Evidence-Based Reviews

Managing polypharmacy: Walking the fine line between help and harm

Current Psychiatry. 2003 February;2(2):24-36

References

1. Lazarou J, Pomeranz BH, Corey PN. Incidence of adverse drug reactions in hospitalized patients: a meta-analysis of prospective studies. JAMA 1998;279(15):1200-5.

2. Incalzi RA, Gemma A, Capparella O, et al. Predicting mortality and length of stay of geriatric patients in an acute care general hospital. J Gerontol 1992;47(2):M35-9.

3. Berube MS, Neely DJ, DeVinne PB. American Heritage Dictionary. (2nd College ed). Boston: Houghton Mifflin Co, 1982.

4. Friend DG. Polypharmacy: multiple-ingredient and shotgun prescriptions. N Engl J Med 1959;260(20):1015-8.

5. Sheppard C, Collins L, Fiorentino D, Fracchia J, Merlis S. Polypharmacy in psychiatric treatment. I. Incidence at a state hospital. Curr Ther Res Clin Exp 1969;(12):765-74.

6. Bjerrum L, Rosholm JU, Hallas J, Kragstrup J. Methods for estimating the occurrence of polypharmacy by means of a prescription database. Eur J Clin Pharmacol 1997;53(1):7-11.

7. Werder SF. Polypharmacy: definitions and risk factors (grand rounds). University of Kansas School of Medicine-Wichita, Department of Psychiatry and Behavioral Sciences. Via Christi Regional Medical Center, St. Joseph Campus: Dec 12, 2000.

8. Bjerrum L, Sogaard J, Hallas J, Kragstrup J. Polypharmacy: correlations with sex, age and drug regimen. A prescription database study. Eur J Clin Pharmacol 1998;54(3):197-202.

9. Bjerrum L. Pharmacoepidemiological Studies of Polypharmacy: Methodological issues, population estimates, and influence of practice patterns (PhD thesis). Odense University Faculty of Health Sciences, Department of clinical pharmacology and research unit of general practice. Denmark; 1998. Available at http://www.sdu.dk/health/IPH/genpract/staff/lbjerrum/PHD/PHD.HTM. Accessed Jan. 9, 2003.

10. Wilder BJ. Pharmacokinetics of valproate and carbamazepine. J Clin Psychopharmacol 1992;12(1 suppl):64S-68S.

11. Preskorn SH. The rational basis for the development and use of newer antidepressants. In: Outpatient management of depression: a guide for the practitioner (2nd ed). Caddo, OK: Professional Publications, Inc; 1999;57-103.

12. Vaughan DA. Interaction of fluoxetine with tricyclic antidepressants. Am J Psychiatry 1988;145(11):1478.-

13. Meeker JE, Reynolds PC. Postmortem tissue methamphetamine concentrations following selegiline administration. J Anal Toxicol 1990;14(5):330-1.

14. Sallee FR, DeVane CL, Ferrell RE. Fluoxetine-related death in a child with cytochrome P-450 2D6 genetic deficiency. J Child Adolesc Psychopharmacol 2000;10(1):27-34.

15. Ellis RJ, Mayo MS, Bodensteiner DM. Ciprofloxacin-warfarin coagulopathy: a case series. Am J Hematol 2000;63(1):28-31.

16. Konig SA, Siemes H, Blaker F, et al. Severe hepatotoxicity during valproate therapy: an update and report of eight new fatalities. Epilepsia 1994;35(5):1005-15.

17. Fattinger K, Roos M, Vergeres P, et al. Epidemiology of drug exposure and adverse drug reactions in two Swiss departments of internal medicine. Br J Clin Pharmacol 2000;49(2):158-67.

18. Ebbesen J, Buajordet I, Erikssen J, Svaar H, Brors O, Hilberg T. Drugs as a cause of death. A prospective quality assurance project in a department of medicine (Norwegian). Tidsskr Nor Laegeforen 1995;115(19):2369-72.

19. Alarcon T, Barcena A, Gonzalez-Montalvo JI, Penalosa C, Salgado A. Factors predictive of outcome on admission to an acute geriatric ward. Age Ageing 1999;28(5):429-32.

20. Smith NK, Albazzaz MK. A prospective study of urinary retention and risk of death after proximal femoral fracture. Age Ageing 1996;25(2):150-4.

