key: cord-0952913-3hxe8lxc
authors: Rose, Klaus; Grant-Kels, Jane M.; Ettienne, Earl B.; Tanjinatus, Oishi; Striano, Pasquale; Neubauer, David
title: COVID-19 and Treatment and Immunization of Children—The Time to Redefine Pediatric Age Groups is Here
date: 2021-04-29
journal: Rambam Maimonides Med J
DOI: 10.5041/rmmj.10433
sha: f8976152be5225d2fb8b4f4bf6cdfb501fad24ab
doc_id: 952913
cord_uid: 3hxe8lxc

Children are infected with coronavirus disease 2019 (COVID-19) as often as adults, but with fewer symptoms. During the first wave of the COVID-19 pandemic, multisystem inflammatory syndrome (MIS) in children (MIS-C), with symptoms similar to Kawasaki syndrome, was described in young minors testing positive for COVID-19. The United States (US) Centers for Disease Control and Prevention (CDC) defined MIS-C as occurring in <21-year-olds, triggering hundreds of PubMed-listed papers. However, postpubertal adolescents are no longer children biologically; the term MIS-C is misleading. Furthermore, MIS also occurs in adults, termed MIS-A by the CDC. Acute and delayed inflammations can be triggered by COVID-19. The 18th birthday is an administrative not a biological age limit, whereas the body matures slowly during puberty. This blur in defining children leads to confusion regarding MIS-C/MIS-A. United States and European Union (EU) drug approval is handled separately for children, defined as <18-year-olds, ascribing non-existent physical characteristics up to the 18th birthday. This blur between the administrative and the physiological meanings for the term child is causing flawed demands for pediatric studies in all drugs and vaccines, including those against COVID-19. Effective treatment of all conditions, including COVID-19, should be based on actual physiological need. Now, the flawed definition for children in the development of drugs and vaccines and their approval is negatively impacting prevention and treatment of COVID-19 in minors. This review reveals the necessity for redefining pediatric age groups to rapidly establish recommendations for optimal prevention and treatment in minors.

The severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), which causes coronavirus disease 2019 (COVID- 19) , has led to havoc worldwide. The most important single prognostic factor is patient age. 1,2 Initially, COVID-19 was thought not to affect children. However, it is now known that children are also easily infected, but most have no or few symptoms. Since most infected minors neither cough nor sneeze, their role as vectors in spreading the disease is limited. However, their role as a potential reservoir of the virus should be kept in mind. 3, 4 A multisystem inflammatory syndrome (MIS) in children (MIS-C) was described during the first wave of the COVID-19 pandemic, 5, 6 with some similarities to Kawasaki syndrome. 2, 7 Subsequently, the United States (US) Centers for Disease Control and Prevention (CDC) published a Health Advisory, 8 defining MIS-C as occurring in patients <21 years old with fever, laboratory evidence of inflammation, illness requiring hospitalization, multisystem (2 organs) involvement, no alternative plausible diagnoses, and current or recent COVID-19 infection or COVID-19 exposure. The American Academy of Pediatrics (AAP) issued an interim guidance, listing potential complications and manifestations including Kawasaki disease-like features, toxic shock syndrome-like features, cytokine storm/macrophage activation or hyperinflammatory features, and more. 9 The CDC health advisory triggered many PubMed-listed papers. As of January 1, 2021, the search terms "multisystem inflammatory syndrome COVID children" revealed 391 publications; the search terms "multisystem inflammatory syndrome COVID" 434 publications; and the search term "MIS-C" 204 publications.

Is the term MIS-C appropriate? The CDC health advisory 8 included four references: a CDC description of Kawasaki disease 7 plus three published papers. 5, 6, 10 Kawasaki disease primarily affects children <5 years old. 7 The Royal College of Paediatrics and Child Health (RCPCH) and Riphagen et al. provide guidance on diagnosis and treatment. 5 ,10 Verdoni et al. had reported an increased number of children in an Italian pediatric hospital. 6 A UK national consensus paper advised how to manage MIS-C. 11

The first MIS-C reports assumed a pediatric challenge, 5,6,10 and both the US CDC and the AAP defined MIS-C as occurring in patients <21 years old. 8, 9 Furthermore, the AAP defines the pediatric population as 21 years old, and even older for those with special needs. 12 Although this is reasonable for administrative purposes, in reality 15-or 20-yearolds are physically no longer children. The UK authors do not define children. 10,11 For them, a child would appear to be somebody seen by a pediatrician, which in our view reflects a circular and nonscientific perspective.

