What’s the best treatment for cradle cap?

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What’s the best treatment for cradle cap?
EVIDENCE-BASED ANSWER

Ketoconazole (Nizoral) shampoo appears to be a safe and efficacious treatment for infants with cradle cap (strength of recommendation [SOR]: C, consensus, usual practice, opinion, disease-oriented evidence, and case series). Limit topical corticosteroids to severe cases because of possible systemic absorption (SOR: C). Overnight application of emollients followed by gentle brushing and washing with baby shampoo helps to remove the scale associated with cradle cap (SOR: C).

Clinical commentary

If parents can’t leave it be, recommend mineral oil and a brush to loosen scale
Valerie J. King, MD, MPH
Oregon Health Sciences University, Portland

Cradle cap is distressing to parents. They want everyone else to see how gorgeous their new baby is, and cradle cap can make their beautiful little one look scruffy. My standard therapy has been to stress to the parents that it isn’t a problem for the baby.

If the parents still want to do something about it, I recommend mineral oil and a soft brush to loosen the scale. Although no evidence supports this, it seems safe and is somewhat effective.

This review makes me feel more comfortable with recommending ketoconazole shampoo when mineral oil proves insufficient. For resistant cases, a cute hat can work wonders.

 

Evidence summary

Cradle cap is a form of seborrheic dermatitis that manifests as greasy patches of scaling on the scalp of infants between the second week and sixth month of life.1,2 Untreated, it usually resolves at 8 months.1 It’s generally nonpruritic and doesn’t bother the infant, though it can be a stressor for parents.1

Researchers have noted a potential link with increased concentrations of the yeast Malassezia furfur (formerly Pityrosporum ovale), but a causative mechanism has not been identified.1,2 Overnight use of emollients such as mineral oil to soften scales followed by gentle brushing and washing with baby shampoo is an accepted treatment, although no trials could be found to show its efficacy for infants.1,3

Numerous treatments for seborrheic dermatitis with proven efficacy for adults have been adopted for use for infants. These include topical antifungals, anti-dandruff shampoos with zinc pyrithione or selenium sulfide, coal tar preparations, and episodic topical corticosteroids.1,4 Although each of these agents is used for infants with cradle cap, significantly sized randomized controlled trials in this age group are essentially absent.

Although limited evidence exists for seborrhea treatment in any age group, ketoconazole shampoo appears to be backed by the strongest evidence. For example, an uncontrolled multicenter trial with 575 adults found ketoconazole shampoo was superior to placebo for treatment of scalp seborrheic dermatitis with an 88% “excellent response” rate (P<.0001, no relative risk or confidence intervals given).4

 

 

 

Based on small studies, ketoconazole appears safe and effective for infants. A small (n=13) phase I safety trial of infants demonstrated that ketoconazole shampoo applied twice weekly for 1 month resulted in no detectable serum ketoconazole levels or elevation in liver function tests.5 In another small (n=19) uncontrolled study of once-daily ketoconazole 2% cream, 79% of infants affected with seborrheic dermatitis of the scalp and diaper area showed good response by day 10 (no statistical methods reported). Peak plasma ketoconazole levels in this study were only 1% to 2% of those documented after systemic administration.6

Studies conducted on topical steroids have also shown weak data. An unblinded uncontrolled comparative study of 2% ketoconazole cream and 1% hydrocortisone cream in the treatment of infantile seborrheic dermatitis revealed no statistical difference (31% vs 35%) in severity for 48 infants. All skin lesions in both treatment groups were cleared by the end of the second week of treatment.2

Multiple authors note safety concerns when considering treatment for mild and self-limited conditions such as cradle cap. Several studies have demonstrated systemic absorption and, in some cases, adrenocortical suppression when using mild topical steroids such as 1% hydrocortisone cream in pediatric populations.1,3,7

Recommendations from others

The guidance from PRODIGY (the UK’s National Health Service primary care database) recommends regular washing with baby shampoo followed by gentle brushing. Alternatively, softening the scale with mineral oil, followed by gentle brushing and shampooing is an alternative approach. Ketoconazole 2% shampoo or cream once a day has been shown to be effective; PRODIGY recommends avoiding topical corticosteroids.1

A review article recommends daily shampooing with an unmedicated shampoo. If this doesn’t work, the authors recommend trying a dandruff shampoo and softening the scales with mineral oil before washing.8 While the American Academy of Dermatology has no official guidelines on this subject, their patient-oriented pamphlet Dermatology Insights suggests that “cradle cap is treated with anti-dandruff or baby shampoo, with or without hydrocortisone lotion or cream, depending on the severity.”9

Acknowledgments

The opinions and assertions contained herein are the private views of the authors and not to be construed as official, or as reflecting the views of the US Air Force Medical Service or the US Air Force at large.

References

1. PRODIGY [database]. Seborrhoeic dermatitis. Knowledge Guidance structured review (2006). Sowerby Centre for Health Informatics at Newcastle Ltd (SCHIN). Available at: www.prodigy.nhs.uk/seborrhoeic_dermatitis. Accessed on February 6, 2007.

2. Wannanukul S, Chiabunkana J. Comparative study of 2% ketoconazole cream and 1% hydrocortisone cream in the treatment of infantile seborrheic dermatitis. J Med Assoc Thai 2004;87:S68-S71.

3. Janniger CK. Infantile seborrheic dermatitis: An approach to cradle cap. Cutis 1993;51:233-235.

4. Peter RU, Richarz-Barthauer U. Successful treatment and prophylaxis of scalp seborrhoeic dermatitis and dandruff with 2% ketoconazole shampoo: results of a multicentre, double-blind, placebo-controlled trial. Br J Dermatol 1995;132:441-445.

5. Brodell R, Patel S, Venglarick J, Moses D, Gemmel D. The safety of ketoconazole shampoo for infantile seborrheic dermatitis. Pediatr Dermatol 1998;15:406-407.

6. Taieb A, Legrain V, Palmier C, Lejean S, Six M, Maleville J. Topical ketoconazole for infantile seborrhoeic dermatitis. Dermatologica 1990;181:26-32.

7. Turpeinen M, Salo O, Leisti S. Effect of percutaneous absorption of hydrocortisone on adrenocortical responsiveness in infants with severe skin disease. Br J Dermatol 1986;115:475-484.

8. Seborrhea: What it is and how to treat it. Am Fam Physician 2000;61:2173-2174.

9. When to be concerned about childhood hair shedding. Dermatology Insights 2003;4(1):24.-Available at: www.aad.org/NR/rdonlyres/0AA67E605-01E104C7A-B493-9959923A8282/0/di_spring03.pdf#page=24. Accessed on February 6, 2007.

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Paul Crawford, MD
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University of North Carolina at Chapel Hill

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EVIDENCE-BASED ANSWER

Ketoconazole (Nizoral) shampoo appears to be a safe and efficacious treatment for infants with cradle cap (strength of recommendation [SOR]: C, consensus, usual practice, opinion, disease-oriented evidence, and case series). Limit topical corticosteroids to severe cases because of possible systemic absorption (SOR: C). Overnight application of emollients followed by gentle brushing and washing with baby shampoo helps to remove the scale associated with cradle cap (SOR: C).

Clinical commentary

If parents can’t leave it be, recommend mineral oil and a brush to loosen scale
Valerie J. King, MD, MPH
Oregon Health Sciences University, Portland

Cradle cap is distressing to parents. They want everyone else to see how gorgeous their new baby is, and cradle cap can make their beautiful little one look scruffy. My standard therapy has been to stress to the parents that it isn’t a problem for the baby.

If the parents still want to do something about it, I recommend mineral oil and a soft brush to loosen the scale. Although no evidence supports this, it seems safe and is somewhat effective.

This review makes me feel more comfortable with recommending ketoconazole shampoo when mineral oil proves insufficient. For resistant cases, a cute hat can work wonders.

 

Evidence summary

Cradle cap is a form of seborrheic dermatitis that manifests as greasy patches of scaling on the scalp of infants between the second week and sixth month of life.1,2 Untreated, it usually resolves at 8 months.1 It’s generally nonpruritic and doesn’t bother the infant, though it can be a stressor for parents.1

Researchers have noted a potential link with increased concentrations of the yeast Malassezia furfur (formerly Pityrosporum ovale), but a causative mechanism has not been identified.1,2 Overnight use of emollients such as mineral oil to soften scales followed by gentle brushing and washing with baby shampoo is an accepted treatment, although no trials could be found to show its efficacy for infants.1,3

Numerous treatments for seborrheic dermatitis with proven efficacy for adults have been adopted for use for infants. These include topical antifungals, anti-dandruff shampoos with zinc pyrithione or selenium sulfide, coal tar preparations, and episodic topical corticosteroids.1,4 Although each of these agents is used for infants with cradle cap, significantly sized randomized controlled trials in this age group are essentially absent.

Although limited evidence exists for seborrhea treatment in any age group, ketoconazole shampoo appears to be backed by the strongest evidence. For example, an uncontrolled multicenter trial with 575 adults found ketoconazole shampoo was superior to placebo for treatment of scalp seborrheic dermatitis with an 88% “excellent response” rate (P<.0001, no relative risk or confidence intervals given).4

 

 

 

Based on small studies, ketoconazole appears safe and effective for infants. A small (n=13) phase I safety trial of infants demonstrated that ketoconazole shampoo applied twice weekly for 1 month resulted in no detectable serum ketoconazole levels or elevation in liver function tests.5 In another small (n=19) uncontrolled study of once-daily ketoconazole 2% cream, 79% of infants affected with seborrheic dermatitis of the scalp and diaper area showed good response by day 10 (no statistical methods reported). Peak plasma ketoconazole levels in this study were only 1% to 2% of those documented after systemic administration.6

Studies conducted on topical steroids have also shown weak data. An unblinded uncontrolled comparative study of 2% ketoconazole cream and 1% hydrocortisone cream in the treatment of infantile seborrheic dermatitis revealed no statistical difference (31% vs 35%) in severity for 48 infants. All skin lesions in both treatment groups were cleared by the end of the second week of treatment.2

Multiple authors note safety concerns when considering treatment for mild and self-limited conditions such as cradle cap. Several studies have demonstrated systemic absorption and, in some cases, adrenocortical suppression when using mild topical steroids such as 1% hydrocortisone cream in pediatric populations.1,3,7

Recommendations from others

The guidance from PRODIGY (the UK’s National Health Service primary care database) recommends regular washing with baby shampoo followed by gentle brushing. Alternatively, softening the scale with mineral oil, followed by gentle brushing and shampooing is an alternative approach. Ketoconazole 2% shampoo or cream once a day has been shown to be effective; PRODIGY recommends avoiding topical corticosteroids.1

A review article recommends daily shampooing with an unmedicated shampoo. If this doesn’t work, the authors recommend trying a dandruff shampoo and softening the scales with mineral oil before washing.8 While the American Academy of Dermatology has no official guidelines on this subject, their patient-oriented pamphlet Dermatology Insights suggests that “cradle cap is treated with anti-dandruff or baby shampoo, with or without hydrocortisone lotion or cream, depending on the severity.”9

Acknowledgments

The opinions and assertions contained herein are the private views of the authors and not to be construed as official, or as reflecting the views of the US Air Force Medical Service or the US Air Force at large.

