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Review paper

The 2020 update on anaphylaxis in paediatric population

Izabela Tarczoń
1
,
Ewa Cichocka-Jarosz
2
,
Anna Knapp
2
,
Przemko Kwinta
2

1.
Przylądek Zdrowia, Krakow, Poland
2.
Department of Paediatrics, Jagiellonian University Medical College, Krakow, Poland
Adv Dermatol Allergol 2022; XXXIX (1): 13-19
DOI: https://doi.org/10.5114/ada.2021.103327
Online publish date: 2021/02/06
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Introduction

The goal of our work is to present a traditional review of recent publications on anaphylaxis in children, with a particular emphasis on changes in the newest recommendations on its diagnosis, novel diagnostic methods, verification of adrenaline-based standard treatment, and upcoming advances in prevention approaches. The reviewed and summarized information is to provide an update of practical guidelines for the medical personnel to improve the care of paediatric patients.

Definition and diagnosis

Anaphylaxis is the most severe form of an allergic reaction. Its diagnosis is purely clinical. The characteristic symptoms, which affect dermal, respiratory, cardiovascular or gastrointestinal systems, develop from minutes to a few hours after exposure to a known or potential trigger. There were several published anaphylaxis definitions [1–5], which share a common denominator of anaphylaxis life-threatening potential. The clinical criteria of anaphylaxis were first proposed at the second NIAID/FAAN Symposium in 2005 [1] (Table 1). Subsequently they were adopted by WAO [5] and EAACI [6] and have been used since then. They identify anaphylaxis with 95% sensitivity (95% CI: 85–99), but only 71% specificity (95% CI: 61–79), the positive predictive value equals 64% (95% CI: 53–73), while the negative predictive value equals 96% (95% CI: 89–99) [7]. Usefulness of the above criteria was the topic of a decade-long debate regarding their role in correct diagnosis and proper use of adrenaline. Therefore, the WAO Anaphylaxis Committee proposed a revised definition and clinical criteria of anaphylaxis in 2019 [8]. Accordingly, anaphylaxis is recognized as a serious systemic hypersensitivity reaction with usually rapid onset and potentially life-threatening compromise of breathing and/or the circulation, which may occur without typical skin features. New clinical criteria without previously obligatory dermal symptoms appear to facilitate the diagnosis of anaphylaxis and expedite introduction of adequate intervention. Currently there are two scenarios of anaphylaxis, which may present as 1) typical dermal features AND other significant symptoms from at least one other system OR 2) disorders of the respiratory system and/or cardiovascular system following exposure to a known or potential allergen (Table 1). The revised definition of anaphylaxis is included in an updated version (ICD-11) of the International Statistical Classification of Diseases and Related Health problems (ICD) of the World Health Organization (WHO) [9], which will become effective starting 1 January 2022 as indicated at the WHO webpage (http://www.who.int/classifications/icd/en/, retrieved 27 December 2020).

Epidemiology

The true global extent of anaphylaxis is hard to estimate [10]. In the European population, data have been mainly based on the European Anaphylaxis Registry (EAR) since 2014 [11]. The Registry currently contains 14706 cases, including 4256 of children and adolescents (The Anaphylaxis Registry ANAPHYLAXIE.net, https://www.anaphylaxie.net/en/#tabs-quote-1552943354-58-1, retrieved 22 December 2020). The previous data analyses originating from the EAR included a study of risk factors of biphasic anaphylaxis and epinephrine administration [12], phenotype and risk factors of venom-induced anaphylaxis (VIA) [13], anaphylaxis in children and adolescents [14], in the elderly [15], and a summary of preventive measures to avoid anaphylaxis [16]. A systematic review of the literature on the epidemiology of anaphylaxis in Europe shows the incidence rate between 1.5 and 7.9 in 100,000 person-years, and the lifetime prevalence of 0.3% (95% CI: 0.1–0.5) [3]. The American College of Allergy, Asthma and Immunology estimates the general incidence of anaphylaxis in the USA from 30–60 cases to 950 cases in 100,000 person-years with lifetime prevalence of 0.05–2.0% [4]. Anaphylaxis accounts for up to 0.26% of all hospital admissions [17]. The death rate remains constant at 0.5% to 1%. This is in contrast to Australia [18], where the number of fatal anaphylaxis cases due to all causes rose annually by 6.2% from 1997 to 2013, mainly because of adverse food reactions [18]. The latest published data on prevalence of anaphylaxis in Poland are based on the National Health Fund’s records for 2008–2015 and a 2015 questionnaire-based survey collected from 305 allergists [19]. In 2015, 3144 people received treatment for anaphylactic shock with an estimated prevalence rate of anaphylaxis equal to 8.2 per 100,000 with the highest prevalence rate in women aged 50–54 years (14.5 per 100,000). The most common causes of anaphylaxis included insect venom (41.4%), food (29.8%) and drugs (17.4%) [19].

