Abstract
Background
Food allergy is an important public health problem because it affects children and adults, can be severe and even life-threatening, and may be increasing in prevalence. Beginning in 2008, the National Institute of Allergy and Infectious Diseases, working with other organizations and advocacy groups, led the development of the first clinical guidelines for the diagnosis and management of food allergy. A recent landmark clinical trial and other emerging data suggest that peanut allergy can be prevented through introduction of peanut-containing foods beginning in infancy.
Objectives
Prompted by these findings, along with 25 professional organizations, federal agencies, and patient advocacy groups, the National Institute of Allergy and Infectious Diseases facilitated development of addendum guidelines to specifically address the prevention of peanut allergy.
Results
The addendum provides 3 separate guidelines for infants at various risk levels for the development of peanut allergy and is intended for use by a wide variety of health care providers. Topics addressed include the definition of risk categories, appropriate use of testing (specific IgE measurement, skin prick tests, and oral food challenges), and the timing and approaches for introduction of peanut-containing foods in the health care provider’s office or at home. The addendum guidelines provide the background, rationale, and strength of evidence for each recommendation.
Conclusions
Guidelines have been developed for early introduction of peanut-containing foods into the diets of infants at various risk levels for peanut allergy.
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Introduction
Peanut allergy is a growing public health problem. In 1999, peanut allergy was estimated to affect 0.4% of children and 0.7% of adults in the United States [1], and by 2010, peanut allergy prevalence had increased to approximately 2% among children in a national survey [2], with similar results reported in a regional cohort. [3] Peanut allergy is the leading cause of death related to food-induced anaphylaxis in the United States [4, 5], and although overall mortality is low, the fear of life-threatening anaphylactic reactions contributes significantly to the medical and psychosocial burden of disease. In the majority of patients, peanut allergy begins early in life and persists as a lifelong problem. Therefore, cost-effective measures to prevent peanut allergy would have a high effect in terms of improving public health, reducing personal suffering, and decreasing health care use and costs.
The “Guidelines for the diagnosis and management of food allergy in the United States” [6] were published in December 2010 by an Expert Panel and a Coordinating Committee convened by the National Institute of Allergy and Infectious Diseases (NIAID). These guidelines did not offer strategies for the prevention of food allergy and particularly peanut allergy because of a lack of definitive studies at the time. The guidelines indicated that “insufficient evidence exists for delaying introduction of solid foods, including potentially allergenic foods, beyond 4 to 6 months of age, even in infants at risk of developing allergic disease.” This statement differed from previous clinical practice guidelines in the United Kingdom [7] and United States [8], which recommended the exclusion of allergenic foods from the diets of infants at high risk for allergy and is consistent with more recent recommendations regarding primary allergy prevention [9–12].
In February 2015, the New England Journal of Medicine published the results of the Learning Early about Peanut Allergy (LEAP) trial [13]. This trial was based on a prior observation [14] that the prevalence of peanut allergy was 10-fold higher among Jewish children in the United Kingdom compared with Israeli children of similar ancestry. In Israel, peanut-containing foods are usually introduced in the diet when infants are approximately 7 months of age and consumed in substantial amounts, whereas in the United Kingdom children do not typically consume any peanut-containing foods during their first year of life. The LEAP trial randomized 640 children between 4 and 11 months of age with severe eczema, egg allergy, or both to consume or avoid peanut-containing foods until 60 months of age, at which time a peanut oral food challenge (OFC) was conducted to determine the prevalence of peanut allergy. LEAP trial participants were stratified at study entry into 2 separate study cohorts on the basis of pre-existing sensitization to peanut, as determined by means of skin prick testing: one cohort consisted of infants with no measureable skin test wheal to peanut (negative skin test response) and the other consisted of those with measurable wheal responses (1–4 mm in diameter). Infants with a 5 mm wheal diameter or greater were not randomized because the majority of infants at this level of sensitization were presumed to be allergic to peanut. Among the 530 participants in the intention-to-treat population with negative baseline skin test response to peanut, the prevalence of peanut allergy at 60 months of age was 13.7% in the peanut avoidance group and 1.9% in the peanut consumption group (P < .001; an 86.1% relative reduction in the prevalence of peanut allergy). Among the 98 participants with a measurable peanut skin test response at entry, the prevalence of peanut allergy was 35.3% in the avoidance group and 10.6% in the consumption group (P = .004; a 70% relative reduction in the prevalence of peanut allergy).
The LEAP trial was the first randomized trial to study early allergen introduction as a preventive strategy. Because of the size of the observed effect and the large number of study participants, its outcome received wide publicity in both the medical community and the press. This raised the need to operationalize the LEAP findings by developing clinical recommendations focusing on peanut allergy prevention. To achieve this goal and its wide implementation, the NIAID invited the members of the 2010 Guidelines Coordinating Committee and other stakeholder organizations to develop this addendum on peanut allergy prevention to the 2010 “Guidelines for the diagnosis and management of food allergy in the United States.” Twenty-six stakeholder organizations participated in this 2015–2016 Coordinating Committee. Of note, unrelated to this effort, a consensus statement on behalf of 9 international professional societies regarding the implications and implementation of the LEAP trial findings was published as well [15].
Additional evidence on early introduction of allergenic foods comes from the LEAP-On study [16], which demonstrated the durability of oral tolerance to peanut achieved in the LEAP trial and the Enquiring About Tolerance study [17], which assessed the potential benefits of early introduction of 6 allergenic foods in a non–high-risk cohort.
Development of the 2017 addendum to the 2010 “Guidelines for the diagnosis and management of food allergy”
The process to develop the 2017 addendum closely followed that used in the 2010 guidelines [6].
Coordinating Committee
The NIAID established a Coordinating Committee (CC), the members of which are listed in Appendix A, to oversee the development of the addendum; review drafts of the addendum for accuracy, practicality, clarity, and broad utility of the recommendations in clinical practice; review and approve the final addendum; and disseminate the addendum. The CC members represented 26 professional organizations, advocacy groups, and federal agencies.
Expert Panel
The CC convened an Expert Panel (EP) in June 2015 that was chaired by Joshua Boyce, MD. The 26 panel members, listed in Appendix B, were specialists from a variety of relevant clinical, scientific, and public health areas. Panel members were nominated by the CC organizations, and the composition of the panel received unanimous approval by the CC member organizations.
The charge to the EP was to use the literature review prepared by the NIAID (see the next section) in conjunction with consensus expert opinion and EP-identified supplementary documents to (1) develop evidence-based recommendations for the early introduction of dietary peanut to prevent peanut allergy; (2) agree on principles for grading the evidence; (3) achieve consensus while allowing ample opportunity for consideration of divergent opinions; (4) determine whether the recommendations could extend beyond peanut to other food allergens; and (5) keep patient and societal interests at the forefront. The new recommendations are intended to supplement and modify guidelines 37 to 40 in Section 5.3.4 of the 2010 guidelines: “Prevention of food allergy.”
Literature review
NIAID staff conducted a literature search of PubMed limited to the years 2010 (January) to 2016 (June). Using the following specific search terms ([food allergy or milk allergy or egg allergy or peanut allergy] OR [eczema or atopic dermatitis] AND prevention), PubMed returned more than 1500 articles. NIAID staff reviewed 1506 abstracts and assessed each for relevance to the topic of food allergy prevention with an emphasis on peanut allergy. Sixty-four publications (original research articles, editorials/letters, and systematic reviews) were deemed relevant and placed into 2 tiers: tier 1 contained 18 items considered highly relevant to the early introduction of peanut or other allergenic foods (see Appendix C), and tier 2 contained 46 items on related topics, such as food allergy or eczema prevention.