EVIDENCE-BASED ANSWER

Ketoconazole (Nizoral) shampoo appears to be a safe and efficacious treatment for infants with cradle cap (strength of recommendation [SOR]: C, consensus, usual practice, opinion, disease-oriented evidence, and case series). Limit topical corticosteroids to severe cases because of possible systemic absorption (SOR: C). Overnight application of emollients followed by gentle brushing and washing with baby shampoo helps to remove the scale associated with cradle cap (SOR: C).

Clinical commentary

If parents can’t leave it be, recommend mineral oil and a brush to loosen scale
Valerie J. King, MD, MPH
Oregon Health Sciences University, Portland

Cradle cap is distressing to parents. They want everyone else to see how gorgeous their new baby is, and cradle cap can make their beautiful little one look scruffy. My standard therapy has been to stress to the parents that it isn’t a problem for the baby.

If the parents still want to do something about it, I recommend mineral oil and a soft brush to loosen the scale. Although no evidence supports this, it seems safe and is somewhat effective.

This review makes me feel more comfortable with recommending ketoconazole shampoo when mineral oil proves insufficient. For resistant cases, a cute hat can work wonders.

 

Evidence summary

Cradle cap is a form of seborrheic dermatitis that manifests as greasy patches of scaling on the scalp of infants between the second week and sixth month of life.1,2 Untreated, it usually resolves at 8 months.1 It’s generally nonpruritic and doesn’t bother the infant, though it can be a stressor for parents.1

Researchers have noted a potential link with increased concentrations of the yeast Malassezia furfur (formerly Pityrosporum ovale), but a causative mechanism has not been identified.1,2 Overnight use of emollients such as mineral oil to soften scales followed by gentle brushing and washing with baby shampoo is an accepted treatment, although no trials could be found to show its efficacy for infants.1,3

Numerous treatments for seborrheic dermatitis with proven efficacy for adults have been adopted for use for infants. These include topical antifungals, anti-dandruff shampoos with zinc pyrithione or selenium sulfide, coal tar preparations, and episodic topical corticosteroids.1,4 Although each of these agents is used for infants with cradle cap, significantly sized randomized controlled trials in this age group are essentially absent.

Although limited evidence exists for seborrhea treatment in any age group, ketoconazole shampoo appears to be backed by the strongest evidence. For example, an uncontrolled multicenter trial with 575 adults found ketoconazole shampoo was superior to placebo for treatment of scalp seborrheic dermatitis with an 88% “excellent response” rate (P<.0001, no relative risk or confidence intervals given).4

 

 

 

Based on small studies, ketoconazole appears safe and effective for infants. A small (n=13) phase I safety trial of infants demonstrated that ketoconazole shampoo applied twice weekly for 1 month resulted in no detectable serum ketoconazole levels or elevation in liver function tests.5 In another small (n=19) uncontrolled study of once-daily ketoconazole 2% cream, 79% of infants affected with seborrheic dermatitis of the scalp and diaper area showed good response by day 10 (no statistical methods reported). Peak plasma ketoconazole levels in this study were only 1% to 2% of those documented after systemic administration.6

Studies conducted on topical steroids have also shown weak data. An unblinded uncontrolled comparative study of 2% ketoconazole cream and 1% hydrocortisone cream in the treatment of infantile seborrheic dermatitis revealed no statistical difference (31% vs 35%) in severity for 48 infants. All skin lesions in both treatment groups were cleared by the end of the second week of treatment.2

Multiple authors note safety concerns when considering treatment for mild and self-limited conditions such as cradle cap. Several studies have demonstrated systemic absorption and, in some cases, adrenocortical suppression when using mild topical steroids such as 1% hydrocortisone cream in pediatric populations.1,3,7

Recommendations from others

The guidance from PRODIGY (the UK’s National Health Service primary care database) recommends regular washing with baby shampoo followed by gentle brushing. Alternatively, softening the scale with mineral oil, followed by gentle brushing and shampooing is an alternative approach. Ketoconazole 2% shampoo or cream once a day has been shown to be effective; PRODIGY recommends avoiding topical corticosteroids.1

A review article recommends daily shampooing with an unmedicated shampoo. If this doesn’t work, the authors recommend trying a dandruff shampoo and softening the scales with mineral oil before washing.8 While the American Academy of Dermatology has no official guidelines on this subject, their patient-oriented pamphlet Dermatology Insights suggests that “cradle cap is treated with anti-dandruff or baby shampoo, with or without hydrocortisone lotion or cream, depending on the severity.”9

Acknowledgments

The opinions and assertions contained herein are the private views of the authors and not to be construed as official, or as reflecting the views of the US Air Force Medical Service or the US Air Force at large.

References

1. PRODIGY [database]. Seborrhoeic dermatitis. Knowledge Guidance structured review (2006). Sowerby Centre for Health Informatics at Newcastle Ltd (SCHIN). Available at: www.prodigy.nhs.uk/seborrhoeic_dermatitis. Accessed on February 6, 2007.

2. Wannanukul S, Chiabunkana J. Comparative study of 2% ketoconazole cream and 1% hydrocortisone cream in the treatment of infantile seborrheic dermatitis. J Med Assoc Thai 2004;87:S68-S71.

3. Janniger CK. Infantile seborrheic dermatitis: An approach to cradle cap. Cutis 1993;51:233-235.

4. Peter RU, Richarz-Barthauer U. Successful treatment and prophylaxis of scalp seborrhoeic dermatitis and dandruff with 2% ketoconazole shampoo: results of a multicentre, double-blind, placebo-controlled trial. Br J Dermatol 1995;132:441-445.

5. Brodell R, Patel S, Venglarick J, Moses D, Gemmel D. The safety of ketoconazole shampoo for infantile seborrheic dermatitis. Pediatr Dermatol 1998;15:406-407.

6. Taieb A, Legrain V, Palmier C, Lejean S, Six M, Maleville J. Topical ketoconazole for infantile seborrhoeic dermatitis. Dermatologica 1990;181:26-32.

7. Turpeinen M, Salo O, Leisti S. Effect of percutaneous absorption of hydrocortisone on adrenocortical responsiveness in infants with severe skin disease. Br J Dermatol 1986;115:475-484.

8. Seborrhea: What it is and how to treat it. Am Fam Physician 2000;61:2173-2174.

9. When to be concerned about childhood hair shedding. Dermatology Insights 2003;4(1):24.-Available at: www.aad.org/NR/rdonlyres/0AA67E605-01E104C7A-B493-9959923A8282/0/di_spring03.pdf#page=24. Accessed on February 6, 2007.

References

1. PRODIGY [database]. Seborrhoeic dermatitis. Knowledge Guidance structured review (2006). Sowerby Centre for Health Informatics at Newcastle Ltd (SCHIN). Available at: www.prodigy.nhs.uk/seborrhoeic_dermatitis. Accessed on February 6, 2007.

2. Wannanukul S, Chiabunkana J. Comparative study of 2% ketoconazole cream and 1% hydrocortisone cream in the treatment of infantile seborrheic dermatitis. J Med Assoc Thai 2004;87:S68-S71.

3. Janniger CK. Infantile seborrheic dermatitis: An approach to cradle cap. Cutis 1993;51:233-235.

4. Peter RU, Richarz-Barthauer U. Successful treatment and prophylaxis of scalp seborrhoeic dermatitis and dandruff with 2% ketoconazole shampoo: results of a multicentre, double-blind, placebo-controlled trial. Br J Dermatol 1995;132:441-445.

5. Brodell R, Patel S, Venglarick J, Moses D, Gemmel D. The safety of ketoconazole shampoo for infantile seborrheic dermatitis. Pediatr Dermatol 1998;15:406-407.

6. Taieb A, Legrain V, Palmier C, Lejean S, Six M, Maleville J. Topical ketoconazole for infantile seborrhoeic dermatitis. Dermatologica 1990;181:26-32.

7. Turpeinen M, Salo O, Leisti S. Effect of percutaneous absorption of hydrocortisone on adrenocortical responsiveness in infants with severe skin disease. Br J Dermatol 1986;115:475-484.

8. Seborrhea: What it is and how to treat it. Am Fam Physician 2000;61:2173-2174.

9. When to be concerned about childhood hair shedding. Dermatology Insights 2003;4(1):24.-Available at: www.aad.org/NR/rdonlyres/0AA67E605-01E104C7A-B493-9959923A8282/0/di_spring03.pdf#page=24. Accessed on February 6, 2007.

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What is the best treatment for infants with colic?

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What is the best treatment for infants with colic?
EVIDENCE-BASED ANSWER

Infantile colic, defined as excessive crying in an otherwise healthy baby, is a distressing phenomenon, but there is little evidence to support the many treatments offered. Several small studies report some benefit from use of a hypoallergenic (protein hydrolysate) formula, maternal diet adjustment (focusing on a low-allergen diet), and reduced stimulation of the infant. While dicyclomine has been shown to be effective for colic, there are significant concerns about its safety, and the manufacturer has contraindicated its use in this population. An herbal tea containing chamomile, vervain, licorice, fennel, and balm-mint was also effective in a small RCT, but the volume necessary for treatment limits its usefulness (strength of recommendation: B, inconsistent or limited-quality patientoriented evidence). The one proven treatment is time, as this behavior tends to dissipate by 6 months of age.

