Mary N. Hall, MD

Evidence summary

ADHD affects 7% to 8% of school-age children, and the prevalence is increasing.¹ The quality of studies investigating the link between diet and ADHD is limited by small sample sizes, subjective outcome measures, and nonstandardized intervention protocols.

Elimination diets show little or no effect
Studies of elimination diets for ADHD have investigated the effects of withholding sugar and artificial food colorings (AFCs).

Sugar. A 1995 meta-analysis of 16 double-blind, randomized, placebo-controlled trials evaluated the effect of dietary sugar in the form of sucrose, glucose, and fructose on behavior or cognition of children. Outcomes included subjective measurements from teachers, parents, and researchers, as well as objective scoring of activities.

No significant differences in the summary effect size were noted for any measured variable. A weakness of the analysis was that not all of the trials studied children who had been specifically diagnosed with ADHD.²

AFCs. A 2004 meta-analysis of 15 double-blind, placebo-controlled trials (total 219 children) evaluated the effect of AFCs on hyperactivity. Outcomes were measured by behavioral rating scales that ranged from standardized forms such as the Conners Parent-Teacher Questionnaire (12 trials) to nonvalidated author-developed scales (3 trials). Analysis revealed a small summary effect size (0.283; 95% confidence interval, 0.079-0.488), and the authors concluded that AFCs do have a small effect on hyperactivity.³

A secondary analysis of children who previously showed worsening of hyperactivity with AFCs (either by parental report or in an earlier study) found a larger effect size (0.53). This finding implies that a subset of children whose parents notice an increase in hyperactivity with AFCs may benefit from exclusion. However, because the quality of the meta-analysis is limited by the heterogeneity of the studies, publication bias, unvalidated outcome measures, and variety of diagnoses in the participants, no recommendation can be made for AFC exclusion diets.³

Supplementation with fatty acids doesn’t improve symptoms
Because polyunsaturated fatty acids (PUFAs) are essential for brain development and function, a deficiency theoretically may contribute to a range of developmental disorders, including ADHD. An RCT of 63 children 6 to 12 years of age with ADHD randomly assigned the children to supplementation with the most abundant PUFA, docosahexanoic (DHA), or placebo for 4 months. Measured outcomes included objective attention evaluation by computer and written tests and standardized objective measures such as the Conners Rating Scales.⁴ The study found no significant improvement in any ADHD symptom.⁴

The findings of this trial were confirmed by another double-blinded RCT of 40 children with ADHD who were randomized to DHA or placebo. The second trial found no significant differences in ADHD symptoms after 2 months.⁵

Recommendations

The American Academy of Pediatrics states that there is a need for well-designed, rigorous studies of currently promoted but less well-established therapies for ADHD, such as occupational therapy, biofeedback, herbs, vitamins, and food supplements. These interventions aren’t supported by evidence-based studies at present.⁶

The American Academy of Child and Adolescent Psychiatry’s guidelines on managing ADHD don’t mention dietary interventions.⁷

Investigators from the Cincinnati Children’s Hospital report that elimination diets and food supplements have little or no quality evidence to support their effectiveness.⁸

Evidence summary

ADHD affects 7% to 8% of school-age children, and the prevalence is increasing.¹ The quality of studies investigating the link between diet and ADHD is limited by small sample sizes, subjective outcome measures, and nonstandardized intervention protocols.

Elimination diets show little or no effect
Studies of elimination diets for ADHD have investigated the effects of withholding sugar and artificial food colorings (AFCs).

Sugar. A 1995 meta-analysis of 16 double-blind, randomized, placebo-controlled trials evaluated the effect of dietary sugar in the form of sucrose, glucose, and fructose on behavior or cognition of children. Outcomes included subjective measurements from teachers, parents, and researchers, as well as objective scoring of activities.