The term "child" has different meanings depending on the used context. Administratively and legally, a child is a minor. However, the body matures before administrative adulthood. 13 In the past, minors became adults through religious and other traditional rites that ceremoniously continue today in some groups. Today, a child becomes an adult by passing an age limit. This age limit has been applied to scientific studies despite the fact that onset and completion of puberty has been noted to be accelerated in the last decades. 14 Adults have been reported to experience MIS as a result of COVID-19 infection. In adults it is now referred to as MIS-A. [15] [16] [17] This begs the question: If MIS can occur in both children and adults, is it appropriate to differentiate between MIS-C and MIS-A? Furthermore, if MIS-C and MIS-A have the same symptoms, is there a justification for separate clinical trials in MIS-C?

This question is not theoretical, but has practical implications. For example, one study compared the antibodies of COVID-19 patients with those of MIS-C patients, claiming they were different. 18 The authors compared three groups: Group 1, recovered patients after mild COVID-19 respiratory disease; Group 2, hospitalized severe COVID-19 patients; and Group 3, children hospitalized with MIS-C. The ages of the groups are presented in Table 1 . Note the overlapping age ranges for Groups 2 and 3; however, the upper age limit of Group 3 was the age of patients administratively allowed on a pediatric ward. Obviously, some adolescents in Group 2 were treated in adult wards. Weisberg et al. and most others use MIS-C uncritically. 18 Viral infections can induce various autoimmune disorders, including secondary hemophagocytic lymphohistiocytosis and macrophage activation syndrome. 16, 19, 20 Multisystem inflammatory syndrome might be a macrophage activation syndrome. 16, 20 The immune responses to MIS may be related to a direct infection, an uncontrolled autoimmune response, or both. 19 Many MIS-C patients were and are physiologically no longer children. Hence, there should be no differentiation between MIS-C and MIS-A: the term should be MIS only. This paper discusses the implications of differentiating between pediatric and adult designations with a focus first on COVID-19 and then on drug development and drug approval in general.

Most COVID-19 and MIS-C papers share the presentation and course of their patients and advise on treatment. This was how pediatrics and all clinical disciplines historically emerged and evolved: trying to help by whatever was at hand. 21 For example, during the thalidomide disaster pregnant women took thalidomide for nausea and morning sickness; this led to serious defects to their child, with the most common defect being malformations of arms and legs (phocomelia). Reacting to this, in 1962 the US introduced the requirement to prove the effectiveness and safety of drugs before approval, a principle eventually accepted worldwide. 22 The cornerstone of this proof is clinical studies. A somewhat later learning was that young persons differ from adults. Pediatricians had used formulas and tables for dosing, which usually worked fine. However, at very young ages, absorption, distribution, metabolism, and excretion are very different; formulas and tables could recommend doses that were too high or too low. 23, 24 As a protection against damaging lawsuits in the litigious US, companies began adding pediatric warnings to drug labeling as of 1962. The first chairman of the AAP committee on drugs claimed this disadvantaged children in drug treatment, making them "therapeutic orphans." 25 The AAP and the US Food and Drug Administration (FDA) took up this concept. In 1979, the FDA defined "children" as <17 years old. 26 Since 1997, US law offers voluntary financial rewards for companies performing pediatric studies. Pediatric legislations became permanent in the US in 2012. The EU has been demanding, since 2007, that all new drugs that might later be used in minors have a pediatric investigation plan (PIP), including biologics, vaccines, and drugs that target rare diseases. 24, 26 Today, both the FDA and the European Medicines Agency (EMA) use the 18th birthday to distinguish adults from "children." Note the overlapping age ranges for Groups 2 and 3.

The discussion about on-label versus off-label treatment is old, broad, and keeps US courts busy. Modern labeling has its merits. There are also good arguments against banning scientific discussion of off-label use. Once approved, drugs may be prescribed for any purpose. A physician's failure to appropriately prescribe off-label would inhibit good care and could be considered potential medical malpractice. 27 Imposing a separate pediatric approval had a negative impact on reasonable on-label/offlabel use in the administratively labeled pediatric population. It is certainly justified in preterm newborns, but not in all children.