CLINICAL COMMENTARY

For pure colic, only time will help
Anne Eglash, MD
Department of Family Medicine, University of Wisconsin Medical School, Madison

A broad definition for colic may capture infants who cry for a variety of reasons. I consider pure colic to be a patterned daily behavior of crying that a parent can predict will occur and stop at certain times, and the baby is fine at other times of day. For these babies, I wouldn’t expect a change in formula or maternal diet to help; they greatly improve by about age 3 months.

However, for babies who are fussy and difficult to console throughout day and night, further evaluation and dietary changes are worth trying. For breastfeeding mothers, I usually start with dairy avoidance and test the baby’s stools for microscopic blood to be sure there is no colitis related to maternal diet. Only if there is evidence of infant colitis or allergy should a more restrictive maternal diet be prescribed. For formula-fed infants, a change to a proteinhydrolysate formula is worth a try, the main risk being the cost of the formula.

 

Evidence summary

Colic has been described using the “rule of 3”: crying for at least 3 hours per day on at least 3 days per week for at least 3 weeks.1 The distinction can be subtle; a normal infant can cry more than 2 hours per day. This syndrome has its onset typically in the first few weeks of life. It spontaneously resolves by age 4 to 6 months. Prevalence depends on the definition used for colic; approximately 5% to 25% of infants meet some reasonable definition of colic.2 The cause of infantile colic is poorly understood. Although clinicians tend to focus on a likely gastrointestinal cause, neuropsychological issues, food allergy, and parenting misadventures are also potential contributing factors.

There are myriad strategies—ranging from craniosacral osteopathic manipulation to car ride simulation—offered for dealing with infantile colic. Although none of these treatments has been validated in rigorous studies, the available evidence offers tentative support for 3 strategies: (1) a trial of a hypoallergenic (protein hydrolysate) formula (for formula fed infants), (2) a low-allergen maternal diet (for breastfeeding mothers), and (3) reduced stimulation of the infant.

A systematic review analyzed controlled clinical trials lasting at least 3 days involving infants less than 6 months of age who cried excessively.3 Twenty-seven studies were included; the outcome measure was colic symptoms, typically reported as duration of crying. Two reports studying hypoallergenic (protein hydrolysate) formula in nearly 130 infants found an effect size of 0.22 (95% confidence interval [CI], 0.10–0.34) for the hypoallergenic formula. Additionally, 3 behavioral trials (involving nearly 200 infants) revealed the benefits of reduced stimulation of the colicky infant (effect size of 0.48; 95% CI, 0.23–0.74).

A more recent systematic review4 followed a similar high-quality search strategy and identified 22 articles, and reported a number needed to treat (NNT) of 6 for the 2 hypoallergenic formula studies identified in the previous review.4 Because of concern regarding the quality of the behavioral studies involving infants with colic, the authors of this second review only included 1 small (42 patients) trial of decreased stimulation, which resulted in a relative risk (RR) of 1.87 (95% CI, 1.04–3.34) and a NNT of 2. There was some inconclusive evidence to suggest benefit to dietary adjustment for breastfeeding mothers (specifically, the avoidance of cow’s milk and other potential allergens like nuts, eggs, and wheat).

 

 

 

A recent randomized controlled trial confirmed the value of this approach by showing significant improvement in distress scores of infants whose mothers followed a low-allergen diet (excluding dairy, soy, wheat, eggs, peanuts, tree nuts, and fish) for 7 days.5 This well-designed study included 107 patients (a relatively large sample in the published research about colic), and showed an absolute risk reduction of 37% (NNT=3) for those mothers following the challenge.

A small RCT (43 patients) suggested efficacy in the substitution of a whey hydrolysate formula in place of cow’s milkbased formula for infants with colic (casein hydrolysate formula has been more widely studied), but there continues to be controversy regarding the preferred protein hydrolysate formula (whey vs casein) in the treatment of colic.3

Several medications have been tested in RCTs; only dicyclomine has shown an effect in a few small RCTs.3,4 However, there have been reports of apnea and other serious, although infrequent, adverse effects. For that reason, the manufacturer has contraindicated the use of this medication in infants aged <6 months.

A small (n=68) study of an herbal tea showed reduced symptoms (RR=0.57 favoring the active tea), although the mean volume of tea consumption (32 mL/kg/d) is a nutritional concern in this age group.6 No adverse events were noted, but the small sample size limits the ability to detect any but the most common events.

Recommendations from others

The American Gastroenterological Association recommends a hypoallergenic, protein hydrolysate formula for formula fed infants or a maternal low-allergen diet as an initial strategy for infant struggling with colic symptoms if the clinician is considering a diagnosis of (cow’s milk) allergy.7

The American Academy of Family Physicians on their familydoctor.org web site makes no specific formula or diet adjustment recommendations.8 The web site does list some techniques (eg, massage or warm compress of abdomen, swing or car rides) not supported by the available evidence. The National Library of Medicine and the National Institutes of Health web site Medline Plus presents similar information.9 The American Academy of Pediatrics does not address the topic on its public web site.

References

1. Wessel MA, Cobb JC, Jackson EB, Harris GS, Jr, Detwiler AC. Paroxysmal fussing in infancy, sometimes called colic. Pediatrics 1954;14:421-435.

2. Kilgour T, Wade S. Infantile colic. Clin Evid 2005;13:362-372.

3. Lucassen PL, Assendelft WJ, Gubbels JW, van Eijk JT, van Geldrop WJ, Neven AK. Effectiveness of treatments for infantile colic: systematic review. BMJ 1998;316:1563-1569.

4. Garrison MM, Christakis DA. A systematic review of treatments for infant colic. Pediatrics 2000;106:184-190.

5. Hill DJ, Roy N, Heine RG, et al. Effect of a low-allergen maternal diet on colic among breastfed infants: a randomized, controlled trial. Pediatrics 2005;116:e709-e715.

6. Lucassen PLBJ, Assendelft WJJ, Gubbels JW, van Eijk JT, Douwes AC. Infantile colic: crying time reduction with a whey hydrolysate: a double-blind, randomized, placebo-controlled trial. Pediatrics 2000;106:1349-1354.

7. Sampson HA, Sicherer SH, Birnbaum AH. AGA technical review on the evaluation of food allergy in gastrointestinal disorders. Gastroenterology 2001;120:1026-1040.

8. Familydoctor.org [web site]. Colic: Learning how to deal with your baby’s crying. Last updated April 2005. Available at: familydoctor.org/036.xml. Accessed on June 12, 2006.

9. Colic and crying. Medline Plus, last updated August 23, 2005. Available at: www.nlm.nih.gov/medlineplus/ency/article/000978.htm#Treatment. Accessed on June 12, 2006.

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EVIDENCE-BASED ANSWER

Infantile colic, defined as excessive crying in an otherwise healthy baby, is a distressing phenomenon, but there is little evidence to support the many treatments offered. Several small studies report some benefit from use of a hypoallergenic (protein hydrolysate) formula, maternal diet adjustment (focusing on a low-allergen diet), and reduced stimulation of the infant. While dicyclomine has been shown to be effective for colic, there are significant concerns about its safety, and the manufacturer has contraindicated its use in this population. An herbal tea containing chamomile, vervain, licorice, fennel, and balm-mint was also effective in a small RCT, but the volume necessary for treatment limits its usefulness (strength of recommendation: B, inconsistent or limited-quality patientoriented evidence). The one proven treatment is time, as this behavior tends to dissipate by 6 months of age.

CLINICAL COMMENTARY

For pure colic, only time will help
Anne Eglash, MD
Department of Family Medicine, University of Wisconsin Medical School, Madison

A broad definition for colic may capture infants who cry for a variety of reasons. I consider pure colic to be a patterned daily behavior of crying that a parent can predict will occur and stop at certain times, and the baby is fine at other times of day. For these babies, I wouldn’t expect a change in formula or maternal diet to help; they greatly improve by about age 3 months.

However, for babies who are fussy and difficult to console throughout day and night, further evaluation and dietary changes are worth trying. For breastfeeding mothers, I usually start with dairy avoidance and test the baby’s stools for microscopic blood to be sure there is no colitis related to maternal diet. Only if there is evidence of infant colitis or allergy should a more restrictive maternal diet be prescribed. For formula-fed infants, a change to a proteinhydrolysate formula is worth a try, the main risk being the cost of the formula.

 

Evidence summary

Colic has been described using the “rule of 3”: crying for at least 3 hours per day on at least 3 days per week for at least 3 weeks.1 The distinction can be subtle; a normal infant can cry more than 2 hours per day. This syndrome has its onset typically in the first few weeks of life. It spontaneously resolves by age 4 to 6 months. Prevalence depends on the definition used for colic; approximately 5% to 25% of infants meet some reasonable definition of colic.2 The cause of infantile colic is poorly understood. Although clinicians tend to focus on a likely gastrointestinal cause, neuropsychological issues, food allergy, and parenting misadventures are also potential contributing factors.

There are myriad strategies—ranging from craniosacral osteopathic manipulation to car ride simulation—offered for dealing with infantile colic. Although none of these treatments has been validated in rigorous studies, the available evidence offers tentative support for 3 strategies: (1) a trial of a hypoallergenic (protein hydrolysate) formula (for formula fed infants), (2) a low-allergen maternal diet (for breastfeeding mothers), and (3) reduced stimulation of the infant.

A systematic review analyzed controlled clinical trials lasting at least 3 days involving infants less than 6 months of age who cried excessively.3 Twenty-seven studies were included; the outcome measure was colic symptoms, typically reported as duration of crying. Two reports studying hypoallergenic (protein hydrolysate) formula in nearly 130 infants found an effect size of 0.22 (95% confidence interval [CI], 0.10–0.34) for the hypoallergenic formula. Additionally, 3 behavioral trials (involving nearly 200 infants) revealed the benefits of reduced stimulation of the colicky infant (effect size of 0.48; 95% CI, 0.23–0.74).