Assessing the quality of the body of evidence
For each of the 18 tier 1 references, the EP assessed quality by using the Grading of Recommendations Assessment, Development and Evaluation (GRADE) approach [18]. GRADE provides a comprehensive and transparent methodology to develop recommendations for the diagnosis, treatment, and management of patients. In assessing the body of evidence of a group of relevant articles or of a single article, GRADE considers study design and other factors, such as the precision, consistency, and directness of the data. By using this approach, GRADE then provides a categorical assessment of the contribution of individual publications and the overall quality and strength of the body of evidence.
Each publication was assigned a grade according to the following criteria [19, 20]:
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High: Further research is very unlikely to have an effect on the quality of the body of evidence, and therefore the confidence in the recommendation is high and unlikely to change.
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Moderate: Further research is likely to have an effect on the quality of the body of evidence and may change the recommendation.
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Low: Further research is very likely to have an important effect on the body of evidence and is likely to change the recommendation.
A GRADE designation of “low” for the quality of evidence does not imply that an article is not factually correct or lacks scientific merit. For example, a well-designed and executed single-site study of a treatment in a small cohort of highly selected subjects may still yield an overall GRADE rating of “low.” This is because such a study is characterized as providing “sparse” data, and the patient population may not be representative of the at-risk population. Each of these factors reduces the level of evidence from “high,” which is the initial designation for evidence from randomized controlled trials. It is worth emphasizing that these 2 limitations are not of the study per se but of the body of evidence.
Preparation of the draft addendum
The draft version of the addendum, prepared by the NIAID, contained 3 new guidelines and was reviewed, modified, and endorsed by the EP members. The EP-approved document was forwarded to the CC members for review.
Public comment period, addendum revision, and final approval
Concurrent with CC member review, the draft addendum was posted to the NIAID Web site in March 2016 for a period of 45 days to allow for public review and comment. One hundred four comments were received. All comments were reviewed by the EP and the CC, and some contributed to the final revision of the addendum. The final addendum was reviewed and approved by the EP and the CC.
Dissemination of the addendum guidelines
The final addendum is published herein and available through the Internet.
Defining the strength of each clinical guideline
The EP has used the verb “recommends” or “suggests” for each clinical recommendation.
These words convey the strength of the recommendation, defined as follows:
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Recommend is used when the EP strongly recommended for or against a particular course of action.
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Suggest is used when the EP weakly recommended for or against a particular course of action.
Addendum guidelines
Table 1 provides a summary of the 3 addendum guidelines to be used as a quick reference.
The EP came to consensus on the following 3 definitions used throughout the addendum guidelines.
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Severe eczema is defined as persistent or frequently recurring eczema with typical morphology and distribution assessed as severe by a health care provider and requiring frequent need for prescription-strength topical corticosteroids, calcineurin inhibitors, or other anti-inflammatory agents despite appropriate use of emollients.
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Egg allergy is defined as a history of an allergic reaction to egg and a skin prick test (SPT) wheal diameter of 3 mm or greater with egg white extract, or a positive oral egg food challenge result.
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A specialist is defined as a health care provider with the training and experience to (1) perform and interpret SPTs and OFCs and (2) know and manage their risks. Such persons must have appropriate medications and equipment on site.
Addendum guideline 1
The EP recommends that infants with severe eczema, egg allergy, or both have introduction of age-appropriate peanut-containing food as early as 4 to 6 months of age to reduce the risk of peanut allergy. Other solid foods should be introduced before peanut-containing foods to show that the infant is developmentally ready. The EP recommends that evaluation with peanut-specific IgE (peanut sIgE) measurement, SPTs, or both be strongly considered before introduction of peanut to determine if peanut should be introduced and, if so, the preferred method of introduction. To minimize a delay in peanut introduction for children who may test negative, testing for peanut sIgE may be the preferred initial approach in certain health care settings, such as family medicine, pediatrics, or dermatology practices, in which skin prick testing is not routine. Alternatively, referral for assessment by a specialist may be an option if desired by the health care provider and when available in a timely manner.
Figure 1 provides recommended approaches for evaluation of children with severe eczema, egg allergy, or both before peanut introduction.
A peanut sIgE level of less than 0.35 kUA/L has strong negative predictive value for the diagnosis of peanut allergy [21]. Therefore, peanut sIgE testing may help in certain health care settings (eg, family medicine, pediatric, or dermatology practices, where skin prick testing is not routine) to reduce unnecessary referrals of children with severe eczema, egg allergy, or both and to minimize a delay in peanut introduction for children who may have negative test results. However, the EP emphasizes that a peanut sIgE level of 0.35 kUA/L or greater lacks adequate positive predictive value for the diagnosis of peanut allergy, and an infant with a value of 0.35 kUA/L or greater should be referred to a specialist.
Thus, peanut sIgE testing can place an infant into one of 2 categories (Fig. 1):
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sIgE Category A: If the peanut sIgE level is less than 0.35 kUA/L (ImmunoCAP), the EP recommends that peanut should be introduced in the diet soon thereafter, with a cumulative first dose of approximately 2 g of peanut protein given in this feeding. This can be given as a feeding at home (Appendix D), considering the low likelihood of a severe allergic reaction. If the caregiver or health care provider has concerns, a supervised feeding can be offered at the health care provider’s office (Appendix E).
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sIgE Category B: If the peanut sIgE level is 0.35 kUA/L or greater (ImmunoCAP), the EP recommends that the child be referred to a specialist for further consultation and possible skin prick testing.
The EP does not recommend food allergen panel testing or the addition of sIgE testing for foods other than peanut because of their poor positive predictive value, which could lead to misinterpretation, overdiagnosis of food allergy, and unnecessary dietary restrictions [6].
SPTs with peanut extract can place an infant in one of 3 categories (Fig. 1):
-
SPT Category A: If an SPT to peanut extract produces a wheal diameter of 2 mm or less above saline control, the EP recommends that peanut be introduced in the diet soon after testing, with a cumulative first dose of approximately 2 g of peanut protein given in this feeding. This can be given at home (Appendix D), considering the low likelihood of a severe allergic reaction. If the caregiver or health care provider has concerns, a supervised feeding can be offered at the health care provider’s office (Appendix E).
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SPT Category B: If an SPT to peanut extract produces a wheal diameter of 3 to 7 mm greater than that elicited by the saline control, the EP suggests that a supervised peanut feeding or a graded OFC be undertaken at a specialist’s office or a specialized facility (see Appendices E and G, respectively). Infants in this category can be sensitized without being allergic to peanut and might benefit from early peanut consumption. If the supervised peanut feeding or graded OFC yields no reaction, the EP recommends that peanut should be added to the child’s diet. If the supervised peanut feeding or the graded OFC results in an allergic reaction, the EP recommends that the child should strictly avoid dietary peanut and the family should be counseled regarding food allergy management.
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SPT Category C: If an SPT produces a wheal diameter 8 mm or greater than that elicited by the saline control, the likelihood of peanut allergy is high. Children in this category should continue to be evaluated and managed by a specialist. [21–23]
How much dietary peanut protein to introduce
If the decision is made to introduce dietary peanut based on the recommendations of addendum guideline 1, the total amount of peanut protein to be regularly consumed per week should be approximately 6 to 7 g over 3 or more feedings (see Appendix F). In the LEAP trial, at evaluations conducted at 12 and 30 months of age, 75% of children in the peanut consumption group reported eating at least this amount of peanut, based on analysis of a 3-day food diary recorded just before the evaluation.
Rationale
Infants with severe eczema, egg allergy, or both are at high risk for the development of peanut allergy. Significant evidence on this group is available from the infants who participated in the LEAP trial or were screened for the LEAP trial but were not enrolled because of a large SPT response (>4 mm). At 60 months of age, approximately 23% of peanut avoiders and those infants not enrolled had food allergy [24].
