,Leo‐Summers L,Cooney LMPredictors of mortality and institutionalization after hip fracture: the New Haven EPESE cohort. Established Populations for Epidemiologic Studies of the Elderly.Am J Public Health.1994;84:1807–1812.
Richmond J,Aharonoff GB,Zuckerman JD,Koval KJ.Mortality risk after hip fracture.J Orthop Trauma.2003;17(1):53–56.
Parvizi J,Ereth MH,Lewallen DG.Thirty‐day mortality following hip arthroplasty for acute fracture.J Bone Joint Surg Am.2004;86‐A:1983–1988.
Cornwall R,Gilbert MS,Koval KJ,Strauss E,Siu AL.Functional outcomes and mortality vary among different types of hip fractures: a function of patient characteristics.Clin Orthop Relat Res.2004:64–71.
Auerbach AD,Wachter RM,Katz P,Showstack J,Baron RB,Goldman L.Implementation of a voluntary hospitalist service at a community teaching hospital: improved clinical efficiency and patient outcomes.Ann Intern Med.2002;137:859–865.
Meltzer D,Manning WG,Morrison J, et al.Effects of physician experience on costs and outcomes on an academic general medicine service: results of a trial of hospitalists.Ann Intern Med.2002;137:866–874.

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Journal of Hospital Medicine - 2(4)

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Journal of Hospital Medicine - 2(4)

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219-225

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219-225

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Effects of a hospitalist care model on mortality of elderly patients with hip fractures

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Effects of a hospitalist care model on mortality of elderly patients with hip fractures

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hospitalist as consultant, geriatric patient, osteoporosis, post‐operative evaluation

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hospitalist as consultant, geriatric patient, osteoporosis, post‐operative evaluation

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Mayo Clinic College of Medicine, Hospital Internal Medicine, Department of Medicine, Rochester, MN 55905; Fax: (507) 255‐1027

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