A more recent systematic review4 followed a similar high-quality search strategy and identified 22 articles, and reported a number needed to treat (NNT) of 6 for the 2 hypoallergenic formula studies identified in the previous review.4 Because of concern regarding the quality of the behavioral studies involving infants with colic, the authors of this second review only included 1 small (42 patients) trial of decreased stimulation, which resulted in a relative risk (RR) of 1.87 (95% CI, 1.04–3.34) and a NNT of 2. There was some inconclusive evidence to suggest benefit to dietary adjustment for breastfeeding mothers (specifically, the avoidance of cow’s milk and other potential allergens like nuts, eggs, and wheat).

 

 

 

A recent randomized controlled trial confirmed the value of this approach by showing significant improvement in distress scores of infants whose mothers followed a low-allergen diet (excluding dairy, soy, wheat, eggs, peanuts, tree nuts, and fish) for 7 days.5 This well-designed study included 107 patients (a relatively large sample in the published research about colic), and showed an absolute risk reduction of 37% (NNT=3) for those mothers following the challenge.

A small RCT (43 patients) suggested efficacy in the substitution of a whey hydrolysate formula in place of cow’s milkbased formula for infants with colic (casein hydrolysate formula has been more widely studied), but there continues to be controversy regarding the preferred protein hydrolysate formula (whey vs casein) in the treatment of colic.3

Several medications have been tested in RCTs; only dicyclomine has shown an effect in a few small RCTs.3,4 However, there have been reports of apnea and other serious, although infrequent, adverse effects. For that reason, the manufacturer has contraindicated the use of this medication in infants aged <6 months.

A small (n=68) study of an herbal tea showed reduced symptoms (RR=0.57 favoring the active tea), although the mean volume of tea consumption (32 mL/kg/d) is a nutritional concern in this age group.6 No adverse events were noted, but the small sample size limits the ability to detect any but the most common events.

Recommendations from others

The American Gastroenterological Association recommends a hypoallergenic, protein hydrolysate formula for formula fed infants or a maternal low-allergen diet as an initial strategy for infant struggling with colic symptoms if the clinician is considering a diagnosis of (cow’s milk) allergy.7

The American Academy of Family Physicians on their familydoctor.org web site makes no specific formula or diet adjustment recommendations.8 The web site does list some techniques (eg, massage or warm compress of abdomen, swing or car rides) not supported by the available evidence. The National Library of Medicine and the National Institutes of Health web site Medline Plus presents similar information.9 The American Academy of Pediatrics does not address the topic on its public web site.

EVIDENCE-BASED ANSWER

Infantile colic, defined as excessive crying in an otherwise healthy baby, is a distressing phenomenon, but there is little evidence to support the many treatments offered. Several small studies report some benefit from use of a hypoallergenic (protein hydrolysate) formula, maternal diet adjustment (focusing on a low-allergen diet), and reduced stimulation of the infant. While dicyclomine has been shown to be effective for colic, there are significant concerns about its safety, and the manufacturer has contraindicated its use in this population. An herbal tea containing chamomile, vervain, licorice, fennel, and balm-mint was also effective in a small RCT, but the volume necessary for treatment limits its usefulness (strength of recommendation: B, inconsistent or limited-quality patientoriented evidence). The one proven treatment is time, as this behavior tends to dissipate by 6 months of age.

CLINICAL COMMENTARY

For pure colic, only time will help
Anne Eglash, MD
Department of Family Medicine, University of Wisconsin Medical School, Madison

A broad definition for colic may capture infants who cry for a variety of reasons. I consider pure colic to be a patterned daily behavior of crying that a parent can predict will occur and stop at certain times, and the baby is fine at other times of day. For these babies, I wouldn’t expect a change in formula or maternal diet to help; they greatly improve by about age 3 months.

However, for babies who are fussy and difficult to console throughout day and night, further evaluation and dietary changes are worth trying. For breastfeeding mothers, I usually start with dairy avoidance and test the baby’s stools for microscopic blood to be sure there is no colitis related to maternal diet. Only if there is evidence of infant colitis or allergy should a more restrictive maternal diet be prescribed. For formula-fed infants, a change to a proteinhydrolysate formula is worth a try, the main risk being the cost of the formula.

 

Evidence summary

Colic has been described using the “rule of 3”: crying for at least 3 hours per day on at least 3 days per week for at least 3 weeks.1 The distinction can be subtle; a normal infant can cry more than 2 hours per day. This syndrome has its onset typically in the first few weeks of life. It spontaneously resolves by age 4 to 6 months. Prevalence depends on the definition used for colic; approximately 5% to 25% of infants meet some reasonable definition of colic.2 The cause of infantile colic is poorly understood. Although clinicians tend to focus on a likely gastrointestinal cause, neuropsychological issues, food allergy, and parenting misadventures are also potential contributing factors.

There are myriad strategies—ranging from craniosacral osteopathic manipulation to car ride simulation—offered for dealing with infantile colic. Although none of these treatments has been validated in rigorous studies, the available evidence offers tentative support for 3 strategies: (1) a trial of a hypoallergenic (protein hydrolysate) formula (for formula fed infants), (2) a low-allergen maternal diet (for breastfeeding mothers), and (3) reduced stimulation of the infant.

A systematic review analyzed controlled clinical trials lasting at least 3 days involving infants less than 6 months of age who cried excessively.3 Twenty-seven studies were included; the outcome measure was colic symptoms, typically reported as duration of crying. Two reports studying hypoallergenic (protein hydrolysate) formula in nearly 130 infants found an effect size of 0.22 (95% confidence interval [CI], 0.10–0.34) for the hypoallergenic formula. Additionally, 3 behavioral trials (involving nearly 200 infants) revealed the benefits of reduced stimulation of the colicky infant (effect size of 0.48; 95% CI, 0.23–0.74).

A more recent systematic review4 followed a similar high-quality search strategy and identified 22 articles, and reported a number needed to treat (NNT) of 6 for the 2 hypoallergenic formula studies identified in the previous review.4 Because of concern regarding the quality of the behavioral studies involving infants with colic, the authors of this second review only included 1 small (42 patients) trial of decreased stimulation, which resulted in a relative risk (RR) of 1.87 (95% CI, 1.04–3.34) and a NNT of 2. There was some inconclusive evidence to suggest benefit to dietary adjustment for breastfeeding mothers (specifically, the avoidance of cow’s milk and other potential allergens like nuts, eggs, and wheat).

 

 

 

A recent randomized controlled trial confirmed the value of this approach by showing significant improvement in distress scores of infants whose mothers followed a low-allergen diet (excluding dairy, soy, wheat, eggs, peanuts, tree nuts, and fish) for 7 days.5 This well-designed study included 107 patients (a relatively large sample in the published research about colic), and showed an absolute risk reduction of 37% (NNT=3) for those mothers following the challenge.

A small RCT (43 patients) suggested efficacy in the substitution of a whey hydrolysate formula in place of cow’s milkbased formula for infants with colic (casein hydrolysate formula has been more widely studied), but there continues to be controversy regarding the preferred protein hydrolysate formula (whey vs casein) in the treatment of colic.3

Several medications have been tested in RCTs; only dicyclomine has shown an effect in a few small RCTs.3,4 However, there have been reports of apnea and other serious, although infrequent, adverse effects. For that reason, the manufacturer has contraindicated the use of this medication in infants aged <6 months.

A small (n=68) study of an herbal tea showed reduced symptoms (RR=0.57 favoring the active tea), although the mean volume of tea consumption (32 mL/kg/d) is a nutritional concern in this age group.6 No adverse events were noted, but the small sample size limits the ability to detect any but the most common events.

Recommendations from others

The American Gastroenterological Association recommends a hypoallergenic, protein hydrolysate formula for formula fed infants or a maternal low-allergen diet as an initial strategy for infant struggling with colic symptoms if the clinician is considering a diagnosis of (cow’s milk) allergy.7

The American Academy of Family Physicians on their familydoctor.org web site makes no specific formula or diet adjustment recommendations.8 The web site does list some techniques (eg, massage or warm compress of abdomen, swing or car rides) not supported by the available evidence. The National Library of Medicine and the National Institutes of Health web site Medline Plus presents similar information.9 The American Academy of Pediatrics does not address the topic on its public web site.

References

1. Wessel MA, Cobb JC, Jackson EB, Harris GS, Jr, Detwiler AC. Paroxysmal fussing in infancy, sometimes called colic. Pediatrics 1954;14:421-435.

2. Kilgour T, Wade S. Infantile colic. Clin Evid 2005;13:362-372.

3. Lucassen PL, Assendelft WJ, Gubbels JW, van Eijk JT, van Geldrop WJ, Neven AK. Effectiveness of treatments for infantile colic: systematic review. BMJ 1998;316:1563-1569.

4. Garrison MM, Christakis DA. A systematic review of treatments for infant colic. Pediatrics 2000;106:184-190.

5. Hill DJ, Roy N, Heine RG, et al. Effect of a low-allergen maternal diet on colic among breastfed infants: a randomized, controlled trial. Pediatrics 2005;116:e709-e715.

6. Lucassen PLBJ, Assendelft WJJ, Gubbels JW, van Eijk JT, Douwes AC. Infantile colic: crying time reduction with a whey hydrolysate: a double-blind, randomized, placebo-controlled trial. Pediatrics 2000;106:1349-1354.

7. Sampson HA, Sicherer SH, Birnbaum AH. AGA technical review on the evaluation of food allergy in gastrointestinal disorders. Gastroenterology 2001;120:1026-1040.

8. Familydoctor.org [web site]. Colic: Learning how to deal with your baby’s crying. Last updated April 2005. Available at: familydoctor.org/036.xml. Accessed on June 12, 2006.

9. Colic and crying. Medline Plus, last updated August 23, 2005. Available at: www.nlm.nih.gov/medlineplus/ency/article/000978.htm#Treatment. Accessed on June 12, 2006.

References

1. Wessel MA, Cobb JC, Jackson EB, Harris GS, Jr, Detwiler AC. Paroxysmal fussing in infancy, sometimes called colic. Pediatrics 1954;14:421-435.