The demand for separate testing of drugs in children appears noble at first. Nonetheless, there is a catch: the semantic blur between the different meanings of the term "child." Minors become bodily mature long before the 18th birthday. 23 The children-are-therapeutic-orphans concept turns the real dangers of effective drugs in preterm newborns into alleged dangers for all drugs in all "children." Relevant aspects of pediatric research have been moved from studies with therapeutic intent to studies aiming at acquiring pediatric labeling. 24, 28 Yet historically, the entire pediatric discipline developed "off-label" decades before this term emerged in 1988. 29 As a result, the term MIS-C has been flawed from the beginning. The official CDC warning 8 resulted in its worldwide adoption, triggering several hundred publications that further accentuate this weakness of modern medicine. Physicians are good at caring for patients within the existing framework. Hence, if an authority uses the term MIS-C, that term is generally accepted. The COVID-19 pandemic reveals how a flawed term is accepted, repeated worldwide, ultimately impacting the effectiveness of patient care.

The FDA and the EMA jointly published a document explaining their pediatric requirements for companies that develop vaccines or treatments against COVID-19. 30 The EMA demands PIPs for virtually all new drugs, vaccines, and biologics. Up until 2017, the FDA could not mandate pediatric studies for drugs targeting a rare disease. However, since 2020, it requires pediatric studies for new anticancer drugs in patients 11 years old. 31 The FDA also demands that companies submit an initial pediatric study plan (iPSP). 24, 30 

During the COVID-19 pandemic, the FDA authorized remdesivir for emergency treatment of patients 12 years old, weighing 40 kg. 32, 33 The EMA issued a conditional marketing authorization for the same patient group. 34 In October 2020, the FDA expanded this emergency authorization for hospitalized children weighing 3.5 kg, giving dosing recommendations based on the patient's body weight. 35 The pediatric studies required by the remdesivir PIP are listed in Box 1. 36 There is no known age limit that would require a fundamentally different treatment of young COVID-19 patients compared to the treatment of adults. Antivirals, monoclonal antibodies, and receptor blockers work the same before and after a person's 18th birthday. For pre-adolescent children, dosing recommendations are needed, such as the ones issued by the FDA. 35 However, all PIP-required pediatric COVID-19 studies follow the same rigid PIP scheme used by the EMA in all clinical areas. 24 Furthermore, treating a MIS patient with remdes-

1. Open-label single-arm pharmacokinetics, tolerability, and efficacy study in hospitalized children from 32 weeks' gestational age to 17 years with confirmed COVID-19

2. Population pharmacokinetics modeling and simulation study on pediatric dose/posology in pediatric subjects 32 weeks' gestational age to 17 years to achieve systemic exposures equivalent to those in adults 3. Extrapolation study on efficacy and safety of remdesivir from adults to children 32 weeks' gestational age to 17 years with confirmed COVID-19

EMA, European Medicines Agency; PIP, pediatric investigation plan.

ivir is medically contraindicated, since there is no longer direct inflammation by the virus; rather, the immune system is overreacting. 2

The FDA emergency approval of the first vaccine (BNT162b2) was for patients 16 years old, 37 the second (Moderna) for those 18 years old. 38 More vaccines are under development. In general, vaccines have helped to contain most viral infectious diseases, although there is no effective vaccine yet against human immunodeficiency virus. Clearly, minors will eventually need to be vaccinated against COVID-19. There is no scientifically valid reason to limit the age for administering the first two approved COVID-19 vaccines. A 15-year-old will not react differently from an 18-year-old. The decision to define the lower age limit of both pivotal vaccination studies was made by the developers.

Box 2 shows the pediatric studies demanded in the EMA PIP for BNT162b2. 39 All these studies were demanded in children aged from birth to 17 years. However, while 15-year-olds are administratively still children, their bodies are not. Once a compound is known to be effective in humans, double-blind placebo-controlled studies (points 2 and 3 in Box 2) are not necessary and therefore unethical. Dose-finding studies do not need to be double-blinded. The PIP-demanded studies (Box 2) lack medical necessity and represent a waste of money and time.

The FDA/EMA-employed authors and their allies in academic pediatric research and industry speak of therapeutic tragedies in pediatric patients, 40 drug development in pediatric patients, 41, 42 or developing medicines for children, 43 assuming that all children of all ages are in danger of toxicities when treated with drugs. Such dangers exist in preterm newborns, and to a lesser degree in mature newborns, but clearly not in all children-particularly if "children" are defined as being up to the age of 18 or 21.