No significant differences in the summary effect size were noted for any measured variable. A weakness of the analysis was that not all of the trials studied children who had been specifically diagnosed with ADHD.²

AFCs. A 2004 meta-analysis of 15 double-blind, placebo-controlled trials (total 219 children) evaluated the effect of AFCs on hyperactivity. Outcomes were measured by behavioral rating scales that ranged from standardized forms such as the Conners Parent-Teacher Questionnaire (12 trials) to nonvalidated author-developed scales (3 trials). Analysis revealed a small summary effect size (0.283; 95% confidence interval, 0.079-0.488), and the authors concluded that AFCs do have a small effect on hyperactivity.³

A secondary analysis of children who previously showed worsening of hyperactivity with AFCs (either by parental report or in an earlier study) found a larger effect size (0.53). This finding implies that a subset of children whose parents notice an increase in hyperactivity with AFCs may benefit from exclusion. However, because the quality of the meta-analysis is limited by the heterogeneity of the studies, publication bias, unvalidated outcome measures, and variety of diagnoses in the participants, no recommendation can be made for AFC exclusion diets.³

Supplementation with fatty acids doesn’t improve symptoms
Because polyunsaturated fatty acids (PUFAs) are essential for brain development and function, a deficiency theoretically may contribute to a range of developmental disorders, including ADHD. An RCT of 63 children 6 to 12 years of age with ADHD randomly assigned the children to supplementation with the most abundant PUFA, docosahexanoic (DHA), or placebo for 4 months. Measured outcomes included objective attention evaluation by computer and written tests and standardized objective measures such as the Conners Rating Scales.⁴ The study found no significant improvement in any ADHD symptom.⁴

The findings of this trial were confirmed by another double-blinded RCT of 40 children with ADHD who were randomized to DHA or placebo. The second trial found no significant differences in ADHD symptoms after 2 months.⁵

Recommendations

The American Academy of Pediatrics states that there is a need for well-designed, rigorous studies of currently promoted but less well-established therapies for ADHD, such as occupational therapy, biofeedback, herbs, vitamins, and food supplements. These interventions aren’t supported by evidence-based studies at present.⁶

The American Academy of Child and Adolescent Psychiatry’s guidelines on managing ADHD don’t mention dietary interventions.⁷

Investigators from the Cincinnati Children’s Hospital report that elimination diets and food supplements have little or no quality evidence to support their effectiveness.⁸

Evidence summary

ADHD affects 7% to 8% of school-age children, and the prevalence is increasing.¹ The quality of studies investigating the link between diet and ADHD is limited by small sample sizes, subjective outcome measures, and nonstandardized intervention protocols.

Elimination diets show little or no effect
Studies of elimination diets for ADHD have investigated the effects of withholding sugar and artificial food colorings (AFCs).

Sugar. A 1995 meta-analysis of 16 double-blind, randomized, placebo-controlled trials evaluated the effect of dietary sugar in the form of sucrose, glucose, and fructose on behavior or cognition of children. Outcomes included subjective measurements from teachers, parents, and researchers, as well as objective scoring of activities.

No significant differences in the summary effect size were noted for any measured variable. A weakness of the analysis was that not all of the trials studied children who had been specifically diagnosed with ADHD.²

AFCs. A 2004 meta-analysis of 15 double-blind, placebo-controlled trials (total 219 children) evaluated the effect of AFCs on hyperactivity. Outcomes were measured by behavioral rating scales that ranged from standardized forms such as the Conners Parent-Teacher Questionnaire (12 trials) to nonvalidated author-developed scales (3 trials). Analysis revealed a small summary effect size (0.283; 95% confidence interval, 0.079-0.488), and the authors concluded that AFCs do have a small effect on hyperactivity.³

A secondary analysis of children who previously showed worsening of hyperactivity with AFCs (either by parental report or in an earlier study) found a larger effect size (0.53). This finding implies that a subset of children whose parents notice an increase in hyperactivity with AFCs may benefit from exclusion. However, because the quality of the meta-analysis is limited by the heterogeneity of the studies, publication bias, unvalidated outcome measures, and variety of diagnoses in the participants, no recommendation can be made for AFC exclusion diets.³

Supplementation with fatty acids doesn’t improve symptoms
Because polyunsaturated fatty acids (PUFAs) are essential for brain development and function, a deficiency theoretically may contribute to a range of developmental disorders, including ADHD. An RCT of 63 children 6 to 12 years of age with ADHD randomly assigned the children to supplementation with the most abundant PUFA, docosahexanoic (DHA), or placebo for 4 months. Measured outcomes included objective attention evaluation by computer and written tests and standardized objective measures such as the Conners Rating Scales.⁴ The study found no significant improvement in any ADHD symptom.⁴

The findings of this trial were confirmed by another double-blinded RCT of 40 children with ADHD who were randomized to DHA or placebo. The second trial found no significant differences in ADHD symptoms after 2 months.⁵