2. Kilgour T, Wade S. Infantile colic. Clin Evid 2005;13:362-372.

3. Lucassen PL, Assendelft WJ, Gubbels JW, van Eijk JT, van Geldrop WJ, Neven AK. Effectiveness of treatments for infantile colic: systematic review. BMJ 1998;316:1563-1569.

4. Garrison MM, Christakis DA. A systematic review of treatments for infant colic. Pediatrics 2000;106:184-190.

5. Hill DJ, Roy N, Heine RG, et al. Effect of a low-allergen maternal diet on colic among breastfed infants: a randomized, controlled trial. Pediatrics 2005;116:e709-e715.

6. Lucassen PLBJ, Assendelft WJJ, Gubbels JW, van Eijk JT, Douwes AC. Infantile colic: crying time reduction with a whey hydrolysate: a double-blind, randomized, placebo-controlled trial. Pediatrics 2000;106:1349-1354.

7. Sampson HA, Sicherer SH, Birnbaum AH. AGA technical review on the evaluation of food allergy in gastrointestinal disorders. Gastroenterology 2001;120:1026-1040.

8. Familydoctor.org [web site]. Colic: Learning how to deal with your baby’s crying. Last updated April 2005. Available at: familydoctor.org/036.xml. Accessed on June 12, 2006.

9. Colic and crying. Medline Plus, last updated August 23, 2005. Available at: www.nlm.nih.gov/medlineplus/ency/article/000978.htm#Treatment. Accessed on June 12, 2006.

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What is the best treatment for gastroesophageal reflux and vomiting in infants?

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EVIDENCE-BASED ANSWER

The literature on pediatric reflux can be divided into studies addressing clinically apparent reflux (vomiting or regurgitation) and reflux as measured by pH probe or other methods (TABLES 1 AND 2). Sodium alginate reduces vomiting and improves parents’ assessment of symptoms (strength of recommendation [SOR]: B, small randomized controlled trial [RCT]). Formula thickened with rice cereal decreases the number of postprandial emesis episodes in infants with gastroesophageal reflux disease (GERD) (SOR: B, small RCT).

There are conflicting data on the effect of carob bean gum as a formula thickener and its effect on regurgitation frequency (SOR: B, small RCTs). Metoclopramide does not affect vomiting or regurgitation, but is associated with greater weight gain in infants over 3 months with reflux (SOR: B, low-quality RCTs).

Carob bean gum used as a formula thickener decreases reflux as measured by intraluminal impedance but not as measured by pH probe (SOR: B, RCT). Omeprazole and metoclopramide each improve the reflux index as measured by esophageal pH probe (SOR: B, RCT).

Evidence is conflicting for other commonly used conservative measures (such as positional changes) or other medications for symptomatic relief of infant GERD. There is very limited evidence or expert opinion regarding breastfed infants, particularly with regard to preservation of breastfeeding during therapy.

TABLE 1
Interventions that affect vomiting or regurgitation

INTERVENTIONTRIAL DESCRIPTIONEFFECT
Carob bean gum*Unblinded crossover RCT (n=14 infants w/regurgitation). Reflux episodes measured by intraluminal impedance and visual regurgitation score.5Improved.
0.4 g/100 ccCarob bean gum: 15 regurgitations/342 hrs.
Standard formula: 68
P<.0003
RCT, thickened vs. standard formula (n=20).No improvement.
Outcome: regurgitation score, parental diary.6Thickened formula: 2.2≠ 1.92 regurgitation score. Control formula: 3.3≠ 1.16.
P=.14
Crossover RCT (n=24). Formula thickened with carob bean gum vs rice cereal.Improved.
Outcomes: symptom scores and emesis episodes.7Both groups showed improved symptom scores and decreased emesis, but carob bean gum was superior to rice cereal-thickened formula.
Sodium alginateDouble-blind multicenter RCT of alginate vs placebo added to formula or breast milk (n=88). Intention-to-treat analysis.9Improved.
225 mg/115 ccFunded by manufacturer. 25% dropout rate. Breastfed infants included, but results not reported separately.Alginate: from 8.5 vomiting/regurgitation episodes to 3 per 24 h.
orPlacebo: from 7 episodes to 5 per 24 h.
450 mg/225 ccP=.009
Rice cerealRCT of thickened vs unthickened formula (n=20). Emesis episodes per 90-min postprandial period.4Improved.
(see also Carob emesis bean gum, above)Thickened formula: 1.2 +/- 0.7 episodes per 90 minutes postprandial
Placebo: 3.9 +/- 0.9 emesis episodes
P=0.015
MetoclopramideCrossover RCT (n=30). Metoclopramide vs placebo for 7 days. Mean daily symptom count (included vomiting and regurgitation).10No improvement.
0.1 mg/kg 4 times dailyPlacebo: Symptom count for
Placebo 6.5 1.3 per day
Metoclopramide 5.6 1.2
P=.19
Subgroup analysis infants >3 mo showed greater weight gain for treated infants.
*Used in the UK (Instant Carobel); not widely available in US
†Available in UK as Gaviscon Infant.

TABLE 2
Interventions that affect pH probe/measured reflux

INTERVENTIONDESCRIPTIONEFFECT
Carob bean gum*Unblinded crossover RCT (n=14 infants w/regurgitation). Reflux episodes measured by intraluminal impedance and visual regurgitation score. Limitations: unblinded; small sample size; no breastfed infants included.5Improved.
0.4 g/100 ccCarob bean gum: 536 episodes in 342 hours. Placebo: 647 episodes. P<.02
RCT, thickened vs standard formula.No improvement.
Reflux meas. by 24-h pH probe.6Reflux index for thickened formula, 11.1 ± 6.1. Standard formula, 13.2 ± 4.7. P=.41
Rice cerealRCT of thickened vs unthickened formulaNo improvement. Thickened formula group:
(n=20). Reflux measured by scintigraphy.426.8 ± 5.8 episodes per 90 min postprandial period. Unthickened formula group: 27.9 ± 4.0. P=NS.
Infant seat at 60°RCT, positioning in infant seat vs prone.Worsened. Infant seat: 16 ± 2.4 episodes
Episodes of reflux measured by pH probe.3in 2 h. Prone position: 10 ± 2.3 episodes.
P=.002
Head of bed at 30°Crossover RCT (n=90). Prone position vs prone/head of bed elevated to 30°. Number and length of reflux episodes, measured by pH probe.8No improvement. Head-elevated 6.2 ± 0.6 episodes per 2 h. Flat prone 7.8 ± 0.8 episodes per 2 h. P=NS.
Head-elevated 17.1 ± 2.4 minutes longest episode. Flat prone 17.9 ± 2.2 minutes. P=NS.
Pacifier useRCT (n=48). Seated vs prone position, with or without pacifier; reflux episodes meas. by pH probe.3Prone: Worsened from 7.2 ± 1.1 episodes in 2 h without pacifier to 12.8 ± 2.3 w/pacifier. P=.04.
OmeprazoleRCT (n=30 irritable infants with reflux or esophagitis). Reflux index (% of time pH <4) meas. by pH probe and “cry/fuss time.”11Irritability unchanged. Improved pH:
(Infants 5–10 kg: 10 mg/d; infants >10 kg: 10 mg bid)Omeprazole: Reflux index –8.9% ± 5.6.
Placebo: Reflux Index –1.9% ± 2. P<.001.
MetoclopramideCrossover RCT (n=30). Metoclopramide vs placebo for 7 days. Reflux index measured by pH probe. Wide confidence intervals.10Improved reflux index. Metoclopramide:
(0.1 mg/kg 4 times daily)10.3% (95% CI, 2.4–22.8). Placebo: 13.4% (95% CI, 2.8–30.5). P<.001

Evidence summary

Regurgitation (“spitting up”) and gastroesophageal reflux are common in infants. In a cross-sectional survey of 948 parents of healthy infants aged 0 to 13 months, regurgitation occurred daily in half of infants from birth to 3 months old, peaked to 67% at age 4 months, and was absent in 95% by age 12 months.1 Gastroesophageal disease (GERD) is characterized by refractory symptoms or complications (pain, irritability, vomiting, failure to thrive, dysphagia, respiratory symptoms, or esophagitis) and occurs in the minority of infants with reflux.2 This distinguishes the “happy spitter,” whose parents may simply require reassurance, from infants who require treatment.

 

 

 

Unfortunately, most of the available studies do not make this distinction in their subjects. Also, available data primarily regard formula-fed infants, and are insufficient to make recommendations for breastfed infants. Esophageal pH probe monitoring is the gold standard for measuring reflux in research; however, its correlation with symptoms is questionable and it is infrequently used in clinical practice.3 Therefore, recommendations are focused primarily on treating only clinically-evident reflux (emesis and regurgitation).

Five small RCTs studied the practice of using formula thickeners (TABLES 1 AND 2). In 1 study, formula thickened with rice cereal decreased emesis episodes.4 Two studies of carob bean gum–thickened formula vs plain formula yielded conflicting results.5,6 In the study showing improvement with carob bean gum, the parents were not blinded to the treatment, which may have led to bias favoring the treatment.5 An uncontrolled, comparative trial of carob bean gum vs rice cereal suggested superiority of carob bean gum as a thickener, although both treatments yielded improvement.7 Carob bean gum is available in the UK as a powder (Instant Carobel) but is not widely available in the US.

Three trials studied the effects of other conservative therapies such as positional changes and pacifiers on reflux measured by pH probe; unfortunately, none assessed clinical outcomes such as emesis or regurgitation.3 Reflux by pH probe was worsened in a trial studying the infant seat for positioning. In the trial studying elevating the head of the bed to 30° in the prone position, reflux measured by pH probe was also unchanged; prone positioning is no longer recommended due to the risk of Sudden Infant Death Syndrome (SIDS).8 The trial of pacifier use showed improvement of reflux by pH probe when used in the seated position, but worsening in the prone position. Since pH probe does not necessarily reflect clinical symptoms, the utility of the information from these studies is limited.

Only 1 trial of drugs used to treat infant reflux measured clinical symptoms. This large manufacturer-sponsored RCT found that sodium alginate9 significantly reduced emesis episodes in treated infants. Sodium alginate is marketed in the UK as Gaviscon Infant. While this trial included breastfed infants, it did not report the numbers of breastfed infants in the 2 treatment groups or present data separately for breastfed infants. Small RCTs of metoclopramide10 and omeprazole11 show significant improvement in reflux index measured by pH probe. However, metoclopramide yielded no improvement in symptom counts, and the omeprazole study resulted in no differences in “cry-fuss time” between treatment groups.