Epidemiology in children

In children, the combined data from 29 studies indicated the anaphylaxis incidence rate between 1 and 761 per 100,000 person-years. The incidence rates varied in different continents: 2.3–761 per 100,000 person-years in Europe, 0.8–70 per 100,000 person-years in North America. Globally, prevalence estimates for anaphylaxis in the paediatric population ranged from 0.04% to 1.8% [20]. In childhood until the age of 10, anaphylaxis occurs more often in boys than girls [21], probably because of the higher incidence of food allergy in the former [22]. In the prepubescent age, the rates of both severity [23] and fatality [24] are comparable in both genders. Over 13 years of age, there is a gradual increase in the incidence of severe anaphylaxis in males, in particular in venom [25] or drug-induced anaphylaxis [26]. The majority of the new cases is diagnosed in children under the age of 4 [3]. Overall, the highest incidence rate is for the food-induced anaphylaxis (1.4–76.7 per 100,000 person-years with the prevalence estimates between 0.3 and 1.2% [20]. The hospitalization rate due to anaphylaxis among infants and toddlers was constant between 2006 and 2015 in the United States. However, it increased significantly in the older children (age > 3 < 18 years) [27]. The incidence rate of anaphylaxis induced by a specific food allergen (peanuts, nuts, fruit, milk, seafood, eggs) in children was between 0.1 and 9.7 per 100,000 person-years, which was higher than the one for venom, anaesthesia or serum triggers [20]. Even though the highest rate of food-induced anaphylaxis was observed in the youngest age group, the latest epidemiological data from the United States [28], Italy [29], and Australia [30] showed an increased number of hospitalized older children due to food-induced anaphylaxis, especially among the 13–17-year-olds. It is especially worrisome since the estimated risk of morbidity and mortality due to food-induced anaphylaxis is greater in the adolescents compared to other age groups [21].