Balance of benefits and harms
In the LEAP trial, among the 530 participants in the intention-to-treat population with negative baseline SPT responses to peanut, 13.7% of the avoidance group and 1.9% of the consumption group had peanut allergy at 60 months of age (P < .001; a 12.6% absolute risk reduction and an 86.1% relative risk reduction in the prevalence of peanut allergy, resulting in a number needed to treat of 8.5 [number of infants needed to have early introduction of peanut to prevent peanut allergy in one child]). Among the 98 participants with positive peanut SPT responses at entry, 35.3% of the avoidance group and 10.6% of the consumption group had peanut allergy at 60 months of age (P = .004; a 24.7% absolute risk reduction and a 70% relative risk reduction in the prevalence of peanut allergy, resulting in a number needed to treat of 4).
The LEAP-On study [24] demonstrated that the benefits achieved in the LEAP trial persisted when LEAP trial peanut consumers subsequently avoided peanut for 1 year from 60 to 72 months of age. This indicates that the oral tolerance achieved in the LEAP trial was durable.
The LEAP trial did not include infants with SPT wheals greater than 4 mm, and therefore no data are available on the potential effectiveness of peanut consumption in preventing peanut allergy in this group. However, EP members believe it is possible that some of these infants may benefit from early introduction of peanut provided that they tolerate oral peanut.
As shown in Fig. 1, the EP recommends that infants with severe eczema, egg allergy, or both, with peanut sIgE levels of less than 0.35 kUA/L or with a peanut SPT wheal of 2 mm or less have dietary peanut introduced as early as 4 to 6 months of age without a need for further evaluation. This recommendation is supported by expert opinion and analysis of the LEAP population findings. In the LEAP trial, infants consuming peanut in this post hoc defined category had a relative risk reduction of 79% of having peanut allergy at 60 months of age compared with infants who avoided peanut.
In the LEAP trial, at study entry, all infants randomly assigned to the consuming group had a baseline peanut OFC. Of the 272 infants with no wheal induced by peanut SPT and who received a baseline oral peanut challenge, only 1 had a reaction presenting as an erythematous urticarial rash that was graded as a “moderate” adverse event and was treated successfully with chlorpheniramine. Among the 29 infants with a wheal diameter of 1 to 2 mm who received a baseline oral peanut challenge, 2 had reactions, which also presented with mild symptoms not requiring treatment with epinephrine. Therefore, for the SPT Category A children, the risk of a severe reaction to peanut at first introduction is low, and introduction of peanut at home is an option. However, it is understandable that some caregivers of infants with severe eczema, egg allergy, or both may be uncomfortable introducing dietary peanut at home. In such cases the health care provider should offer the option of a supervised feeding of a peanut-containing food in the office.
The rate of positive peanut OFC results at baseline for infants with a 3 to 4 mm wheal diameter (4/17 infants) was higher than in infants with 0 to 2 mm wheal diameters (3/301 infants), but the elicited symptoms were mild. Infants with larger wheal diameters (>4 mm) were not included in the LEAP trial, and therefore no safety data are available from this group. However, based on the Australian HealthNuts study, which conducted peanut OFCs in a large number of older (12–18 months old) children from the general Australian population, the rate of reactions to peanut is expected to be substantially higher with increasing SPT wheal diameter [21, 23]. In the HealthNuts study [23] an SPT wheal diameter of 8 mm or greater had a 95% positive predictive value for peanut allergy (positive oral peanut challenge result). Therefore, the EP recommends that for SPT Category B infants (3 to 7 mm SPT wheal diameter), a supervised feeding or a graded peanut OFC should be conducted in a specialist’s office or a specialized facility (Appendix G). SPT Category C infants are considered high risk for established allergy to peanut and should not receive peanut-containing foods in their diet, unless such foods are recommended by a specialist after further evaluation.
Quality of evidence: Moderate
The designation of the quality of evidence as “moderate” (as opposed to “high”) is based on the fact that this recommendation derives primarily from a single randomized, open-label study: the LEAP trial. However, it should be noted that the assessment of the LEAP trial’s primary outcome was based on a double-blind, placebo-controlled OFC. Furthermore, confidence in this recommendation is bolstered by the large effect size demonstrated in the LEAP trial and prior epidemiologic data that peanut allergy is relatively infrequent in Israel, where early childhood consumption of peanut is common.
Contribution of expert opinion
Significant.
Additional comments
-
1.
Breast-feeding recommendations: The EP recognizes that early introduction of peanut may seem to depart from recommendations for exclusive breast-feeding through 6 months of age [25, 26]. However, it should be noted that data from the nutrition analysis of the LEAP cohort [27] indicate that introduction of peanut did not affect the duration or frequency of breast-feeding and did not influence growth or nutrition.
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2.
Age of peanut introduction: For children with severe eczema, egg allergy, or both, the EP recommends that introduction of solid foods begins at 4 to 6 months of age, starting with solid food other than peanut, so that the child can demonstrate the ability to consume solid food without evidence of nonspecific signs and symptoms that could be confused with IgE-mediated food allergy. However, it is important to note that infants in the LEAP trial were enrolled between 4 and 11 months of age and benefitted from peanut consumption regardless of age at entry. Therefore, if the 4- to 6-month time window is missed for any reason, including developmental delay, infants may still benefit from early peanut introduction. On the other hand, older age at screening is associated with larger wheal diameters induced by peanut SPT and hence a higher likelihood of established peanut allergy [28].
A practical consideration for applying this guideline at 4 to 6 months of age is that infants visit their health care provider for well-child evaluations and infant immunizations at this time. This provides a fortuitous opportunity for eczema evaluation, caregiver reporting of egg allergy, and, if needed, referral to a specialist for peanut allergy evaluation before dietary introduction of peanut.
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3.
Considerations for family members with established peanut allergy: The EP recognizes that many infants eligible for early peanut introduction under this guideline will have older siblings or caregivers with established peanut allergy. The EP recommends that in this situation caregivers discuss with their health care providers the overall benefit (reduced risk of peanut allergy in the infant) versus risk (potential for further sensitization and accidental exposure of the family member to peanut) of adding peanut to the infant’s diet.
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4.
Children identified as allergic to peanut: For children who have been identified as allergic to peanut, the EP recommends strict peanut avoidance. This may include those children in SPT Category B who fail the supervised peanut feeding or the OFC, or those children in SPT Category C who, on further evaluation by a specialist, are confirmed as being allergic to peanut. These children should be under long-term management by a specialist.
Addendum guideline 2
The EP suggests that infants with mild-to-moderate eczema should have introduction of age-appropriate peanut-containing food around 6 months of age, in accordance with family preferences and cultural practices, to reduce the risk of peanut allergy. Other solid foods should be introduced before peanut-containing foods to show that the infant is developmentally ready. The EP recommends that infants in this category may have dietary peanut introduced at home without an in-office evaluation. However, the EP recognizes that some caregivers and health care providers may desire an in-office supervised feeding, evaluation, or both.
Rationale
The LEAP trial did not target infants with mild or moderate eczema. The EP considered the potential risk/benefit ratio of early dietary peanut introduction in infants with mild-to-moderate eczema and concluded that the individual and societal benefits of introducing peanut in this population would be significant. The EP has no reason to believe that the mechanisms of protection of early dietary peanut differ in infants with mild-to-moderate eczema from those that lead to protection in infants at higher risk of peanut allergy.
Balance of benefits and harms
The LEAP trial included only infants with severe eczema or egg allergy based on careful medical history. Therefore, some infants who participated in the LEAP trial based on the presence of egg allergy had atopic dermatitis severity scores (SCORAD scores [29]) at screening that would have placed them in the moderate or mild eczema category. The EP considered the outcomes of these children and concluded that infants with mild-to-moderate eczema would likely benefit from early peanut introduction.
Quality of evidence
Low.
The quality of evidence is low because this recommendation is based on extrapolation of data from a single study.
Contribution of expert opinion
Significant.
Additional comment
Additional support for early introduction of peanut in infants who do not have severe eczema comes from the Enquiring About Tolerance study [17], which enrolled infants from the general population at 3 months of age and sequentially introduced 6 allergenic foods beginning at the time of enrollment. These children were not intentionally selected based on increased risk of food allergy or atopy. Although the intention-to-treat group did not show benefit, most likely because of relatively poor compliance with feeding recommendations, the children in the per-protocol group who had peanut introduced early in infancy showed a significant reduction in peanut sensitization and peanut allergy at age 3 years. This study also provides support for guideline 3 below.