Recommendations from others

The North American Society for Pediatric Gastroenterology and Nutrition recommends thickening agents or a trial of hypoallergenic formula for vomiting infants.2 They caution against prone positioning and favor proton pump inhibitors over H2 blockers for symptomatic relief and healing of esophagitis. They found insufficient evidence to recommend surgery over medication.

Clinical Commentary

Lack of age-appropriate RCTs make evidence-based treatment difficult
Alfreda L. Bell, MD
Kelsey-Seybold Clinic, Houston, Tex

Gastroesophageal reflux, defined as the passage of gastric contents into the esophagus, is one of the most common gastroesophageal problems in infants. GERD is a pathological process in infants manifested by poor weight gain, signs of esophagitis, persistent respiratory symptoms or complications, and changes in neurologic behavior. Gastroesophageal reflux generally resolves within the first year of life, as the lower esophageal sphincter mechanism matures. Traditionally, these infants have been managed conservatively with feeding schedule modifications, thickened feeds, changes in positions after feeding, and formula changes. Depending on the history and clinical presentation of an infant with GERD, more detailed evaluation and treatment may be necessary.

As per the North American Society for Pediatric Gastroenterology and Nutrition, if an upper gastrointestinal series has ruled out anatomic causes of gastroesophageal reflux, and nonpharmacologic interventions have failed, an acid suppressive agent is usually the first line of therapy. The lack of age-appropriate case definitions and randomized controlled trials, however, make it difficult for those practitioners who treat infants to have a evidence-based protocol for managing GERD.

References

1. Nelson SP, Chen EH,, Syniar GM, Christoffel KK. Prevalence of symptoms of gastroesophageal reflux during infancy. A pediatric practice-based survey. Pediatric Practice Research Group. Arch Pediatr Adolesc Med 1997;151:569-572.

2. Rudolph CD, Mazur LJ, Liptak GS, et al. North American Society for Pediatric Gastroenterology and Nutrition. Guidelines for evaluation and treatment of gastroesophageal reflux in infants and children: Recommendations of the North American Society for Pediatric Gastroenterology and Nutrition. J Pediatr Gastroenterol Nutr 2001;32 Suppl 2:S1-S31.

3. Carroll AE, Garrison MM, Christakis DA. A systematic review of nonpharmacological and nonsurgical therapies for gastroesophageal reflux in infants. Arch Pediatr Adolesc Med 2002;156:109-113.

4. Orenstein SR, Magill HL, Brooks P. Thickening of infant feedings for therapy of gastroesophageal reflux. J Pediatr 1987;110:181-186.

5. Wenzl TG, Schneider S, Scheele F, Silny J, Heimann G, Skopnik H. Effects of thickened feeding on gastroesophageal reflux in infants: a placebo-controlled crossover study using intraluminal impedance. Pediatrics 2003;111(4 Pt 1):e355-359.

6. Vandemplas Y, Hachimi-Idrissi S, Casteels A, Mahler T, Loeb. A clinical trial with an “anti-regurgitation” formula. Eur J Pediatr 1994;153:419-423.

7. Borelli O, Salvia G, Campanozzi A. Use of a new thickened formula for treatment of symptomatic gastroesophageal reflux in infants. Ital J Gastroenterol Hepatol 1997;29:237-242.

8. Orenstein SR. Prone positioning in infant gastroesophageal reflux: Is elevation of the head worth the trouble? J Pediatr 1990;117:184-187.

9. Miller S. Comparison of the efficacy and safety of a new aluminum-free paediatric alginate preparation and placebo in infants with recurrent gastro-oesophageal reflux. Curr Med Res Opin 1999;15:160-168.

10. olia V, Calhoun J, Kuhns L, Kauffman RE. Randomized, prospective double-blind trial of metoclopramide and placebo for gastroesophageal reflux in infants. J Pediatr 1989;115:141-145.

11. Moore DJ, Tao BS, Lines DR, Hirte C, Heddle ML, Davidson GP. Double-blind placebo-controlled trial of omeprazole in irritable infants with gastroesophageal reflux. J Pediatr 2003;143:219-223.

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EVIDENCE-BASED ANSWER

The literature on pediatric reflux can be divided into studies addressing clinically apparent reflux (vomiting or regurgitation) and reflux as measured by pH probe or other methods (TABLES 1 AND 2). Sodium alginate reduces vomiting and improves parents’ assessment of symptoms (strength of recommendation [SOR]: B, small randomized controlled trial [RCT]). Formula thickened with rice cereal decreases the number of postprandial emesis episodes in infants with gastroesophageal reflux disease (GERD) (SOR: B, small RCT).

There are conflicting data on the effect of carob bean gum as a formula thickener and its effect on regurgitation frequency (SOR: B, small RCTs). Metoclopramide does not affect vomiting or regurgitation, but is associated with greater weight gain in infants over 3 months with reflux (SOR: B, low-quality RCTs).

Carob bean gum used as a formula thickener decreases reflux as measured by intraluminal impedance but not as measured by pH probe (SOR: B, RCT). Omeprazole and metoclopramide each improve the reflux index as measured by esophageal pH probe (SOR: B, RCT).

Evidence is conflicting for other commonly used conservative measures (such as positional changes) or other medications for symptomatic relief of infant GERD. There is very limited evidence or expert opinion regarding breastfed infants, particularly with regard to preservation of breastfeeding during therapy.

TABLE 1
Interventions that affect vomiting or regurgitation

INTERVENTIONTRIAL DESCRIPTIONEFFECT
Carob bean gum*Unblinded crossover RCT (n=14 infants w/regurgitation). Reflux episodes measured by intraluminal impedance and visual regurgitation score.5Improved.
0.4 g/100 ccCarob bean gum: 15 regurgitations/342 hrs.
Standard formula: 68
P<.0003
RCT, thickened vs. standard formula (n=20).No improvement.
Outcome: regurgitation score, parental diary.6Thickened formula: 2.2≠ 1.92 regurgitation score. Control formula: 3.3≠ 1.16.
P=.14
Crossover RCT (n=24). Formula thickened with carob bean gum vs rice cereal.Improved.
Outcomes: symptom scores and emesis episodes.7Both groups showed improved symptom scores and decreased emesis, but carob bean gum was superior to rice cereal-thickened formula.
Sodium alginateDouble-blind multicenter RCT of alginate vs placebo added to formula or breast milk (n=88). Intention-to-treat analysis.9Improved.
225 mg/115 ccFunded by manufacturer. 25% dropout rate. Breastfed infants included, but results not reported separately.Alginate: from 8.5 vomiting/regurgitation episodes to 3 per 24 h.
orPlacebo: from 7 episodes to 5 per 24 h.
450 mg/225 ccP=.009
Rice cerealRCT of thickened vs unthickened formula (n=20). Emesis episodes per 90-min postprandial period.4Improved.
(see also Carob emesis bean gum, above)Thickened formula: 1.2 +/- 0.7 episodes per 90 minutes postprandial
Placebo: 3.9 +/- 0.9 emesis episodes
P=0.015
MetoclopramideCrossover RCT (n=30). Metoclopramide vs placebo for 7 days. Mean daily symptom count (included vomiting and regurgitation).10No improvement.
0.1 mg/kg 4 times dailyPlacebo: Symptom count for
Placebo 6.5 1.3 per day
Metoclopramide 5.6 1.2
P=.19
Subgroup analysis infants >3 mo showed greater weight gain for treated infants.
*Used in the UK (Instant Carobel); not widely available in US
†Available in UK as Gaviscon Infant.

TABLE 2
Interventions that affect pH probe/measured reflux

INTERVENTIONDESCRIPTIONEFFECT
Carob bean gum*Unblinded crossover RCT (n=14 infants w/regurgitation). Reflux episodes measured by intraluminal impedance and visual regurgitation score. Limitations: unblinded; small sample size; no breastfed infants included.5Improved.
0.4 g/100 ccCarob bean gum: 536 episodes in 342 hours. Placebo: 647 episodes. P<.02
RCT, thickened vs standard formula.No improvement.
Reflux meas. by 24-h pH probe.6Reflux index for thickened formula, 11.1 ± 6.1. Standard formula, 13.2 ± 4.7. P=.41
Rice cerealRCT of thickened vs unthickened formulaNo improvement. Thickened formula group:
(n=20). Reflux measured by scintigraphy.426.8 ± 5.8 episodes per 90 min postprandial period. Unthickened formula group: 27.9 ± 4.0. P=NS.
Infant seat at 60°RCT, positioning in infant seat vs prone.Worsened. Infant seat: 16 ± 2.4 episodes
Episodes of reflux measured by pH probe.3in 2 h. Prone position: 10 ± 2.3 episodes.
P=.002
Head of bed at 30°Crossover RCT (n=90). Prone position vs prone/head of bed elevated to 30°. Number and length of reflux episodes, measured by pH probe.8No improvement. Head-elevated 6.2 ± 0.6 episodes per 2 h. Flat prone 7.8 ± 0.8 episodes per 2 h. P=NS.
Head-elevated 17.1 ± 2.4 minutes longest episode. Flat prone 17.9 ± 2.2 minutes. P=NS.
Pacifier useRCT (n=48). Seated vs prone position, with or without pacifier; reflux episodes meas. by pH probe.3Prone: Worsened from 7.2 ± 1.1 episodes in 2 h without pacifier to 12.8 ± 2.3 w/pacifier. P=.04.
OmeprazoleRCT (n=30 irritable infants with reflux or esophagitis). Reflux index (% of time pH <4) meas. by pH probe and “cry/fuss time.”11Irritability unchanged. Improved pH:
(Infants 5–10 kg: 10 mg/d; infants >10 kg: 10 mg bid)Omeprazole: Reflux index –8.9% ± 5.6.
Placebo: Reflux Index –1.9% ± 2. P<.001.
MetoclopramideCrossover RCT (n=30). Metoclopramide vs placebo for 7 days. Reflux index measured by pH probe. Wide confidence intervals.10Improved reflux index. Metoclopramide:
(0.1 mg/kg 4 times daily)10.3% (95% CI, 2.4–22.8). Placebo: 13.4% (95% CI, 2.8–30.5). P<.001

Evidence summary

Regurgitation (“spitting up”) and gastroesophageal reflux are common in infants. In a cross-sectional survey of 948 parents of healthy infants aged 0 to 13 months, regurgitation occurred daily in half of infants from birth to 3 months old, peaked to 67% at age 4 months, and was absent in 95% by age 12 months.1 Gastroesophageal disease (GERD) is characterized by refractory symptoms or complications (pain, irritability, vomiting, failure to thrive, dysphagia, respiratory symptoms, or esophagitis) and occurs in the minority of infants with reflux.2 This distinguishes the “happy spitter,” whose parents may simply require reassurance, from infants who require treatment.