Triggers

Worldwide, the most common triggers of anaphylaxis are food, drugs and venom, though geographic differences exist due to nutritional habits typical in the particular region [31]. In the European paediatric population foods (66%) predominate, then venoms (19%) and drugs (5%) as demonstrated by the EAR between 2007 and 2015 [14]. The type of triggers changes with age. Foods are the most common allergens in children under 6 years, with milk and hen egg white prevailing in the infants younger than 2 years. Anaphylactic reactions to hazelnuts and cashews are typical for the pre-school group, while peanuts trigger anaphylaxis in populations of any age. According to EAR, venoms (wasps more often than bees) are the leading cause of anaphylaxis in school-age children and teenagers, whereas medications (analgesics and antibiotics) result in anaphylaxis mostly in the latter age group [14]. The most common factors that necessitate hospital re-admissions due to anaphylaxis include food allergens, such as seeds and tree nuts, age groups of 6–12 and 13–17, and weekend days [32]. The fatal anaphylaxis in children is most often caused by drugs, foods and venoms [21, 22, 30]. The common food triggers include peanuts and tree nuts, which predominate in the general paediatric population [25], and cow milk typical for the youngest children [22]. Some food triggers inducing fatal anaphylaxis are region specific, such as seafood in Australia [30].
Another difficult issue is idiopathic anaphylaxis (IA) for which a trigger cannot be identified. It is less common in children compared to the adult population. The Network for Online Registration of Anaphylaxis (NORA) in Europe reports a surprisingly low number of IA cases (6.5%), but the data collection might have been somehow affected by the particular profile of that network highly specialized in allergy diagnosis [11]. Contrary to NORA results, in the review of 40 paediatric anaphylactic cases treated in an emergency department (ED) in the United States in the year 2014, 17.5% of cases were classified as IA [33]. Evaluation of the potential triggers in idiopathic anaphylaxis has improved due to introduction of a component-resolved diagnostics of hidden allergens found in food ingredients such as meal flavours (e.g. celery, mustard, herbs, spices, fenugreek in particular, legumes – especially lupin), food additives (natural food colourings such as carmine, or preservative sodium metabisulphite, which is present in white and rose wine or light coloured fruit juices), foods eaten for health reasons (quinoa, buckwheat, millet, amaranth) or alpha-gal substances (delayed reactions after consumption of red meat) [34]. CRD allows to determine causative agents in anaphylaxis cases which previously were considered idiopathic even in 1/5 of them [35].

Phenotypes

The symptoms of anaphylaxis may vary in different patients, and even in subsequent episodes in the same person. Phenotypes of anaphylaxis, similarly to phenotypes of asthma, may alter according to its trigger. Typically, food allergy is associated with vomiting, nausea and gastrointestinal symptoms [36], while allergy to drugs and insect venom results in hypotension regardless of age [13, 37]. A report based on the Beijing Pharmacovigilance Database (2004–2014) showed that children of 0–5 years were more likely to develop cyanosis than children of 13–17 years (OR = 5.14, 95% CI: 1.74–15.20), children of 13–17 years were more likely to develop hypotension than children of 6–12 years (OR = 11.79, 95% CI: 2.28–60.87), and to manifest both neurological symptoms (OR = 3.56, 95% CI: 1.26–10.08) and severe anaphylaxis compared to the children of 0–5 years (OR = 15.46, 95% CI: 1.85–129.33) [38]. The EAR case control study of the VIA (n = 3,612, including 20% of patients younger than 22 years) and non-VIA (n = 3,605) patients matched for age and gender demonstrated that hypotension was a predominant manifestation in any age VIA group when compared to either other non-VIA triggers or symptoms of different body systems [13]. There were episodic incidents of drug-induced perioperative anaphylaxis reported in children, which compromised a total of 29 cases from the UK, USA and France (average age: 11 years) during a 10-year period [39]. The severe symptoms occurred in 86% of the group, and 14% developed circulatory failure. The first symptom was hypotension (59%), then tachycardia and bronchospasm [39]. Another study based on the data from the Paediatric Research Consortium reported 54 cases of drug-triggered reactions (incidence 1 : 4219) out of 227,833 allergic cases [40]. There were 6 cases consistent with anaphylaxis diagnosis (incidence 1 : 37972). The following sedative and/or analgesic medications showed a significant association with development of allergic reactions: midazolam (OR = 2.2; 95% CI: 1.2–3.9), ketamine (OR = 3.8; 95% CI: 2.1–7.1), methohexital (OR = 48.8, 95% CI: 14.9–159.9), and morphine (OR = 4.4; 95% CI: 1.04–18.2) [40]. There were no mortalities. The most recently described troubling phenomenon is a potential transfer of atopy and an associated risk of anaphylaxis during transplant surgeries [41].