Addendum guideline 3
The EP suggests that infants without eczema or any food allergy have age-appropriate peanut-containing foods freely introduced in the diet together with other solid foods and in accordance with family preferences and cultural practices.
Rationale
No evidence exists for restricting allergenic foods in infants without known risks for food allergy. The probability for development of peanut allergy in such children is very low. However, approximately 14% of all children with peanut allergy at age 12 to 18 months in the HealthNuts Study lacked known risk factors for food allergy [16]. Consequently, because such children constitute a significant majority of any birth cohort, they contribute substantially to the overall societal burden of peanut allergy. The EP finds no evidence to suggest that mechanisms of oral tolerance induction would differ in these infants from the immunologic mechanisms that are protective in infants at higher risk of peanut allergy. Thus, the early introduction of dietary peanut in children without risk factors for peanut allergy is generally anticipated to be safe and to contribute modestly to an overall reduction in the prevalence of peanut allergy. Furthermore, in countries such as Israel, where peanut products are a popular component of the diet and where they are introduced early in life, the prevalence of peanut allergy is low [14].
Balance of benefits and harms
The EP acknowledges that any analysis of benefit and harm in this population relies primarily on expert opinion and is subject to current differences in regional/societal rates of peanut consumption and peanut sensitization. In countries where peanut products are not widely consumed by adults, early dietary introduction of peanut could lead to an increase in sensitization and allergic manifestations. Hence the EP cautions that this guideline be implemented in the context of societal routines/norms.
Quality of evidence
Low.
Contribution of expert opinion
Significant.
Clinical implications: These guidelines will help health care providers with early introduction of peanut-containing foods in infants at various risk levels for peanut allergy. Early introduction of peanut will result in the prevention of peanut allergy in a large number of infants. |
Abbreviations
- CC:
-
Coordinating Committee
- EP:
-
Expert Panel
- GRADE:
-
Grading of Recommendations Assessment, Development and Evaluation
- LEAP:
-
Learning Early about Peanut Allergy
- NIAID:
-
National Institute of Allergy and Infectious Diseases
- OFC:
-
Oral food challenge
- sIgE:
-
Specific IgE
- SPT:
-
Skin prick test
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Feeney M, Du Toit G, Roberts R, Sayre PH, Lawson K, Bahnson HT, et al. Impact of peanut consumption in the LEAP study: feasibility, growth and nutrition. J Allergy Clin Immunol. 2016;138:1108–18.
Du Toit G, Roberts G, Sayre PH, Plaut M, Bahnson HT, et al. Identifying infants at high risk of peanut allergy: the Learning Early About Peanut Allergy (LEAP) screening study. J Allergy Clin Immunol. 2013;131:135–43. e1-12.
Severity scoring of atopic dermatitis: the SCORAD index. Consensus Report of the European Task Force on Atopic Dermatitis. Dermatology 1993;186:23-31.
Bird JA, Groetch M, Allen KJ, Bock SA, Leonard A, Nowak-Wegrzyn AH, et al. Conducting an oral food challenge to peanut in an infant: a work group report. J Allergy Clin Immunol Pract. 2016. In press.
Acknowledgements
There are none.
Funding
Not applicable
Availability of data and materials
Not applicable.
Authors’ contributions
AT, DR and SC wrote the document based on the EP deliberations, and the EP authors reviewed, edited, and approved the submitted version. All authors read and approved the final manuscript.
Competing interests
A. Assa’ad received travel support from the American College of Allergy, Asthma & Immunology (ACAAI); was an elected member of the Board of Directors for the American Academy of Allergy, Asthma, & Immunology (AAAAI) from March 2012 to March 2016; has consultant arrangements with Aimmune; is employed by Cincinnati Children’s Hospital Medical Center; has received grants from DBV Technologies, Aimmune, Stanford Foundation, TEVA Pharmaceuticals, GlaxoSmithKline, the National Institutes of Health (NIH), Astellas, and Food Allergy Research & Education (FARE); and has received payment for lectures from the ACAAI. C. Byrd-Bredbenner and G. J. Fuchs III have received travel support from the NIH/National Institute of Allergy and Infectious Disease (NIAID). E. S. Chan has received travel support from the NIAID, has received grants from DBV Technologies, and has received payment for lectures from Pfizer, Sanofi, Mead Johnson, and Nestle. D. M. Fleischer has received travel support from the NIAID; is a board member for the National Peanut Board, the FAACT Medical Advisory Board, and the FARE Medical Advisory Board; has consultant arrangements with Adamis Pharmaceuticals Corporation, INSYS Therapeutics, DBV Technologies, Aimmune Therapeutics, Intrommune Therapeutics, and Kaleo Pharma; is employed by University Physicians; has received grants from Monsanto Company, Nestle Nutrition Institute, DBV Technologies, and Aimmune Therapeutics; has received payment for lectures from Nestle Nutrition Institute; and has received royalties from UpToDate. M. J. Greenhawt has received a grant from the Agency for Healthcare Research and Quality (1K08HS024599-01, Career Development Award); has received travel support from the NIAID and the Joint Taskforce on Allergy Practice Parameters; has a board membership with the National Peanut Board; has consultant arrangements with Adamis Pharmaceuticals, the Canadian Transportation Agency, Nutricia, Nestle/Gerber, Aimmune, Kaleo Pharmaceutical, and Monsanto; is an Associate Editor for the Annals of Allergy, Asthma, and Immunology; has received payment for lectures from the ACAAI, Reach MD, Thermo Fisher Scientific, the California Society for Allergy and Immunology, the Allergy and Asthma Network, the New England Society for Allergy, UCLA/Harbor Heiner Lectureship, Medscape, the Western Michigan School of Medicine, the Canadian Society of Allergy and Clinical Immunology, and the Pennsylvania Society for Allergy and Immunology. R. S. Gupta has consultant arrangements with BEFORE Brands and DBV Technologies; has received grants from the NIH, FARE, and Mylan LLC; has received payment for lectures from Grand Rounds; and has received royalties from Createspace Independent Publishing Platform. S. M. Jones is on the Research Advisory Board for FARE; is on the Scientific Advisory Board for Aimmune; has consultant arrangements with Stallergenes; has received grants from the NIH/NIAID (Consortium of Food Allergy Research and Immune Tolerance Network–IMPACT Trial), FARE, Aimmune Technologies, DBV Technologies, and the National Peanut Board; has received payment for lectures from the Kansas City Allergy Society, Mercy Children’s Hospital, Riley Children’s Hospital, Southwester Medical School–Children’s Medical Center, the European Academy of Allergy & Clinical Immunology, the New York Allergy & Asthma Society, the University of Iowa Paul M. Seebohm Lectureship in Allergy, and the Iowa Society of Allergy, Asthma, and Immunology. A. Muraro has consultant arrangements with Meda, Novartis, and Menarini; is employed by Padua University Hospital; and has received payment for lectures from Meda and Menarini. L. J. Rosenwasser is a board member for the World Allergy Organization. H. A. Sampson has consultant arrangements with Allertein Therapeutics, Genentech/Roche, Sanofi, Stallergenes, Danone, and Merck; is employed part time as Chief Scientific Officer for DBV Technologies; has received grants from the NIAID and the Immune Tolerance Network; has received royalties from UpToDate and Elsevier; has been offered stock options in DBV Technologies; and is chairman of PhARF Award Selection Committee for Thermo Fisher. L. C. Schneider is on the Medical Advisory Board for FARE, has received a grant from DBV Technologies, and has received stock/stock options in Antera Therapeutics. S. H. Sicherer has received grants from the NIAID, FARE, and HAL Allergy; has received royalties from UpToDate; and is serving as Associate Editor for the Journal of Allergy and Clinical Immunology: In Practice. R. Sidbury has received travel support from the NIH and the Hawaii Dermatology Seminar, has consultant arrangements with Anacor, has provided expert witness testimony on behalf of Roche in Accutane–inflammatory bowel disease cases, has received a grant from Epidermolysis Bullosa Research Partnership, has received payment for lectures from the Taiwanese Dermatological Society, and has received royalties from UpToDate. J. Spergel has consultant arrangements with DBV Technologies and Danone; has received grants from DBV Technologies, Aimmune Therapeutics, and the NIH; has received payment for lectures for Dartmouth College, the ACAAI, and the Florida Allergy Society; and has received stock/stock options in DBV Technologies. D. R. Stukus has received payment for lectures from the ACAAI. C. Venter has consultant arrangements with Danone and Nestle, has received payment for lectures from Mead Johnson, and has received travel support from Thermo Fisher. The rest of the authors declare that they have no relevant conflicts of interest.