 

 

 

Unfortunately, most of the available studies do not make this distinction in their subjects. Also, available data primarily regard formula-fed infants, and are insufficient to make recommendations for breastfed infants. Esophageal pH probe monitoring is the gold standard for measuring reflux in research; however, its correlation with symptoms is questionable and it is infrequently used in clinical practice.3 Therefore, recommendations are focused primarily on treating only clinically-evident reflux (emesis and regurgitation).

Five small RCTs studied the practice of using formula thickeners (TABLES 1 AND 2). In 1 study, formula thickened with rice cereal decreased emesis episodes.4 Two studies of carob bean gum–thickened formula vs plain formula yielded conflicting results.5,6 In the study showing improvement with carob bean gum, the parents were not blinded to the treatment, which may have led to bias favoring the treatment.5 An uncontrolled, comparative trial of carob bean gum vs rice cereal suggested superiority of carob bean gum as a thickener, although both treatments yielded improvement.7 Carob bean gum is available in the UK as a powder (Instant Carobel) but is not widely available in the US.

Three trials studied the effects of other conservative therapies such as positional changes and pacifiers on reflux measured by pH probe; unfortunately, none assessed clinical outcomes such as emesis or regurgitation.3 Reflux by pH probe was worsened in a trial studying the infant seat for positioning. In the trial studying elevating the head of the bed to 30° in the prone position, reflux measured by pH probe was also unchanged; prone positioning is no longer recommended due to the risk of Sudden Infant Death Syndrome (SIDS).8 The trial of pacifier use showed improvement of reflux by pH probe when used in the seated position, but worsening in the prone position. Since pH probe does not necessarily reflect clinical symptoms, the utility of the information from these studies is limited.

Only 1 trial of drugs used to treat infant reflux measured clinical symptoms. This large manufacturer-sponsored RCT found that sodium alginate9 significantly reduced emesis episodes in treated infants. Sodium alginate is marketed in the UK as Gaviscon Infant. While this trial included breastfed infants, it did not report the numbers of breastfed infants in the 2 treatment groups or present data separately for breastfed infants. Small RCTs of metoclopramide10 and omeprazole11 show significant improvement in reflux index measured by pH probe. However, metoclopramide yielded no improvement in symptom counts, and the omeprazole study resulted in no differences in “cry-fuss time” between treatment groups.

Recommendations from others

The North American Society for Pediatric Gastroenterology and Nutrition recommends thickening agents or a trial of hypoallergenic formula for vomiting infants.2 They caution against prone positioning and favor proton pump inhibitors over H2 blockers for symptomatic relief and healing of esophagitis. They found insufficient evidence to recommend surgery over medication.

Clinical Commentary

Lack of age-appropriate RCTs make evidence-based treatment difficult
Alfreda L. Bell, MD
Kelsey-Seybold Clinic, Houston, Tex

Gastroesophageal reflux, defined as the passage of gastric contents into the esophagus, is one of the most common gastroesophageal problems in infants. GERD is a pathological process in infants manifested by poor weight gain, signs of esophagitis, persistent respiratory symptoms or complications, and changes in neurologic behavior. Gastroesophageal reflux generally resolves within the first year of life, as the lower esophageal sphincter mechanism matures. Traditionally, these infants have been managed conservatively with feeding schedule modifications, thickened feeds, changes in positions after feeding, and formula changes. Depending on the history and clinical presentation of an infant with GERD, more detailed evaluation and treatment may be necessary.

As per the North American Society for Pediatric Gastroenterology and Nutrition, if an upper gastrointestinal series has ruled out anatomic causes of gastroesophageal reflux, and nonpharmacologic interventions have failed, an acid suppressive agent is usually the first line of therapy. The lack of age-appropriate case definitions and randomized controlled trials, however, make it difficult for those practitioners who treat infants to have a evidence-based protocol for managing GERD.

EVIDENCE-BASED ANSWER

The literature on pediatric reflux can be divided into studies addressing clinically apparent reflux (vomiting or regurgitation) and reflux as measured by pH probe or other methods (TABLES 1 AND 2). Sodium alginate reduces vomiting and improves parents’ assessment of symptoms (strength of recommendation [SOR]: B, small randomized controlled trial [RCT]). Formula thickened with rice cereal decreases the number of postprandial emesis episodes in infants with gastroesophageal reflux disease (GERD) (SOR: B, small RCT).

There are conflicting data on the effect of carob bean gum as a formula thickener and its effect on regurgitation frequency (SOR: B, small RCTs). Metoclopramide does not affect vomiting or regurgitation, but is associated with greater weight gain in infants over 3 months with reflux (SOR: B, low-quality RCTs).

Carob bean gum used as a formula thickener decreases reflux as measured by intraluminal impedance but not as measured by pH probe (SOR: B, RCT). Omeprazole and metoclopramide each improve the reflux index as measured by esophageal pH probe (SOR: B, RCT).

Evidence is conflicting for other commonly used conservative measures (such as positional changes) or other medications for symptomatic relief of infant GERD. There is very limited evidence or expert opinion regarding breastfed infants, particularly with regard to preservation of breastfeeding during therapy.

TABLE 1
Interventions that affect vomiting or regurgitation

INTERVENTIONTRIAL DESCRIPTIONEFFECT
Carob bean gum*Unblinded crossover RCT (n=14 infants w/regurgitation). Reflux episodes measured by intraluminal impedance and visual regurgitation score.5Improved.
0.4 g/100 ccCarob bean gum: 15 regurgitations/342 hrs.
Standard formula: 68
P<.0003
RCT, thickened vs. standard formula (n=20).No improvement.
Outcome: regurgitation score, parental diary.6Thickened formula: 2.2≠ 1.92 regurgitation score. Control formula: 3.3≠ 1.16.
P=.14
Crossover RCT (n=24). Formula thickened with carob bean gum vs rice cereal.Improved.
Outcomes: symptom scores and emesis episodes.7Both groups showed improved symptom scores and decreased emesis, but carob bean gum was superior to rice cereal-thickened formula.
Sodium alginateDouble-blind multicenter RCT of alginate vs placebo added to formula or breast milk (n=88). Intention-to-treat analysis.9Improved.
225 mg/115 ccFunded by manufacturer. 25% dropout rate. Breastfed infants included, but results not reported separately.Alginate: from 8.5 vomiting/regurgitation episodes to 3 per 24 h.
orPlacebo: from 7 episodes to 5 per 24 h.
450 mg/225 ccP=.009
Rice cerealRCT of thickened vs unthickened formula (n=20). Emesis episodes per 90-min postprandial period.4Improved.
(see also Carob emesis bean gum, above)Thickened formula: 1.2 +/- 0.7 episodes per 90 minutes postprandial
Placebo: 3.9 +/- 0.9 emesis episodes
P=0.015
MetoclopramideCrossover RCT (n=30). Metoclopramide vs placebo for 7 days. Mean daily symptom count (included vomiting and regurgitation).10No improvement.
0.1 mg/kg 4 times dailyPlacebo: Symptom count for
Placebo 6.5 1.3 per day
Metoclopramide 5.6 1.2
P=.19
Subgroup analysis infants >3 mo showed greater weight gain for treated infants.
*Used in the UK (Instant Carobel); not widely available in US
†Available in UK as Gaviscon Infant.

TABLE 2
Interventions that affect pH probe/measured reflux

INTERVENTIONDESCRIPTIONEFFECT
Carob bean gum*Unblinded crossover RCT (n=14 infants w/regurgitation). Reflux episodes measured by intraluminal impedance and visual regurgitation score. Limitations: unblinded; small sample size; no breastfed infants included.5Improved.
0.4 g/100 ccCarob bean gum: 536 episodes in 342 hours. Placebo: 647 episodes. P<.02
RCT, thickened vs standard formula.No improvement.
Reflux meas. by 24-h pH probe.6Reflux index for thickened formula, 11.1 ± 6.1. Standard formula, 13.2 ± 4.7. P=.41
Rice cerealRCT of thickened vs unthickened formulaNo improvement. Thickened formula group:
(n=20). Reflux measured by scintigraphy.426.8 ± 5.8 episodes per 90 min postprandial period. Unthickened formula group: 27.9 ± 4.0. P=NS.
Infant seat at 60°RCT, positioning in infant seat vs prone.Worsened. Infant seat: 16 ± 2.4 episodes
Episodes of reflux measured by pH probe.3in 2 h. Prone position: 10 ± 2.3 episodes.
P=.002
Head of bed at 30°Crossover RCT (n=90). Prone position vs prone/head of bed elevated to 30°. Number and length of reflux episodes, measured by pH probe.8No improvement. Head-elevated 6.2 ± 0.6 episodes per 2 h. Flat prone 7.8 ± 0.8 episodes per 2 h. P=NS.
Head-elevated 17.1 ± 2.4 minutes longest episode. Flat prone 17.9 ± 2.2 minutes. P=NS.
Pacifier useRCT (n=48). Seated vs prone position, with or without pacifier; reflux episodes meas. by pH probe.3Prone: Worsened from 7.2 ± 1.1 episodes in 2 h without pacifier to 12.8 ± 2.3 w/pacifier. P=.04.
OmeprazoleRCT (n=30 irritable infants with reflux or esophagitis). Reflux index (% of time pH <4) meas. by pH probe and “cry/fuss time.”11Irritability unchanged. Improved pH:
(Infants 5–10 kg: 10 mg/d; infants >10 kg: 10 mg bid)Omeprazole: Reflux index –8.9% ± 5.6.
Placebo: Reflux Index –1.9% ± 2. P<.001.
MetoclopramideCrossover RCT (n=30). Metoclopramide vs placebo for 7 days. Reflux index measured by pH probe. Wide confidence intervals.10Improved reflux index. Metoclopramide:
(0.1 mg/kg 4 times daily)10.3% (95% CI, 2.4–22.8). Placebo: 13.4% (95% CI, 2.8–30.5). P<.001

Evidence summary

Regurgitation (“spitting up”) and gastroesophageal reflux are common in infants. In a cross-sectional survey of 948 parents of healthy infants aged 0 to 13 months, regurgitation occurred daily in half of infants from birth to 3 months old, peaked to 67% at age 4 months, and was absent in 95% by age 12 months.1 Gastroesophageal disease (GERD) is characterized by refractory symptoms or complications (pain, irritability, vomiting, failure to thrive, dysphagia, respiratory symptoms, or esophagitis) and occurs in the minority of infants with reflux.2 This distinguishes the “happy spitter,” whose parents may simply require reassurance, from infants who require treatment.