Recommendations

The American Academy of Pediatrics states that there is a need for well-designed, rigorous studies of currently promoted but less well-established therapies for ADHD, such as occupational therapy, biofeedback, herbs, vitamins, and food supplements. These interventions aren’t supported by evidence-based studies at present.⁶

The American Academy of Child and Adolescent Psychiatry’s guidelines on managing ADHD don’t mention dietary interventions.⁷

Investigators from the Cincinnati Children’s Hospital report that elimination diets and food supplements have little or no quality evidence to support their effectiveness.⁸

Evidence summary

The prevalence of infertility in the US is approximately 15% to 17%.^2,3 Secondary infertility may comprise 80% of these cases, though reports vary.² Begin the evaluation of secondary infertility with a thorough history and physical, as outlined in the TABLE), followed by semen analysis and evaluation of ovulation.^1,3,4

TABLE
Secondary infertility? Here’s what to cover in the history and exam

Evaluate the male partner for varicoceles

The semen sample can be taken after the patient abstains from ejaculation for 2 to 6 days. Analyze the sample for volume, pH, sperm concentration, motility, and total number. If the sample is abnormal, repeat the analysis within 3 months.^1,5

Evaluate the male for varicoceles. A retrospective chart review compared 285 men with secondary infertility with 285 men with primary infertility. Varicoceles were the cause of secondary infertility in 177 (69%) of men with secondary infertility compared with 128 (50%) of men with primary infertility (P<.0001).⁶

Order tests to evaluate ovulation

To evaluate ovulation, look at menstrual history, serum progesterone, and urine luteinizing hormone (LH).^1,3,4 If the woman has signs of androgenic dysfunction, draw tests for LH, thyroid-stimulating hormone, follicle-stimulating hormone (FSH), testosterone, prolactin, and 17-hydroxyprogesterone. A woman with irregular menses should have her LH and FSH checked.¹

A hysterosalpingogram is an effective first test in the evaluation of the uterine cavity and tubal patency.^1,7,8 If the woman has comorbidities—such as a history of pelvic inflammatory disease, previous ectopic pregnancy, or endometriosis—then laparoscopy should be the initial test.^1,3 One study demonstrated increased diagnostic yield with a combined approach of hysteroscopy and laparoscopy, in communities where the risk of pelvic infection was great.⁹

Routine postcoital testing is unnecessary.¹⁰ A randomized controlled trial compared 227 couples who received the postcoital test with 217 couples who did not. Routine use of the postcoital test led to more tests and more treatments but had no significant effect on the pregnancy rate.

Recommendations from others

According to the Royal College of Obstetricians and Gynecologists:¹

1. The use of basal body temperature charts to confirm ovulation does not reliably predict ovulation and is not recommended.
2. The routine measurement of thyroid function should not be offered.
3. Women should not be offered an endometrial biopsy to evaluate the luteal phase because there is no evidence that medical treatment of luteal phase defect improves pregnancy rates.
4. Women who are not known to have comorbidities (such as pelvic inflammatory disease, previous ectopic pregnancy, or endometriosis) should be offered hysterosalpingography to screen for tubal occlusion.
5. Women who are thought to have comorbidities should be offered laparoscopy and dye so that tubal and other pelvic pathology can be assessed at the same time.

Evidence summary

The prevalence of infertility in the US is approximately 15% to 17%.^2,3 Secondary infertility may comprise 80% of these cases, though reports vary.² Begin the evaluation of secondary infertility with a thorough history and physical, as outlined in the TABLE), followed by semen analysis and evaluation of ovulation.^1,3,4

TABLE
Secondary infertility? Here’s what to cover in the history and exam

Evaluate the male partner for varicoceles

The semen sample can be taken after the patient abstains from ejaculation for 2 to 6 days. Analyze the sample for volume, pH, sperm concentration, motility, and total number. If the sample is abnormal, repeat the analysis within 3 months.^1,5

Evaluate the male for varicoceles. A retrospective chart review compared 285 men with secondary infertility with 285 men with primary infertility. Varicoceles were the cause of secondary infertility in 177 (69%) of men with secondary infertility compared with 128 (50%) of men with primary infertility (P<.0001).⁶