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Declarations
Published on behalf of the American Academy of Allergy, Asthma & Immunology; American College of Allergy, Asthma & Immunology; Canadian Society of Allergy and Clinical Immunology; Society for Pediatric Dermatology; World Allergy Organization; and Society of Pediatric Nurses.
Copublished in the Journal of Allergy and Clinical Immunology; Annals of Allergy, Asthma & Immunology; Allergy, Asthma & Clinical Immunology; World Allergy Organization Journal; Pediatric Dermatology; and the Journal of Pediatric Nursing.
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Appendices
Appendix A
Coordinating Committee member organizations and representatives
Academy of Nutrition and Dietetics
Alison Steiber, PhD, RD
Allergy & Asthma Network Mothers of Asthmatics (AANMA)
http://www.allergyasthmanetwork.org/main/
Tonya A. Winders, MBA
American Academy of Allergy, Asthma & Immunology (AAAAI)
https://www.aaaai.org/home.aspx
Hugh A. Sampson, MD
David Fleischer, MD
American Academy of Family Physicians (AAFP)
Jason Matuszak, MD
American Academy of Dermatology (AAD)
Lawrence F. Eichenfield, MD, FAAD
Jon Hanifin, MD
American Academy of Emergency Medicine (AAEM)
Joseph P. Wood, MD, JD
American Academy of Pediatrics (AAP)
Scott H. Sicherer, MD, FAAP
American Academy of Physician Assistants (AAPA)
Gabriel Ortiz, MPAS, PA-C, DFAAPA
American College of Allergy, Asthma and Immunology (ACAAI)
Amal Assa’ad, MD
American College of Gastroenterology (ACG)
Steven J. Czinn, MD, FACG
American Partnership for Eosinophilic Disorders (APFED)
Wendy Book, MD
American Society for Nutrition (ASN)
George J. Fuchs III, MD
Asthma and Allergy Foundation of America (AAFA)
Meryl Bloomrosen, MBA, MBI
David R. Stukus, MD
Canadian Society of Allergy and Clinical Immunology (CSACI)
Edmond Chan, MD, FRCPC
Eunice Kennedy Shriver National Institute of Child Health & Human Development (NICHD)
Gilman Grave, MD
European Academy of Allergy and Clinical Immunology (EAACI)
Antonella Muraro, MD, PhD
Food Allergy Research & Education (FARE)
James R. Baker, MD
Mary Jane Marchisotto
National Eczema Association (NEA)
Julie Block
National Heart, Lung, and Blood Institute (NHLBI)
Janet M. de Jesus, MS, RD
National Institute of Allergy and Infectious Diseases (NIAID)
Daniel Rotrosen, MD
Alkis Togias, MD
Marshall Plaut, MD
National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS)
Ricardo Cibotti, PhD
National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK)
Frank Hamilton, MD, MPH
Margaret A. McDowell, PhD, MPH, RD (retired)
Rachel Fisher, MS, MPH, RD
North American Society for Pediatric Gastroenterology, Hepatology and Nutrition (NASPGHAN)
Glenn Furuta, MD
Society of Pediatric Nurses (SPN)
Michele Habich, DNP, APN/CNS, CPN
United States Department of Agriculture (USDA)
Soheila J. Maleki, PhD
World Allergy Organization (WAO)
Lanny J. Rosenwasser, MD
Appendix B
Expert Panel, June 2015
Chair
Joshua A. Boyce, MD
Professor of Medicine and Pediatrics
Harvard Medical School
Director, Inflammation and Allergic Disease Research Section
Director, Jeff and Penny Vinik Center for Allergic Disease Research
Specialty: Allergy/pediatric pulmonology
Panelists
Maria Acebal, JD
Board of Directors, Food Allergy Research & Education
Member of NIAID Advisory Council
Former CEO of Food Allergy and Anaphylaxis Network
Specialty: Advocacy
Amal Assa’ad, MD
Professor, University of Cincinnati Department of Pediatrics
Director, FARE Center of Excellence in Food Allergy
Director of Clinical Services, Division of Allergy and Immunology
Associate Director, Division of Allergy and Immunology
Cincinnati Children’s Hospital Medical Center
Specialty: Allergy/pediatrics
James R. Baker, Jr, MD
CEO and Chief Medical Officer
Food Allergy Research & Education, McLean VA
Founding Director, Mary H. Weiser Food Allergy Center, University of Michigan
Professor of Internal Medicine, Division of Allergy and Clinical Immunology
University of Michigan Health System
Specialty: Allergy/advocacy/education
Lisa A. Beck, MD
Professor, Department of Dermatology
University of Rochester Medical Center
School of Medicine and Dentistry
Specialty: Dermatology
Julie Block
President and CEO
National Eczema Association
Specialty: Advocacy/education
Carol Byrd-Bredbenner, PhD, RD, FAND
Professor of Nutrition/Extension Specialist
Rutgers University, School of Environmental and Biological Sciences
Specialty: Nutrition/health communication/behavioral science
Edmond S. Chan, MD, FRCPC
Clinical Associate Professor
Head, Division of Allergy and Immunology
Department of Pediatrics
BC Children’s Hospital
University of British Columbia
Specialty: Allergy/pediatrics
Lawrence F. Eichenfield, MD
Professor of Pediatrics and Dermatology
Chief, Pediatric and Adolescent Dermatology
Rady Children’s Hospital, San Diego
University of California, San Diego School of Medicine
Specialty: Dermatology/pediatrics
David M. Fleischer, MD
Associate Professor of Pediatrics
University of Colorado School of Medicine
Children’s Hospital Colorado, Aurora, CO
Specialty: Allergy/pediatrics
George J. Fuchs III, MD
Professor of Pediatrics
University of Kentucky College of Medicine
Chief, Gastroenterology, Nutrition & Hepatology
Kentucky Children’s Hospital
Specialty: Gastroenterology/pediatrics
Glenn T. Furuta, MD
Professor of Pediatrics
Director, Gastrointestinal Eosinophilic Diseases Program
University of Colorado School of Medicine
Children’s Hospital Colorado, Aurora, CO
Specialty: Gastroenterology/pediatrics
Matthew J. Greenhawt, MD, MBA, MSc
Assistant Professor of Pediatrics
Allergy Section
University of Colorado School of Medicine
Children’s Hospital Colorado, Aurora, CO
Specialty: Allergy/pediatrics
Ruchi Gupta, MD, MPH
Associate Professor of Pediatrics and Medicine
Director, Food Allergy Outcomes Research Program
Ann and Robert H. Lurie Children’s Hospital of Chicago
Northwestern Medicine, Northwestern University
Specialty: Pediatrics
Michele Habich, DNP, APN/CNS, CPN
Advanced Practice Nurse
Northwestern Medicine, Central DuPage Hospital
Specialty: Nursing/pediatrics/education
Stacie M. Jones, MD
Professor of Pediatrics
University of Arkansas for Medical Sciences
Chief, Allergy and Immunology
Arkansas Children’s Hospital
Specialty: Allergy/pediatrics
Kari Keaton
Facilitator, Metro DC Food Allergy Support Group
Specialty: Advocacy/education
Antonella Muraro, MD, PhD
President of European Academy of Allergy and Clinical Immunology (EAACI)
Professor of Allergy and Pediatric Allergy
Head of the Veneto Region Food Allergy Centre of Excellence for Research and Treatment
University Hospital of Padua, Italy
Specialty: Allergy/pediatrics
Lanny J. Rosenwasser, MD