 

 

 

Unfortunately, most of the available studies do not make this distinction in their subjects. Also, available data primarily regard formula-fed infants, and are insufficient to make recommendations for breastfed infants. Esophageal pH probe monitoring is the gold standard for measuring reflux in research; however, its correlation with symptoms is questionable and it is infrequently used in clinical practice.3 Therefore, recommendations are focused primarily on treating only clinically-evident reflux (emesis and regurgitation).

Five small RCTs studied the practice of using formula thickeners (TABLES 1 AND 2). In 1 study, formula thickened with rice cereal decreased emesis episodes.4 Two studies of carob bean gum–thickened formula vs plain formula yielded conflicting results.5,6 In the study showing improvement with carob bean gum, the parents were not blinded to the treatment, which may have led to bias favoring the treatment.5 An uncontrolled, comparative trial of carob bean gum vs rice cereal suggested superiority of carob bean gum as a thickener, although both treatments yielded improvement.7 Carob bean gum is available in the UK as a powder (Instant Carobel) but is not widely available in the US.

Three trials studied the effects of other conservative therapies such as positional changes and pacifiers on reflux measured by pH probe; unfortunately, none assessed clinical outcomes such as emesis or regurgitation.3 Reflux by pH probe was worsened in a trial studying the infant seat for positioning. In the trial studying elevating the head of the bed to 30° in the prone position, reflux measured by pH probe was also unchanged; prone positioning is no longer recommended due to the risk of Sudden Infant Death Syndrome (SIDS).8 The trial of pacifier use showed improvement of reflux by pH probe when used in the seated position, but worsening in the prone position. Since pH probe does not necessarily reflect clinical symptoms, the utility of the information from these studies is limited.

Only 1 trial of drugs used to treat infant reflux measured clinical symptoms. This large manufacturer-sponsored RCT found that sodium alginate9 significantly reduced emesis episodes in treated infants. Sodium alginate is marketed in the UK as Gaviscon Infant. While this trial included breastfed infants, it did not report the numbers of breastfed infants in the 2 treatment groups or present data separately for breastfed infants. Small RCTs of metoclopramide10 and omeprazole11 show significant improvement in reflux index measured by pH probe. However, metoclopramide yielded no improvement in symptom counts, and the omeprazole study resulted in no differences in “cry-fuss time” between treatment groups.

Recommendations from others

The North American Society for Pediatric Gastroenterology and Nutrition recommends thickening agents or a trial of hypoallergenic formula for vomiting infants.2 They caution against prone positioning and favor proton pump inhibitors over H2 blockers for symptomatic relief and healing of esophagitis. They found insufficient evidence to recommend surgery over medication.

Clinical Commentary

Lack of age-appropriate RCTs make evidence-based treatment difficult
Alfreda L. Bell, MD
Kelsey-Seybold Clinic, Houston, Tex

Gastroesophageal reflux, defined as the passage of gastric contents into the esophagus, is one of the most common gastroesophageal problems in infants. GERD is a pathological process in infants manifested by poor weight gain, signs of esophagitis, persistent respiratory symptoms or complications, and changes in neurologic behavior. Gastroesophageal reflux generally resolves within the first year of life, as the lower esophageal sphincter mechanism matures. Traditionally, these infants have been managed conservatively with feeding schedule modifications, thickened feeds, changes in positions after feeding, and formula changes. Depending on the history and clinical presentation of an infant with GERD, more detailed evaluation and treatment may be necessary.

As per the North American Society for Pediatric Gastroenterology and Nutrition, if an upper gastrointestinal series has ruled out anatomic causes of gastroesophageal reflux, and nonpharmacologic interventions have failed, an acid suppressive agent is usually the first line of therapy. The lack of age-appropriate case definitions and randomized controlled trials, however, make it difficult for those practitioners who treat infants to have a evidence-based protocol for managing GERD.

References

1. Nelson SP, Chen EH,, Syniar GM, Christoffel KK. Prevalence of symptoms of gastroesophageal reflux during infancy. A pediatric practice-based survey. Pediatric Practice Research Group. Arch Pediatr Adolesc Med 1997;151:569-572.

2. Rudolph CD, Mazur LJ, Liptak GS, et al. North American Society for Pediatric Gastroenterology and Nutrition. Guidelines for evaluation and treatment of gastroesophageal reflux in infants and children: Recommendations of the North American Society for Pediatric Gastroenterology and Nutrition. J Pediatr Gastroenterol Nutr 2001;32 Suppl 2:S1-S31.

3. Carroll AE, Garrison MM, Christakis DA. A systematic review of nonpharmacological and nonsurgical therapies for gastroesophageal reflux in infants. Arch Pediatr Adolesc Med 2002;156:109-113.

4. Orenstein SR, Magill HL, Brooks P. Thickening of infant feedings for therapy of gastroesophageal reflux. J Pediatr 1987;110:181-186.

5. Wenzl TG, Schneider S, Scheele F, Silny J, Heimann G, Skopnik H. Effects of thickened feeding on gastroesophageal reflux in infants: a placebo-controlled crossover study using intraluminal impedance. Pediatrics 2003;111(4 Pt 1):e355-359.

6. Vandemplas Y, Hachimi-Idrissi S, Casteels A, Mahler T, Loeb. A clinical trial with an “anti-regurgitation” formula. Eur J Pediatr 1994;153:419-423.

7. Borelli O, Salvia G, Campanozzi A. Use of a new thickened formula for treatment of symptomatic gastroesophageal reflux in infants. Ital J Gastroenterol Hepatol 1997;29:237-242.

8. Orenstein SR. Prone positioning in infant gastroesophageal reflux: Is elevation of the head worth the trouble? J Pediatr 1990;117:184-187.

9. Miller S. Comparison of the efficacy and safety of a new aluminum-free paediatric alginate preparation and placebo in infants with recurrent gastro-oesophageal reflux. Curr Med Res Opin 1999;15:160-168.

10. olia V, Calhoun J, Kuhns L, Kauffman RE. Randomized, prospective double-blind trial of metoclopramide and placebo for gastroesophageal reflux in infants. J Pediatr 1989;115:141-145.

11. Moore DJ, Tao BS, Lines DR, Hirte C, Heddle ML, Davidson GP. Double-blind placebo-controlled trial of omeprazole in irritable infants with gastroesophageal reflux. J Pediatr 2003;143:219-223.

References

1. Nelson SP, Chen EH,, Syniar GM, Christoffel KK. Prevalence of symptoms of gastroesophageal reflux during infancy. A pediatric practice-based survey. Pediatric Practice Research Group. Arch Pediatr Adolesc Med 1997;151:569-572.

2. Rudolph CD, Mazur LJ, Liptak GS, et al. North American Society for Pediatric Gastroenterology and Nutrition. Guidelines for evaluation and treatment of gastroesophageal reflux in infants and children: Recommendations of the North American Society for Pediatric Gastroenterology and Nutrition. J Pediatr Gastroenterol Nutr 2001;32 Suppl 2:S1-S31.

3. Carroll AE, Garrison MM, Christakis DA. A systematic review of nonpharmacological and nonsurgical therapies for gastroesophageal reflux in infants. Arch Pediatr Adolesc Med 2002;156:109-113.

4. Orenstein SR, Magill HL, Brooks P. Thickening of infant feedings for therapy of gastroesophageal reflux. J Pediatr 1987;110:181-186.

5. Wenzl TG, Schneider S, Scheele F, Silny J, Heimann G, Skopnik H. Effects of thickened feeding on gastroesophageal reflux in infants: a placebo-controlled crossover study using intraluminal impedance. Pediatrics 2003;111(4 Pt 1):e355-359.

6. Vandemplas Y, Hachimi-Idrissi S, Casteels A, Mahler T, Loeb. A clinical trial with an “anti-regurgitation” formula. Eur J Pediatr 1994;153:419-423.

7. Borelli O, Salvia G, Campanozzi A. Use of a new thickened formula for treatment of symptomatic gastroesophageal reflux in infants. Ital J Gastroenterol Hepatol 1997;29:237-242.

8. Orenstein SR. Prone positioning in infant gastroesophageal reflux: Is elevation of the head worth the trouble? J Pediatr 1990;117:184-187.

9. Miller S. Comparison of the efficacy and safety of a new aluminum-free paediatric alginate preparation and placebo in infants with recurrent gastro-oesophageal reflux. Curr Med Res Opin 1999;15:160-168.

10. olia V, Calhoun J, Kuhns L, Kauffman RE. Randomized, prospective double-blind trial of metoclopramide and placebo for gastroesophageal reflux in infants. J Pediatr 1989;115:141-145.

11. Moore DJ, Tao BS, Lines DR, Hirte C, Heddle ML, Davidson GP. Double-blind placebo-controlled trial of omeprazole in irritable infants with gastroesophageal reflux. J Pediatr 2003;143:219-223.

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The Journal of Family Practice - 54(4)
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The Journal of Family Practice - 54(4)
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