21. Pulska T, Pahkala K, Laippala P, Kivela SL. Six-year survival of depressed elderly Finns: a community study. Int J Geriatr Psychiatry 1997;12(9):942-50.

22. Waddington JL, Youssef HA, Kinsella A. Mortality in schizophrenia. Antipsychotic polypharmacy and absence of adjunctive anticholinergics over the course of a 10-year prospective study. Br J Psychiatry 1998;173:325-9.

23. Burns R, Nichols LO, Graney MJ, Cloar FT. Impact of continued geriatric outpatient management on health outcomes of older veterans. Arch Intern Med 1995;155(12):1313-8.

24. Kaufman DW, Kelly JP, Rosenberg L, Anderson TE, Mitchell AA. Recent patterns of medication use in the ambulatory adult population of the United States: the Slone survey. JAMA 2002;16;287(3):337-44.

25. Flaherty JH, Perry HM, 3rd, Lynchard GS, Morley JE. Polypharmacy and hospitalization among older home care patients. J Gerontol A Biol Sci Med Sci 2000;55(10):M554-9.

26. Ray WA, Griffin MR, Schaffner W, Baugh DK, Melton LJ, 3rd. Psychotropic drug use and the risk of hip fracture. N Engl J Med 1987;316(7):363-9.

27. Col N, Fanale JE, Kronholm P. The role of medication noncompliance and adverse drug reactions in hospitalizations of the elderly. Arch Intern Med 1990;150(4):841-5.

28. Bero LA, Lipton HL, Bird JA. Characterization of geriatric drug-related hospital readmissions. Med Care 1991;29(10):989-1003.

29. Ray WA, Fought RL, Decker MD. Psychoactive drugs and the risk of injurious motor vehicle crashes in elderly drivers. Am J Epidemiol 1992;136(7):873-83.

30. Prescription drugs and the elderly. Publication AO/HEHS-95-152. Washington, DC: U.S. General Accounting Office, July 1995.

31. Johnson JA, Bootman JL. Drug-related morbidity and mortality. A cost-of-illness model. Arch Intern Med 1995;155(18):1949-56.

32. Fink A, Siu AL, Brook RH, Park RE, Solomon DH. Assuring the quality of health care for older persons. An expert panel’s priorities. JAMA 1987;258(14):1905-8.

33. Lee DR. Polypharmacy: a case report and new protocol for management. J Am Board Fam Pract 1998;11(2):140-4.

34. Hamdy RC, Moore SW, Whalen K, et al. Reducing polypharmacy in extended care. South Med J 1995;88(5):534-8.

35. Haumschild MJ, Ward ES, Bishop JM, Haumschild MS. Pharmacy-based computer system for monitoring and reporting drug interactions. Am J Hosp Pharm 1987;44(2):345-8.

effect = potency at the site of action × concentration at site of action × inter-individual variance

In other words, the clinical response equals the drug’s potency at the site of action times the drug’s concentration at the site of action times the patient’s underlying biology. Likewise, when we consider variability among patients, the second equation becomes:

effect = pharmacodynamics × pharmacokinetics × inter-individual variance

Table 3

HOW PHARMACOKINETICS MAY CAUSE ADVERSE DRUG-DRUG EVENTS

Mechanism of interaction of two or more drugs	Two or more drugs interact where …	Examples
One negatively affects the other’s absorption		Use of tetracycline with substances containing calcium
One negatively affects the other’s distribution		Amiodarone and quinidine, by inhibiting P-glycoprotein, reduce the volume of distribution and/or clearance of digoxin, doubling its serum level
One negatively affects the other’s metabolism	One negatively affects the other’s oxidative metabolism by inducing CYP enzyme activity	Carbamazepine induces CYP 2C9 and CYP 3A4 activity, which stimulates warfarin biotransformation, decreases its half-life, and lowers its serum concentration
	One negatively affects the other’s oxidative metabolism by inhibiting CYP enzyme activity	Ketoconazole inhibits CYP 3A4 activity, which inhibits terfenadine metabolism, resulting in serum terfenadine levels 32 to 100 times normal
	One inhibits hydroxylation of the other’s toxic metabolites, inhibiting their clearance	Combination of carbamazepine and valproate
One negatively affects the other’s elimination		Lithium plus hydrochlorothiazide or an NSAID (both impair lithium excretion)

This addition to the equation explains how inter-individual variability can shift the dose-response curve to produce a greater or lesser effect than that which would be expected in the “usual” patient taking the prescribed dosage.