Order tests to evaluate ovulation

To evaluate ovulation, look at menstrual history, serum progesterone, and urine luteinizing hormone (LH).^1,3,4 If the woman has signs of androgenic dysfunction, draw tests for LH, thyroid-stimulating hormone, follicle-stimulating hormone (FSH), testosterone, prolactin, and 17-hydroxyprogesterone. A woman with irregular menses should have her LH and FSH checked.¹

A hysterosalpingogram is an effective first test in the evaluation of the uterine cavity and tubal patency.^1,7,8 If the woman has comorbidities—such as a history of pelvic inflammatory disease, previous ectopic pregnancy, or endometriosis—then laparoscopy should be the initial test.^1,3 One study demonstrated increased diagnostic yield with a combined approach of hysteroscopy and laparoscopy, in communities where the risk of pelvic infection was great.⁹

Routine postcoital testing is unnecessary.¹⁰ A randomized controlled trial compared 227 couples who received the postcoital test with 217 couples who did not. Routine use of the postcoital test led to more tests and more treatments but had no significant effect on the pregnancy rate.

Recommendations from others

According to the Royal College of Obstetricians and Gynecologists:¹

1. The use of basal body temperature charts to confirm ovulation does not reliably predict ovulation and is not recommended.
2. The routine measurement of thyroid function should not be offered.
3. Women should not be offered an endometrial biopsy to evaluate the luteal phase because there is no evidence that medical treatment of luteal phase defect improves pregnancy rates.
4. Women who are not known to have comorbidities (such as pelvic inflammatory disease, previous ectopic pregnancy, or endometriosis) should be offered hysterosalpingography to screen for tubal occlusion.
5. Women who are thought to have comorbidities should be offered laparoscopy and dye so that tubal and other pelvic pathology can be assessed at the same time.

Evidence summary

The prevalence of infertility in the US is approximately 15% to 17%.^2,3 Secondary infertility may comprise 80% of these cases, though reports vary.² Begin the evaluation of secondary infertility with a thorough history and physical, as outlined in the TABLE), followed by semen analysis and evaluation of ovulation.^1,3,4

TABLE
Secondary infertility? Here’s what to cover in the history and exam

Evaluate the male partner for varicoceles

The semen sample can be taken after the patient abstains from ejaculation for 2 to 6 days. Analyze the sample for volume, pH, sperm concentration, motility, and total number. If the sample is abnormal, repeat the analysis within 3 months.^1,5

Evaluate the male for varicoceles. A retrospective chart review compared 285 men with secondary infertility with 285 men with primary infertility. Varicoceles were the cause of secondary infertility in 177 (69%) of men with secondary infertility compared with 128 (50%) of men with primary infertility (P<.0001).⁶

Order tests to evaluate ovulation

To evaluate ovulation, look at menstrual history, serum progesterone, and urine luteinizing hormone (LH).^1,3,4 If the woman has signs of androgenic dysfunction, draw tests for LH, thyroid-stimulating hormone, follicle-stimulating hormone (FSH), testosterone, prolactin, and 17-hydroxyprogesterone. A woman with irregular menses should have her LH and FSH checked.¹

A hysterosalpingogram is an effective first test in the evaluation of the uterine cavity and tubal patency.^1,7,8 If the woman has comorbidities—such as a history of pelvic inflammatory disease, previous ectopic pregnancy, or endometriosis—then laparoscopy should be the initial test.^1,3 One study demonstrated increased diagnostic yield with a combined approach of hysteroscopy and laparoscopy, in communities where the risk of pelvic infection was great.⁹

Routine postcoital testing is unnecessary.¹⁰ A randomized controlled trial compared 227 couples who received the postcoital test with 217 couples who did not. Routine use of the postcoital test led to more tests and more treatments but had no significant effect on the pregnancy rate.

Recommendations from others

According to the Royal College of Obstetricians and Gynecologists:¹

1. The use of basal body temperature charts to confirm ovulation does not reliably predict ovulation and is not recommended.
2. The routine measurement of thyroid function should not be offered.
3. Women should not be offered an endometrial biopsy to evaluate the luteal phase because there is no evidence that medical treatment of luteal phase defect improves pregnancy rates.
4. Women who are not known to have comorbidities (such as pelvic inflammatory disease, previous ectopic pregnancy, or endometriosis) should be offered hysterosalpingography to screen for tubal occlusion.
5. Women who are thought to have comorbidities should be offered laparoscopy and dye so that tubal and other pelvic pathology can be assessed at the same time.