Risk factors

There is a number of recent reports on the risk factors of severe anaphylaxis. A Spanish study defined severe anaphylaxis as a clinical condition that fulfilled one or more of the following criteria: administration of two or more doses of epinephrine, clinically important biphasic reaction, endotracheal intubation, intensive care unit admission, and/or death. Out of 453 episodes of anaphylaxis, 61 were classified as severe anaphylaxis (13.5%, 95% CI: 10.6–16.9): 53 patients (11.7%) required more than one dose of epinephrine, 14 (3.1%) developed clinically important biphasic reactions, there were 2 (0.4%) intubations in the ED, and 6 (1.3%) admissions to the intensive care unit, with no fatalities reported. The identified independent risk factors for severe anaphylaxis included history of asthma (OR = 2.70, 95% CI: 1.43–5.11), rapid onset of symptoms less than 5 minutes after the allergen exposure (OR = 2.62, 95% CI: 1.41–4.87), unwell appearance (OR = 2.97, 95% CI: 1.38–6.40), tachycardia (OR = 2.34, 95% CI: 1.19–4.96), and hypotension (OR = 3.72, 95% CI: 1.09–12.76) [42]. Yet another study did not confirm the role of asthma in severity of anaphylaxis [43], defined by a specific clinical presentation or need for therapy of respiratory failure. The presented multivariate analyses showed that children with a history of asthma were not more likely to have severe anaphylactic reactions (OR = 0.97; 95% CI: 0.67–1.39) [43].

Biomarkers

Anaphylaxis remains a clinical diagnosis, and bio­markers have no role in acute management. However, they are crucial in the specialist allergy evaluation to confirm the diagnosis and support differential diagnosis. Tryptase is the most useful one, also in the post-mortem evaluation [44, 45]. Even though an elevated tryptase level has a high (93%) positive predictive value, its negative predictive value is only 17% [46]. It is best to collect a blood sample 1–2 hours from the onset of symptoms, and freeze obtained serum until later for further studies [47]. Analysis of tryptase concentration during anaphylaxis compared to its baseline level (> 24 hours since resolution of the symptoms) is currently the most recommended and widely available marker of anaphylaxis. The increased concentration of tryptase that remains within the reference range (0–11.4 µg/l), but exceeds the value calculated with the formula (1.2 × baseline serum tryptase concentration + 2), confirms activation of the mastocytes during the hypersensitivity reaction [48].