Immediate Past President, World Allergy Organization
Professor of Medicine
University of Missouri-Kansas City-School of Medicine
Specialty: Allergy/pediatrics
Hugh A. Sampson, MD
Professor of Pediatrics, Allergy and Immunology
Icahn School of Medicine at Mount Sinai
Director, Jaffe Food Allergy Institute
Specialty: Allergy/pediatrics
Lynda C. Schneider, MD
Professor of Pediatrics
Harvard Medical School
Director, Allergy Program
Boston Children’s Hospital
Specialty: Allergy/pediatrics
Scott H. Sicherer, MD
Professor Pediatrics, Allergy and Immunology
Icahn School of Medicine at Mount Sinai
Division Chief, Pediatric Allergy and Immunology
Specialty: Allergy/pediatrics
Robert Sidbury, MD, MPH
Professor
Department of Pediatrics
Chief, Division of Dermatology
Seattle Children’s Hospital
University of Washington School of Medicine
Specialty: Dermatology/pediatrics
Jonathan Spergel, MD, PhD
Stuart Starr Professor of Pediatrics
Chief, Allergy Section
Director, Center for Pediatric Eosinophilic Disorders
The Children’s Hospital of Philadelphia
Perelman School of Medicine, University of Pennsylvania
Specialty: Allergy/pediatrics
David R. Stukus, MD
Assistant Professor of Pediatrics
Section of Allergy/Immunology
Nationwide Children’s Hospital
Columbus
Specialty: Allergy/pediatrics
Carina Venter, PhD, RD
Allergy Specialist, Dietitian
Cincinnati Children’s Hospital Medical Center
University of Cincinnati College of Medicine
Specialty: Allergy/dietitian/pediatrics
Appendix C
Tier 1 references
-
Feeney M, Du Toit G, Roberts R, Sayre PH, Lawson K, Bahnson HT, et al. Impact of peanut consumption in the LEAP study: feasibility, growth and nutrition. J Allergy Clin Immunol 2016;138:1108–18.
-
Koplin JJ, Peters RL, Dharmage SC, Gurrin L, Tang MLK, Ponsonby AL, et al. Understanding the feasibility and implications of implementing early peanut introduction for prevention of peanut allergy. J Allergy Clin Immunol 2016;138:1131–41.e2.
-
Perkin MR, Logan K, Tseng A, Raji B, Ayis S, Peacock J, et al. Randomized trial of introduction of allergenic foods in breast-fed infants. N Engl J Med 2016;374:1733–43.
-
Du Toit G, Sayre PH, Roberts G, Sever ML, Lawson K, Bahnson HT, et al. Effect of avoidance on peanut allergy after early peanut consumption. N Engl J Med 2016;374:1435–43.
-
Chang YS, Trivedi MK, Jha A, Lin YF, Dimaano L, García-Romero MT. Synbiotics for prevention and treatment of atopic dermatitis: a meta-analysis of randomized clinical trials. JAMA Pediatr 2016;170:236–42.
-
O’Connor C, Kelleher M, O’B Hourihane J. Calculating the effect of populationlevel implementation of the Learning Early About Peanut Allergy (LEAP) protocol to prevent peanut allergy. J Allergy Clin Immunol 2016;137:1263–4.e2.
-
Grimshaw KE, Bryant T, Oliver EM, Martin J, Maskell J, Kemp T, et al. Incidence and risk factors for food hypersensitivity in UK infants: results from a birth cohort study. Clin Transl Allergy 2016;6:1.
-
Rabinovitch N, Shah D, Lanser BJ. Look before you LEAP: risk of anaphylaxis in high-risk infants with early introduction of peanut. J Allergy Clin Immunol 2015;136:822.
-
Peters RL, Allen KJ, Dharmage SC, Lodge CJ, Koplin JJ, Ponsonby AL, et al. Differential factors associated with challenge-proven food allergy phenotypes in a population cohort of infants: a latent class analysis. Clin Exp Allergy 2015;45:953–63.
-
Peters RL, Allen KJ, Dharmage SC, Koplin JJ, Dang T, Tilbrook KP, et al. Natural history of peanut allergy and predictors of resolution in the first 4 years of life: a population-based assessment. J Allergy Clin Immunol 2015;135:1257–66.e2.
-
Du Toit G, Roberts G, Sayre PH, Bahnson HT, Radulovic S, Santos AF, et al. Randomized trial of peanut consumption in infants at risk for peanut allergy. N Engl J Med 2015;372:803–13.
-
Martin PE, Eckert JK, Koplin JJ, Lowe AJ, Gurrin LC, Dharmage SC, et al. Which infants with eczema are at risk of food allergy? Results from a population-based cohort. Clin Exp Allergy 2015;45:255–64.
-
Grimshaw KE, Maskell J, Oliver EM, Morris RC, Foote KD, Mills EN, et al. Introduction of complementary foods and the relationship to food allergy. Pediatrics 2013;132:e1529–38.
-
Palmer DJ, Metcalfe J, Makrides M, Gold MS, Quinn P, West CE, et al. Early regular egg exposure in infants with eczema: a randomized controlled trial. J Allergy Clin Immunol 2013;132:387–92.e1.
-
Du Toit G, Roberts G, Sayre PH, Plaut M, Bahnson HT, Mitchell H, et al. Identifying infants at high risk of peanut allergy: the Learning Early About Peanut Allergy (LEAP) screening study. J Allergy Clin Immunol 2013;131:135–43, e1-12.
-
Joseph CL, Ownby DR, Havstad SL, Woodcroft KJ, Wegienka G, MacKechnie H, et al. Early complementary feeding and risk of food sensitization in a birth cohort. J Allergy Clin Immunol 2011;127:1203–10.e5.
-
Koplin JJ, Osborne NJ, Wake M, Martin PE, Gurrin LC, Robinson MN, et al. Can early introduction of egg prevent egg allergy in infants? A population-based study. J Allergy Clin Immunol 2010;126:807–13.
-
Katz Y, Rajuan N, Goldberg MR, Eisenberg E, Heyman E, Cohen A, et al. Early exposure to cow’s milk protein is protective against IgE-mediated cow’s milk protein allergy. J. Allergy Clin Immunol 2010;126:77–82.e1.
Appendix D
Instructions for home feeding of peanut protein for infants at low risk of an allergic reaction to peanut
These instructions for home feeding of peanut protein are provided by your doctor. You should discuss any questions that you have with your doctor before starting. These instructions are meant for feeding infants who have severe eczema or egg allergy and were allergy tested (blood test, skin test, or both) with results that your doctor considers safe for you to introduce peanut protein at home (low risk of allergy).
General instructions
-
1.
Feed your infant only when he or she is healthy; do not do the feeding if he or she has a cold, vomiting, diarrhea, or other illness.
-
2.
Give the first peanut feeding at home and not at a day care facility or restaurant.
-
3.
Make sure at least 1 adult will be able to focus all of his or her attention on the infant, without distractions from other children or household activities.
-
4.
Make sure that you will be able to spend at least 2 h with your infant after the feeding to watch for any signs of an allergic reaction.
Feeding your infant
-
1.
Prepare a full portion of one of the peanut-containing foods from the recipe options below.
-
2.
Offer your infant a small part of the peanut serving on the tip of a spoon.
-
3.
Wait 10 min.
-
4.
If there is no allergic reaction after this small taste, then slowly give the remainder of the peanut-containing food at the infant’s usual eating speed.
What are symptoms of an allergic reaction? What should I look for?