The question as to whether or not PIPs or iPSPs make sense for the COVID-19 pandemic was not even addressed by the FDA or the EMA. Instead, the need for pediatric drug development was assumed. However, the EMA emphasizes that it offers accelerated procedures for PIPs and related issues for COVID-19 treatments and vaccines. 44 While the usual procedure to negotiate a PIP takes about a year, 24 this procedure is accelerated for drugs and vaccines against COVID-19. Also, the FDA will not approve drugs and vaccines for COVID-19 and other diseases without separate "pediatric" data. Table 2 shows industry-sponsored clinical studies for prevention and treatment of COVID-19. Most Table 3 lists the ongoing clinical studies for MIS-C related to COVID-19 that were found in a PubMed search. Most of these studies are observational or diagnostic, but #1 and #5 offer treatment with mesenchymal stroma cells; #6 plans for "children" aged 18-20 years; and #1 is for "children" ranging from 2 months to 17 years. Again, these inclusion criteria are neither based on biological/physical definitions, nor are they consistent.

The terms MIS-C and MIS-A mirror the artificial division of humans into two populations: adults and children. For legal and/or administrative purposes, classifications into age groups are justified. However, when treating patients, the diagnoses should be the same for identical conditions/syndromes pre- senting with the same symptoms and diagnostic tests, with the same treatments being offered. A diagnosis should not be one thing the day before a specific birthday, and something different the day after-nor should the treatments differ.

From the beginning, the AAP guidelines on pediatric studies have oscillated between the legal and the physiological meanings of the term "child." 45, 46 As stated in the introduction, the AAP defines the pediatric population as 21 years old, and even allows for a higher age limit for patients with special needs. 12 This is acceptable for administrative purposes. The flawed FDA definition of a pediatric population as <17 years originated in 1979. 47 Pediatric drug development 39 was established in a first US law in 1997, which rewarded separate pediatric studies by patent extension. 24, 26 This was expanded upon by the EU, which has demanded PIPs for new drugs, vaccines, and biologics that might later be used in minors since 2007. Today, both the FDA and the EMA use the age limit of 18 years. 24, 48 The semantic confusion regarding MIS-C/MIS-A has a dark side. Since 1974, the AAP has justified separate pediatric studies, characterizing them as a "moral imperative." 43, 44 The FDA's demands for questionable pediatric cancer studies in patients 21 years old should be seen in this context. [48] [49] [50] [51] Once puberty is completed, the body is mature. 13, 14 Therefore, dosing recommendations should be based on modeling and simulation calculations, confirmed in an opportunistic framework not requiring complex logistics, and without exposing patients to separate exaggerated studies. 52, 53 In this context, the term "opportunistic" describes the opportunity to gather additional data when a minor needs to be treated with an innovative drug that is not yet formally approved in this age group.

Another disease that exemplifies this issue is juvenile idiopathic arthritis (JIA), a name that suggests juvenile patients. Historically, arthritides in young patients were first investigated by pediatric rheumatologists. 54 First introduced in 1995, JIA was an umbrella term for diseases that began before the 16th birthday. 55 Before 1995, the terms juvenile rheumatoid arthritis and juvenile chronic arthritis were used. Notably, several diseases under today's JIA umbrella affect adults under different names: adult-onset Still's disease (AOSD) and systemic JIA (sJIA) are the same, as are rheumatoid factorpositive (RF+) polyarthritis (a JIA category) and RF+ rheumatoid arthritis; and enthesitis-related arthritis (another JIA category) and adult undifferentiated spondyloarthritis (SpA). 56, 57 Investigations for arthritides in young patients began when infectious diseases had been pushed back and a focus on rare diseases in young patients emerged, including cancer and arthritis in minors. 24, 50, 51 However, diseases do not change at the 16th or 18th birthday. 58 Today there is a "Center for Adults with Pediatric Rheumatic Illness (CAPRI)." 59 The basic assumption behind pediatric drug development is that children and their diseases are fundamentally different from adults, 60 requiring separate pediatric studies. Today, we know how the fetus develops in the mother, 61 and how children grow from birth into adulthood. 13, 14, 23 While the APP and other organizations recognize the physiological differences between infants, "children," and "adolescents," the administrative age limit across the board remains the determining factor for all "pediatric" studies.