Evidence summary

Because of the significant inflammatory sequelae of PID, it is the standard of care to treat women with suggestive signs and symptoms. Clinical diagnosis has a positive predictive value of 65% to 90% compared with laparoscopy.¹ While no single test is both sensitive and specific, a combination of biochemical tests for inflammation may improve the ability to rule out PID.

A prospective cohort study of 120 women presenting to an ambulatory center with symptoms of PID evaluated the tests commonly used to support the clinical diagnosis of PID.² The objective criteria used for diagnosis included histologic evidence of acute endometritis via endometrial biopsy, purulent exudates in the pelvis on laparoscopy, or microbiologic evidence of Neisseris gonorrhea or Chlamydia trachomatis from the upper genital tract. The Table shows the sensitivities, specificities, and predictive values for an elevated white blood cells (>10,000/mm), ESR (>15 mm/hr), CRP (>5 mg/dL), and increased vaginal white blood cells (>3 white blood cells/high-power field) for detection of PID. If all 4 test results are negative, PID is reliably ruled out with a sensitivity of 100%. These results may be an overestimate, as the gold standard was not uniformly applied.

The role of CRP and ESR in the diagnosis of acute PID was studied in 41 women with clinically suspected acute PID who presented to a university department of obstetrics and gynecology.³ Women underwent laparoscopy, endometrial sampling, and cultures of the upper genital tract to confirm the diagnosis. When considered together, a positive value in either the ESR (cutoff level of 15 mm/hr) or CRP (cutoff >20 mg/dL) had a sensitivity of 91% and a specificity of 50%.

Another report looked at the ability of ESR and CRP to differentiate between mild, moderate, and severe PID in 72 women undergoing laparoscopy at a university department of gynecology.⁴ The cutoff levels were ESR >40 mm/hr and CRP >60 mg/dL. If either test was abnormal, the sensitivity and the negative predictive value for severe disease were 97% and 96%, respectively ( Table). All patients with tuboovarian abscess or perihepatitis and 6 of 7 patients who had anaerobic bacteria isolated from the fallopian tubes tested positive with these cutoff levels.

A meta-analysis from 1991 found 12 studies, not including any of the above studies, and assessed the laboratory criteria for the diagnosis of PID. No single or combination diagnostic indicator was found to reliably predict PID. However, the CRP and the ESR were useful in ruling out PID, with good sensitivities for CRP in 4 of 4 studies analyzed (74%–93%) and for the ESR in 4 of 6 studies (64%–81%). Ten of 12 studies used laparoscopy as the gold standard.⁵

TABLE
Diagnostic performance of blood tests for pelvic inflammatory disease

Recommendations from others

The Centers for Disease Control and Prevention makes no specific recommendation for the use of specific blood tests in the diagnosis of PID.¹ The Association for Genitourinary Medicine states that an elevated ESR or CRP supports the diagnosis of PID.⁶

Evidence summary

Because of the significant inflammatory sequelae of PID, it is the standard of care to treat women with suggestive signs and symptoms. Clinical diagnosis has a positive predictive value of 65% to 90% compared with laparoscopy.¹ While no single test is both sensitive and specific, a combination of biochemical tests for inflammation may improve the ability to rule out PID.

A prospective cohort study of 120 women presenting to an ambulatory center with symptoms of PID evaluated the tests commonly used to support the clinical diagnosis of PID.² The objective criteria used for diagnosis included histologic evidence of acute endometritis via endometrial biopsy, purulent exudates in the pelvis on laparoscopy, or microbiologic evidence of Neisseris gonorrhea or Chlamydia trachomatis from the upper genital tract. The Table shows the sensitivities, specificities, and predictive values for an elevated white blood cells (>10,000/mm), ESR (>15 mm/hr), CRP (>5 mg/dL), and increased vaginal white blood cells (>3 white blood cells/high-power field) for detection of PID. If all 4 test results are negative, PID is reliably ruled out with a sensitivity of 100%. These results may be an overestimate, as the gold standard was not uniformly applied.

The role of CRP and ESR in the diagnosis of acute PID was studied in 41 women with clinically suspected acute PID who presented to a university department of obstetrics and gynecology.³ Women underwent laparoscopy, endometrial sampling, and cultures of the upper genital tract to confirm the diagnosis. When considered together, a positive value in either the ESR (cutoff level of 15 mm/hr) or CRP (cutoff >20 mg/dL) had a sensitivity of 91% and a specificity of 50%.