Treatment and prevention

Adrenaline remains the principal and the first-line treatment recommended intervention in anaphylaxis [12]. Its rapid and timely administration is critical to adequately manage severe symptoms and to avoid a biphasic reaction [49]. When applied within 30 minutes from the onset of the first symptoms, it decreases the risk of biphasic reaction by 23% [50]. Undiluted solution 1 : 1000 (1 mg/ml) of adrenaline is administered intramuscularly at a dose of 0.01 mg/kg (maximum dose 0.5 mg in adults, and 0.3 mg in children) in the anterolateral side of the thigh [1]. Regardless of the site [51], it is recommended to deliver adrenaline intramuscularly instead of subcutaneously since the former resulted in a higher plasma concentration peak (2136 ±351 vs. 1802 ±214 pg/ml) and faster onset of action (8 ±2 vs. 34 ±14 minutes) [52]. When needed, adrenaline injections are repeated every 5 to 15 minutes usually within initial two hours following the first dose [5]. Therefore a 4-hour long observation is optimal for monitoring children with anaphylaxis [53]. In the medical settings, the first adrenaline dose is followed by fast infusion of the intravenous fluids such as 0.9% sodium chloride at 10–20 ml/kg over 10 minutes in case of hypotension unresponsive to intramuscular adrenaline, oxygen supplementation, comfort position of the child with the lower extremities elevated for effective cardiac output. The upright position during anaphylaxis is associated with a greater fatality risk resulting from the empty right ventricle syndrome [54]. Antihistamines and glucocorticosteroids (GCS) may be considered in anaphylaxis management only as the second-line medications [55]. The previous studies failed to demonstrate their ability to prevent biphasic reactions. In fact, the latest data indicated that systemic GCS in anaphylaxis might even increase the risk of biphasic reaction in children [49]. The antihistamines are justified only as medications against bothersome symptoms of urticaria and pruritus. It is crucial that use of either antihistamines or GCS does not delay adrenaline administration in anaphylaxis. In the latest European systematic literature review of 50 studies that included a total of 18,449 participants, adrenaline was verified to be the only disease-modifying intervention in anaphylaxis [56]. Unfortunately, both medical personnel and parents hesitate to use adrenaline as the primary intervention in anaphylaxis in children despite their prior training and data showing a reduced risk of hospitalization, including the risk of stay in the ICU after pre-hospital adrenaline injection [57, 58]. Introduction of new modified autoinjectors might improve the above statistics because they can facilitate appropriate adrenaline administration. Similarly, face–to-face training regardless of its duration may improve knowledge about management in anaphylaxis. There is also some beneficial effect of electronic learning modules [59] and multidisciplinary education programs [60].
Autoinjectors, currently available in Europe include 3 adrenaline doses: 0.15 mg (EpiPen Junior, Emerade, Altellus, Anapen Junior), 0.3 mg (EpiPen Senior, Emerade, Altellus, Anapen Senior) and 0.5 mg (Emerade). In Poland, the following are available: EpiPen 0.15 and 0.30 mg and a pre-filled syringe with adrenaline WZF 0.15 mg (registered, but not yet available in the market) and 0.3 mg. In the USA, in addition to EpiPen autoinjectors, there are also Adrenaclick and Auvi-Q. In 2020, Auvi-Q was the first one in the world to introduce a nominal dose of 0.1 mg dedicated for children with a body weight of 7.5–15 kg [61]. According to EMA and EAACI guidelines, all the patients with a risk of anaphylaxis are recommended to always have two packs of adrenaline, especially during the COVID-19 pandemic [62, 63]. The secondary prevention, in addition to prevention of exposure to the anaphylaxis trigger, includes allergen immunotherapy (Hymenoptera venom), and desensitization to certain medications (acetylsalicylic acid, chemotherapeutic agents, monoclonal antibodies, antibiotics, hormones) according to predefined protocols when indicated for essential therapy [13, 38]. The options of prevention to food-induced anaphylaxis were further expanded in January 2020 when the FDA approved Aimmune’s Palforzia, a peanut allergen in powder form for oral immunotherapy (OIT). The medication is indicated for the patients aged 7–14 years with a clinically confirmed allergy to peanuts. There is a pending FDA decision regarding Viaskin Peanut for epicutaneous immunotherapy for the same indications as above. The results of phase III clinical trials of that medication are very encouraging [64].
The way to promote immunotolerance to various food allergens is their use in thermally processed form, such as cooking or baking for milk, baking or pasteurization for eggs [65]. Desensitization in allergy to wheat flour is carried out with a ready-made commercial formulation [66, 67], while treatment in red meat allergy should start with 1% diluted boiled beef extract and eventually cooked beef [68]. There are numerous algorithms to help with a gradual dose increase of the above products. Low-dose OIT is to promote tolerance to the amount that may occur due to accidental food contamination. It corresponds to 1/32 of hen’s egg, 3 ml of cow’s milk, 50–75 mg of wheat protein and 125–300 mg of peanut protein, which is safe and useful in the management of children with food-induced anaphylaxis. The good age to start OIT would be approximately 5 years [69].

Conclusions

The current epidemiological data, despite apparent differences in incidence and prevalence, indicate an increase in anaphylaxis cases especially in the developed countries. The upcoming ICD-11 classification will enable more accurate reporting of cases and probably improve the quality of population data. At the same time, simplifying anaphylaxis criteria should facilitate its diagnosis in daily practice, hence enable faster administration of adrenaline, the first-line intervention in anaphylaxis. Unfortunately, adrenaline is still not used in children as often as needed by both medical personnel and parents. Identification of the potential causative factor is now possible thanks to the modern component-resolved diagnostics, which starts to play a major role in the secondary prophylaxis. Such prophylaxis is based not only on the prevention of contacts with the noxious allergen, but also development of broadly-defined specific immunotolerance, which should significantly improve quality of life of the patient who had recovered from the anaphylactic shock in the past.

Conflict of interest

The authors declare no conflict of interest.
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