At the interface of drug development and drug approval a coalition has emerged that refuses to apply the learnings of developmental pharmacology. Instead, it demands separate pediatric studies. This coalition is composed of academic researchers, regulatory authorities, pharmaceutical companies, and clinical trials organizations. This requirement has evolved into a business opportunity providing funds for pediatric research. 24, 48, 50 Some clinicians have challenged this situation. 62, 63 In epilepsy, the FDA today accepts "extrapolation" of efficacy from adults down to 2 years of age. 64 But in this context, the term "extrapolation" is flawed. Dosing needs extrapolation; efficacy does not. Antiepileptic drugs work in both adults and children. 65 Other clinical areas still use "pediatric," e.g. the International Pediatric Multiple Sclerosis Study Group (IPMSSG). 66 While the term "pediatric" is incorrect for adolescents, the IPMSSG speaks out against "pediatric" placebo-controlled studies. 24, 67 Most regulatory "pediatric" studies lack medical sense. Many cause harm by withholding effective treatment or by exposing patients to treatment below standard-of-care. 24, 48, 49, 62 Together, regulatory pediatric studies amount to abuse in medical research that numerically exceeds the abuses reported by Beecher, 68 and the Tuskegee study. 24, 69, 70 The FDA is gradually stepping back from demanding separate pediatric studies, 24, 46, 49, 62 but the EMA is expanding on their demands, now requiring PIPs for drugs against liver carcinoma, kidney carcinoma, coronary atherosclerosis, Parkinson's disease, Huntington's chorea, and amyotrophic lateral sclerosis. 71 These diseases occur occasionally before the 18th birthday, but are not, by any sense of the word, pediatric.

The FDA and the EMA maintain the childrenare-therapeutic-orphans concept. 29 For remdesivir pediatric dosing, the FDA has applied science, 34 while the EMA is caught in a dogmatic labyrinth, demanding pointless pediatric studies (Tables 3 and 4 ).

Pediatric studies recruit worldwide, including in the US. Minors in the US will be threatened by EMAmandated pediatric COVID-19 studies once these begin. As long as Institutional Review Boards (IRBs) and ethics committees (ECs) do not recognize the dangers of pediatric studies, the temptation for medical doctors and research institutions to participate in international pediatric studies will continue. This is not the first time that mainstream science has supported a flawed concept. Sometimes, it takes decades or even centuries to change prevalent thinking. 72 Off-label treatment will always be required when treating newly emerging diseases. The current COVID-19 pandemic will not be the world's last pandemic.

It is time for IRBs and ECs to recognize the danger of many pediatric studies, not only for patients, but also as they relate to public trust in medicine, research, and authorities. Pediatric research needs to return to the roots of medical care. What began as a flawed interpretation of legal warnings-and the resulting pediatric labeling-became institutionalized by US pediatric laws, was expanded upon by the EU, and is now maintained due to conflicts of interest. This situation will not disappear overnight.

Nevertheless, there are ways to get things started in the right direction. The COVID-19 pandemic presents an optimal opportunity for beginning. To start with, the CDC should retract and correct its MIS-C warning. 8 Questionable pediatric studies should be suspended by IRBs/ECs, and newly submitted ones should be rejected. Journals should no longer accept the terms MIS-C and MIS-A in the titles or keywords of publications. Ultimately, US and EU pediatric laws need revision. Pediatricians and general practitioners should work with their professional organizations to achieve this goal. A concerted effort by healthcare practitioners who fight daily for their patients' lives can have a powerful impact to achieve these goals. 

Pathologic features of COVID-19: a concise review

COVID-19 and multisystem inflammatory syndrome in children and adolescents

Coronavirus infections in children including COVID-19: an overview of the epidemiology, clinical features, diagnosis, treatment and prevention options in children

COVID-19 infection in children and adolescents

Hyperinflammatory shock in children during COVID-19 pandemic

An outbreak of severe Kawasaki-like disease at the Italian epicentre of the SARS-CoV-2 epidemic: an observational cohort study

Centers for Disease Control and Prevention (CDC) website. 2020. Available at

Emergency preparedness and response: HAN00432. Health Alert Network (HAN), Official CDC Health Advisory

Multisystem inflammatory syndrome in children (MIS-C) interim guidance. AAP website. 2020; Last updated February 10

Indicators of biological maturation and secular changes in biological maturation

The mysterious trend in American heights in the 20th century

Case series of multisystem inflammatory syndrome in adults associated with SARS-CoV-2 infection -United Kingdom and United States

COVID-19 and multisystem inflammatory syndrome, or is it mast cell activation syndrome?