Another report looked at the ability of ESR and CRP to differentiate between mild, moderate, and severe PID in 72 women undergoing laparoscopy at a university department of gynecology.⁴ The cutoff levels were ESR >40 mm/hr and CRP >60 mg/dL. If either test was abnormal, the sensitivity and the negative predictive value for severe disease were 97% and 96%, respectively ( Table). All patients with tuboovarian abscess or perihepatitis and 6 of 7 patients who had anaerobic bacteria isolated from the fallopian tubes tested positive with these cutoff levels.

A meta-analysis from 1991 found 12 studies, not including any of the above studies, and assessed the laboratory criteria for the diagnosis of PID. No single or combination diagnostic indicator was found to reliably predict PID. However, the CRP and the ESR were useful in ruling out PID, with good sensitivities for CRP in 4 of 4 studies analyzed (74%–93%) and for the ESR in 4 of 6 studies (64%–81%). Ten of 12 studies used laparoscopy as the gold standard.⁵

TABLE
Diagnostic performance of blood tests for pelvic inflammatory disease

Recommendations from others

The Centers for Disease Control and Prevention makes no specific recommendation for the use of specific blood tests in the diagnosis of PID.¹ The Association for Genitourinary Medicine states that an elevated ESR or CRP supports the diagnosis of PID.⁶

Evidence summary

Because of the significant inflammatory sequelae of PID, it is the standard of care to treat women with suggestive signs and symptoms. Clinical diagnosis has a positive predictive value of 65% to 90% compared with laparoscopy.¹ While no single test is both sensitive and specific, a combination of biochemical tests for inflammation may improve the ability to rule out PID.

A prospective cohort study of 120 women presenting to an ambulatory center with symptoms of PID evaluated the tests commonly used to support the clinical diagnosis of PID.² The objective criteria used for diagnosis included histologic evidence of acute endometritis via endometrial biopsy, purulent exudates in the pelvis on laparoscopy, or microbiologic evidence of Neisseris gonorrhea or Chlamydia trachomatis from the upper genital tract. The Table shows the sensitivities, specificities, and predictive values for an elevated white blood cells (>10,000/mm), ESR (>15 mm/hr), CRP (>5 mg/dL), and increased vaginal white blood cells (>3 white blood cells/high-power field) for detection of PID. If all 4 test results are negative, PID is reliably ruled out with a sensitivity of 100%. These results may be an overestimate, as the gold standard was not uniformly applied.

The role of CRP and ESR in the diagnosis of acute PID was studied in 41 women with clinically suspected acute PID who presented to a university department of obstetrics and gynecology.³ Women underwent laparoscopy, endometrial sampling, and cultures of the upper genital tract to confirm the diagnosis. When considered together, a positive value in either the ESR (cutoff level of 15 mm/hr) or CRP (cutoff >20 mg/dL) had a sensitivity of 91% and a specificity of 50%.

Another report looked at the ability of ESR and CRP to differentiate between mild, moderate, and severe PID in 72 women undergoing laparoscopy at a university department of gynecology.⁴ The cutoff levels were ESR >40 mm/hr and CRP >60 mg/dL. If either test was abnormal, the sensitivity and the negative predictive value for severe disease were 97% and 96%, respectively ( Table). All patients with tuboovarian abscess or perihepatitis and 6 of 7 patients who had anaerobic bacteria isolated from the fallopian tubes tested positive with these cutoff levels.

A meta-analysis from 1991 found 12 studies, not including any of the above studies, and assessed the laboratory criteria for the diagnosis of PID. No single or combination diagnostic indicator was found to reliably predict PID. However, the CRP and the ESR were useful in ruling out PID, with good sensitivities for CRP in 4 of 4 studies analyzed (74%–93%) and for the ESR in 4 of 6 studies (64%–81%). Ten of 12 studies used laparoscopy as the gold standard.⁵

TABLE
Diagnostic performance of blood tests for pelvic inflammatory disease

Recommendations from others

The Centers for Disease Control and Prevention makes no specific recommendation for the use of specific blood tests in the diagnosis of PID.¹ The Association for Genitourinary Medicine states that an elevated ESR or CRP supports the diagnosis of PID.⁶