-
Mild symptoms can include:
-
○ a new rash
or
-
○ a few hives around the mouth or face
-
-
More severe symptoms can include any of the following alone or in combination:
-
○ lip swelling
-
○ vomiting
-
○ widespread hives (welts) over the body
-
○ face or tongue swelling
-
○ any difficulty breathing
-
○ wheeze
-
○ repetitive coughing
-
○ change in skin color (pale, blue)
-
○ sudden tiredness/lethargy/seeming limp
-
If you have any concerns about your infant’s response to peanut, seek immediate medical attention/call 911.
Four recipe options, each containing approximately 2 g of peanut protein
Note: Teaspoons and tablespoons are US measures (5 and 15 mL for a level teaspoon or tablespoon, respectively).
-
Option 1: Bamba (Osem, Israel), 21 pieces (approximately 2 g of peanut protein)
Note: Bamba is named because it was the product used in the LEAP trial and therefore has proven efficacy and safety. Other peanut puff products with similar peanut protein content can be substituted.
-
a.
For infants less than 7 months of age, soften the Bamba with 4 to 6 teaspoons of water.
-
b.
For older infants who can manage dissolvable textures, unmodified Bamba can be fed. If dissolvable textures are not yet part of the infant’s diet, softened Bamba should be provided.
-
a.
-
Option 2: Thinned smooth peanut butter, 2 teaspoons (9–10 g of peanut butter; approximately 2 g of peanut protein)
-
a.
Measure 2 teaspoons of peanut butter and slowly add 2 to 3 teaspoons of hot water.
-
b.
Stir until peanut butter is dissolved, thinned, and well blended.
-
c.
Let cool.
-
d.
Increase water amount if necessary (or add previously tolerated infant cereal) to achieve consistency comfortable for the infant.
-
a.
-
Option 3: Smooth peanut butter puree, 2 teaspoons (9–10 g of peanut butter; approximately 2 g of peanut protein)
-
a.
Measure 2 teaspoons of peanut butter.
-
b.
Add 2 to 3 tablespoons of pureed tolerated fruit or vegetables to peanut butter. You can increase or reduce volume of puree to achieve desired consistency.
-
a.
-
Option 4: Peanut flour and peanut butter powder, 2 teaspoons (4 g of peanut flour or 4 g of peanut butter powder; approximately 2 g of peanut protein)
Note: Peanut flour and peanut butter powder are 2 distinct products that can be interchanged because they have a very similar peanut protein content.
-
a.
Measure 2 teaspoons of peanut flour or peanut butter powder.
-
b.
Add approximately 2 tablespoons (6–7 teaspoons) of pureed tolerated fruit or vegetables to flour or powder. You can increase or reduce volume of puree to achieve desired consistency.
-
a.
Appendix E
For health care providers: In-office supervised feeding protocol using 2 g of peanut protein
General instructions
-
1.
These recommendations are reserved for an infant defined in guideline 1 as one with severe eczema, egg allergy, or both and with negative or minimally reactive (1 to 2 mm) SPT responses and/or peanut sIgE levels of less than 0.35 kUA/L. They also may apply to the infant with a 3 to 7 mm SPT response if the specialist health care provider decides to conduct a supervised feeding in the office (as opposed to a graded OFC in a specialized facility [see Fig. 1]).
These recommendations can also be followed for infants with mild-to-moderate eczema, as defined in guideline 2, when caregivers and health care providers may desire an in-office supervised feeding.
-
2.
Proceed only if the infant shows no evidence of any concomitant illness, such as an upper respiratory tract infection.
-
a.
Start with a small portion of the initial peanut serving, such as the tip of a teaspoon of peanut butter puree/softened Bamba.
-
b.
Wait 10 min; if there is no sign of reaction after this small portion is given, continue gradually feeding the remaining serving of peanut-containing food (see options below) at the infant’s typical feeding pace.
-
c.
Observe the infant for 30 min after 2 g of peanut protein ingestion for signs/symptoms of an allergic reaction.
-
a.
Four recipe options, each containing approximately 2 g of peanut protein
Note: Teaspoons and tablespoons are US measures (5 and 15 mL for a level teaspoon or tablespoon, respectively).
-
Option 1: Bamba (Osem, Israel), 21 pieces (approximately 2 g of peanut protein)
Note: Bamba is named because it was the product used in the LEAP trial and therefore has known peanut protein content and proven efficacy and safety. Other peanut puffs products with similar peanut protein content can be substituted for Bamba.
-
a.
For infants less than 7 months of age, soften the Bamba with 4 to 6 teaspoons of water.
-
b.
For older infants who can manage dissolvable textures, unmodified Bamba can be fed. If dissolvable textures are not yet part of the infant’s diet, softened Bamba should be provided.
-
a.
-
Option 2: Thinned smooth peanut butter, 2 teaspoons (9–10 g of peanut butter; approximately 2 g of peanut protein)
-
a.
Measure 2 teaspoons of peanut butter and slowly add 2 to 3 teaspoons hot water.
-
b.
Stir until peanut butter is dissolved and thinned and well blended.
-
c.
Let cool.
-
d.
Increase water amount if necessary (or add previously tolerated infant cereal) to achieve consistency comfortable for the infant.
-
a.
-
Option 3: Smooth peanut butter puree, 2 teaspoons (9–10 g of peanut butter; approximately 2 g of peanut protein)
-
a.
Measure 2 teaspoons of peanut butter.
-
b.
Add 2 to 3 tablespoons of previously tolerated pureed fruit or vegetables to peanut butter. You can increase or reduce volume of puree to achieve desired consistency.
-
a.
-
Option 4: Peanut flour and peanut butter powder, 2 teaspoons (4 g of peanut flour or 4 g of peanut butter powder; approximately 2 g of peanut protein)
Note: Peanut flour and peanut butter powder are 2 distinct products that can be interchanged because they have, on average, a similar peanut protein content.
-
a.
Measure 2 teaspoons of peanut flour or peanut butter powder.
-
b.
Add approximately 2 tablespoons (6–7 teaspoons) of pureed tolerated fruit or vegetables to flour or powder. You can increase or reduce the volume of puree to achieve desired consistency.
-
a.
Appendix F
Peanut protein in peanut-containing foods
If the decision is made to introduce dietary peanut to the infant’s diet, the total amount of peanut protein to be regularly consumed per week should be approximately 6 to 7 g over 3 or more feedings. In the LEAP trial, at evaluations conducted at 12 and 24 months of age, 75% of children in the peanut consumption group reported eating at least this amount of peanut.
Be aware of choking risks
-
Whole nuts should not be given to children less than 5 years of age.
-
Peanut butter directly from a spoon or in lumps/dollops should not be given to children less than 4 years of age.
If, after a week or more eating peanut, your infant or child displays mild allergic symptoms within 2 h of eating peanut, you should contact your health care provider.
Typical peanut-containing foods, their peanut protein content, and feeding tips for infants are provided in Table 2, and their nutritional content is found in Table 3.
Appendix G
Graded OFC protocol
From “Conducting an oral food challenge to peanut in an infant: a work group report.” [30]
General instructions
-
1.
A graded OFC should be performed only by a specialist with the training and experience to (1) perform and interpret skin prick testing and OFCs and (2) know and manage their risks. Such persons must have appropriate medications and equipment on site.
-
2.
Four peanut preparations are provided:
-
a.
Option 1: Smooth peanut butter mixed with either a previously tolerated pureed fruit or vegetable.
-
b.
Option 2: Smooth peanut butter dissolved carefully with hot water and cooled.
-
c.
Option 3: Peanut flour mixed with either a previously tolerated pureed fruit or vegetable. Peanut butter powder can be used instead of the peanut flour.
-
d.
Option 4: Bamba peanut snack dissolved in hot water and cooled or even as a solid (ie, as a stick).
Note: Bamba (Osem, Israel) is named because it was the product used in the LEAP trial and therefore has known peanut protein content and proven efficacy and safety. Other peanut puff products with similar peanut protein content can be substituted for Bamba.