Inter-individual variance. The metabolism of dextromethorphan illustrates the effect of inter-individual variance. After a single dose, about 93% of Caucasians develop relatively lower dextromethorphan:dextrophan ratios, and about 7% develop relatively higher ratios. This difference defines patients who are pharmacogenetically CYP 2D6 extensive metabolizers versus those who are not.

Similarly, drugs sometimes cause biological variance, which predisposes to a drug-drug interaction. For example, the literature is replete with case reports and case series reporting that a substantial CYP 2D6 inhibitor—such as fluoxetine—blocks the metabolism of drugs that are principally metabolized by CYP 2D6. If the drug being metabolized has a narrow therapeutic index—such as amitriptyline—the resultant increase in its serum level can cause serious cardio and neurotoxicity, including arrhythmias, delirium, seizures, coma, and death.¹²

In such cases, a CYP 2D6 inhibitor converts the phenotype from a CYP 2D6 extensive metabolizer into a CYP 2D6 poor metabolizer. Hence, the clinician must consider how a specific patient may differ from the usual patient when selecting and dosing a drug. The difference may be genetic or acquired, as in this example.

Table 4

RISK FACTORS FOR POLYPHARMACY

Psychiatric disorders	Medications being taken
Schizophrenia	Cardiovascular agents
Bipolar disorder	Antipsychotics
Depression	Mood stabilizers
Borderline and other personality disorders	Antidepressants
Substance abuse (including tobacco habituation)	Self-medication with aspirin
Neurologic disorders	Demographic variables
Mental retardation	Age 65 or older
Dementia	Ethnicity (Caucasian, African-American)
Chronic pain, facial pain	Female gender
Headache (including migraine)	Psychosocial variables
Insomnia	Lower socioeconomic status
Epilepsy	Inner-city residence
Medical disorders	Lower level of education
Chronic diseases, multiple diseases	Unemployment
Obesity	Self-medication
Diabetes	Concealed drug use
Chronic hypertension
Coronary artery disease

The following equation explains how dose is related to drug concentration, which takes into account the drug’s pharmacokinetics:

drug concentration = dosing rate (mg/day) ÷ clearance (ml/min)

In other words, the concentration achieved in a specific patient is determined by the dosage relative to the patient’s ability to clear the drug from the body.

Consequences, prevalence of polypharmacy

Polypharmacy increases patients’ risk for many ill effects, including incidence and severity of adverse events, drug-drug interactions, medication errors, hospitalizations, morbidity, mortality, and direct and indirect costs. At least 12 reports and studies have been published showing the association between polypharmacy and death,^2,13-23 and in some of these reports the association is present even after controlling for underlying diseases.

The prevalence of polypharmacy varies by country and population. In Denmark, for example, the prevalence of polypharmacy is approximately 1.2%,⁶ compared with approximately 7% in the United States.²⁴ Nearly one-half (46%) of all elderly persons admitted to U.S. hospitals may be taking seven or more medications.²⁵ Polypharmacy is especially problematic in patients age 65 and older (Box 2),^26-31 in whom the top five preventable threats to health are congestive heart failure, breast cancer, hypertension, pneumonia, and adverse drug events.³² Although older persons make up less than 15% of the population, they take the greatest number and quantity of medications, purchase 40% of all nonprescription medications, and use 33% of all retail prescriptions.³⁰

Box 2

POLYPHARMACY RISKS IN PATIENTS AGE 65 AND OLDER

14% of older patients prescribed psychotropics experience a hip fracture, accounting for 32,000 annual hip fractures in the United States.²⁶
28% of older patients’ hospitalizations are due to adverse events or non-adherence to drug therapy.²⁷
35% of older patients taking three or more prescription medications at hospital discharge are re-hospitalized within 6 months. Problems with medications lead to 6.4% of these re-admissions.²⁸
Among older drivers, taking a psychoactive drug multiplies the risk of a motor vehicle accident involving injuries by 1.5 to 5.5 times. The greater the dosage, the greater the risk.²⁹
Hospital admissions related to adverse events from medications in older patients cost $20 billion annually (excluding indirect costs).³⁰
Morbidity and mortality related to drug therapy in ambulatory patients in the United States costs $76.6 billion annually.³¹