Multisystem inflammatory syndrome in adults. Centers for Disease Control and Prevention (CDC) website

Antibody responses to SARS-CoV2 are distinct in children with MIS-C compared to adults with COVID-19

COVID-19: infection or autoimmunity

Complex immune dysregulation in COVID-19 patients with severe respiratory failure

Nurturing Children. A History of Pediatrics

Drug Benefits and Risks: International Textbook of Clinical Pharmacology

Developmental pharmacology --drug disposition, action, and therapy in infants and children

Considering the Patient in Pediatric Drug Development. How Good Intentions Turned into Harm

Therapeutic orphans

Pediatric regulatory initiatives

A Historical Perspective on Off-label Medicine: from Regulation, Promotion, and the First Amendment to the Next Frontiers

The impact of off-label, compassionate and unlicensed use on health care laws in preselected countries

FDA / EMA common commentary on submitting an initial pediatric study plan (iPSP) and paediatric investigation plan (PIP) for the prevention and treatment of COVID-19

FDARA 2017 and the RACE for Children Act: Implications for pediatric cancer drug development

Highlights of Prescribing Information: VEKLURY® (remdesivir) prescribing information

Remdesivir: A review of its discovery and development leading to emergency use authorization for treatment of COVID-19

Emergency Use Authorization (EUA) of Veklury ® (Remdesivir) for Hospitalized Pediatric Patients Weighing 3.5 kg to Less Than 40 kg or Hospitalized Pediatric Patients Less Than 12 Years of Age Weighing at Least 3.5 kg. Last updated

EMA/269449/2020. European Medicines Agency decision, P/0201/2020

Emergency Use Authorization (EUA) of the Pfizer-BioNTech COVID-19 Vaccine to Prevent Coronavirus Disease

Emergency Use Authorization (EUA) of the Moderna COVID-19 Vaccine to Prevent Coronavirus Disease

European Medicines Agency decision, P/0480/2020

The need for pediatric drug development

Paediatric extrapolation: a necessary paradigm shift

Enhancing the pediatric drug development framework to deliver better pediatric therapies tomorrow

Oral medicines for children in the European paediatric investigation plans

EMA initiatives for acceleration of development support and evaluation procedures for COVID-19 treatments and vaccines

Committee on Drugs. Guidelines for the ethical conduct of studies to evaluate drugs in pediatric populations

History of Pediatric Labeling

Minors and a dawning paradigm shift in "pediatric" drug development

Department of Health & Human Services, US Food & Drug Administration

Pediatric melanoma -the whole (conflicts of interest) story

Pediatric oncology at the crossroads: a call for change

The path to perfect pediatric posology -drug development in pediatrics

Use of opportunistic clinical data and a population pharmacokinetic model to support dosing of clindamycin for premature infants to adolescents

Pediatric Rheumatology Collaborative Study Group -over four decades of pivotal clinical drug research in pediatric rheumatology

International League of Associations for Rheumatology (ILAR)

Review: Genetics and the classification of arthritis in adults and children

Toward new classification criteria for juvenile idiopathic arthritis: first steps, pediatric rheumatology international trials organization international consensus

The term "juvenile idiopathic arthritis (JIA)" is misleading. It will not be sufficient to just replace this term

Brigham and Women's Hospital. Pediatric Rheumatology for Adults

Impact of pediatric exclusivity on drug labeling and demonstrations of efficacy

Rebirth of human embryology

Efficacy of antiepileptic drugs in adults predicts efficacy in children: a systematic review

Extrapolating evidence of antiepileptic drug efficacy in adults to children >2 years of age with focal seizures: the case for disease similarity

Drugs for treatment of partial onset seizures: full extrapolation of efficacy from adults to pediatric patients 2 years of age and older guidance for industry

Ethical issues in pediatric regulatory studies involving placebo treatment

International Pediatric Multiple Sclerosis Study Group (PPMSSG)

Clinical trials of disease-modifying agents in pediatric MS: opportunities, challenges, and recommendations from the IPMSSG

Ethics and clinical research

The Belmont Report at 40: reckoning with time

Ethical conduct of research in children: pediatricians and their IRB (Part 1 of 2)

EMA/PDCO Summary report on the review of the list of granted Class Waivers

Galileo Galilei: science vs. faith