-
a.
-
3.
The peanut protein content of the graded OFC protocol is identical for all peanut preparations provided below, except that the volume of food ingested per dose is different. The protocol consists of 5 incremental doses, given 15 to 20 min apart, with a cumulative peanut protein total of approximately 4 g per the 3.9 g total in the LEAP trial.
-
4.
Refer to Table 4 and direct parents to discontinue specific medications for the prescribed amount of time before the graded OFC. Note that certain medications are allowed.
Be prepared in case of a severe reaction (see Table 5)
Note: Teaspoons and tablespoons are US measures (5 and 15 mL for a level teaspoon or tablespoon, respectively).
Option 1: Measures for smooth peanut butter puree
Dose | Peanut butter volumea | Equivalent weight of peanut butter (g [peanut protein content in grams])b | Pureed fruit or vegetable volume | Total volume |
---|---|---|---|---|
1 | \( \raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$8$}\right. \) teaspoon | 0.67 (0.15) | \( \raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$2$}\right. \) teaspoon | \( \raisebox{1ex}{$5$}\!\left/ \!\raisebox{-1ex}{$8$}\right. \) teaspoon |
2 | \( \raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$4$}\right. \) teaspoon | 1.33 (0.29) | \( \raisebox{1ex}{$3$}\!\left/ \!\raisebox{-1ex}{$4$}\right. \) teaspoon | 1 teaspoons |
3 | \( \raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$2$}\right. \) teaspoon | 2.67 (0.59) | 1 teaspoons | \( 1\raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$2$}\right. \) teaspoons |
4 | 1 teaspoon | 5.33 (1.17) | 2 teaspoons | 3 teaspoonsc |
5 | \( 1\raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$2$}\right. \) teaspoons | 8 (1.6) | 4 teaspoons | \( 5\raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$2$}\right. \) teaspoons |
Total protein: 3.96 g |
Option 2: Measures for smooth thinned peanut butter
Dose | Peanut butter volumea | Equivalent weight peanut butter (g [peanut protein content in grams])b | Volume of hot water | Total volume |
---|---|---|---|---|
1 | \( \raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$8$}\right. \) teaspoon | 0.67 (0.15) | \( \raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$8$}\right. \) teaspoon | \( \raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$4$}\right. \) teaspoon |
2 | \( \raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$4$}\right. \) teaspoon | 1.33 (0.29) | \( \raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$4$}\right. \) teaspoon | \( \raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$2$}\right. \) teaspoon |
3 | \( \raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$2$}\right. \) teaspoon | 2.67 (0.59) | \( \raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$2$}\right. \) teaspoon | 1 teaspoon |
4 | 1 teaspoon | 5.33 (1.17) | 1 teaspoon | 2 teaspoons |
5 | \( 1\raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$2$}\right. \) teaspoons | 8 (1.76) | \( 1\raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$2$}\right. \) teaspoons | 3 teaspoonsc |
Total protein: 3.96 g |
Option 3: Measures for peanut flour or peanut butter powder
Dose | Peanut flour or peanut butter powder volumea | Equivalent weight peanut flour or peanut butter powderb (g [peanut protein content in grams]) | Pureed fruit or vegetable volume | Total volume |
---|---|---|---|---|
1 | \( \raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$8$}\right. \) teaspoon | 0.25 (0.13) | \( \raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$2$}\right. \) teaspoon | \( \raisebox{1ex}{$3$}\!\left/ \!\raisebox{-1ex}{$4$}\right. \) teaspoon |
2 | \( \raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$4$}\right. \) teaspoon | 0.5 (0.25) | 1 teaspoon | \( 1\raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$4$}\right. \) teaspoons |
3 | \( \raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$2$}\right. \) teaspoon | 1.0 (0.5) | 2 teaspoons | \( 2\raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$2$}\right. \) teaspoons |
4 | 1 teaspoon | 2.0 (1.0) | 3 teaspoonsc | 4 teaspoons |
5 | 2 teaspoons | 4.0 (2.0) | 6 teaspoonsd | 8 teaspoons |
Total protein: 3.88 g |
Protocol instructions for options 1, 2, and 3
-
1.
Measure peanut butter, peanut flour, or peanut butter powder for dose 1.
-
2.
Prepare the first dose:
-
a.
If using option 1, add previously tolerated pureed fruit or vegetable to measured dose 1 peanut butter and stir until well blended. You can increase or reduce volume of puree to achieve desired consistency. Note: Increasing the volume may increase the difficulty of getting through the entire protocol with a young baby.
-
b.
If using option 2, slowly add hot water to measured dose 1 peanut butter and stir until peanut butter is dissolved, thinned, and well blended. Let the mixture cool. You can increase water volume (or add previously tolerated infant cereal) to achieve desired consistency.
-
c.
If using option 3, add previously tolerated pureed fruit or vegetable to measured dose 1 peanut flour or peanut butter powder and stir until well blended. You can increase or reduce volume of puree to achieve desired consistency. Note: Increasing the volume may increase the difficulty of getting through entire protocol with a young baby.
-
a.
-
3.
Label dose 1.
-
4.
Repeat steps 1 to 3 for the remaining doses 2 through 5, labeling each dose appropriately and before proceeding to the preparation of the next dose.
-
5.
Feed dose 1 to infant and observe for symptoms of reactivity for 15 to 20 min.
-
6.
If no symptoms appear, repeat with dose 2 and observe for 15 to 20 min.
-
7.
Continue in this manner with doses 3, 4, and 5.
Option 4: Bamba peanut snack (Osem, Israel)
Dose | Bamba, no. of sticks | Equivalent weight (peanut protein content [g])a | Volume of hot water (approximate, will need to be adjusted for each child) | Approximate final volume |
---|---|---|---|---|
1 | 1 stick | 0.81 (0.1) | \( \raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$2$}\right. \) teaspoon | \( \raisebox{1ex}{$3$}\!\left/ \!\raisebox{-1ex}{$4$}\right. \) teaspoons |
2 | 3 sticks | 2.43 (0.3) | 1 teaspoon | \( 1\raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$2$}\right. \) teaspoons |
3 | 5 sticks | 4.05 (0.5) | \( 1\raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$2$}\right. \) teaspoons | \( 2\raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$4$}\right. \) teaspoons |
4 | 10 sticks | 8.1 (1.0) | 3 teaspoons | 4 teaspoons |
5 | 21 sticks | 17.01 (2.0) | 6 teaspoons | \( 7\raisebox{1ex}{$1$}\!\left/ \!\raisebox{-1ex}{$2$}\right. \) teaspoons |
Total protein: 3.9 g |
Protocol instructions for option 4
-
1.
Count Bamba sticks for dose 1.
-
2.
Prepare the first dose by slowly adding hot water to measured Bamba and stirring until Bamba is dissolved, thinned, well blended, and cooled. You can increase water volume to achieve desired consistency. Note: Increasing the volume may increase the difficulty of getting through the entire protocol with a young baby.
-
3.
Label dose 1.
-
4.
Repeat steps 1 to 3 for the remaining doses 2 through 5, labeling each dose appropriately and before proceeding to the preparation of the next dose.
-
5.
Feed dose 1 to the infant and observe for symptoms of reactivity for 15 to 20 min.
-
6.
If no symptoms appear, repeat with dose 2 and observe for 15 to 20 min.
-
7.
Continue in this manner with doses 3, 4, and 5.
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Cite this article
Togias, A., Cooper, S.F., Acebal, M.L. et al. Addendum guidelines for the prevention of peanut allergy in the United States: Report of the National Institute of Allergy and Infectious Diseases–sponsored expert panel. World Allergy Organ J 10, 1 (2017). https://doi.org/10.1186/s40413-016-0137-9
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DOI: https://doi.org/10.1186/s40413-016-0137-9