Despite children’s unique vulnerability, clinical guidance and resources are lacking around use of the radiation medical countermeasures (MCMs) available commercially and in the Strategic National Stockpile to support immediate dispensing to pediatric populations. To better understand the current capabilities and shortfalls, a literature review and gap analysis were performed.
A comprehensive review of the medical literature, Food and Drug Administration (FDA)-approved labeling, FDA summary reviews, medical references, and educational resources related to pediatric radiation MCMs was performed from May 2016–February 2017.
Fifteen gaps related to the use of radiation MCMs in children were identified. The need to address these gaps was prioritized based upon the potential to decrease morbidity and mortality, improve clinical management, strengthen caregiver education, and increase the relevant evidence base.
Key gaps exist in information to support safe and successful use of MCMs in children during radiation emergencies; failure to address these gaps could have negative consequences for families and communities. There is a clear need for pediatric-specific guidance to ensure clinicians can appropriately identify, triage, and treat children who have been exposed to radiation, and for resources to ensure accurate communication about the safety and utility of radiation MCMs for children.
Release of radioactive materials into the environment may occur intentionally or unintentionally. Although infrequent, several large-scale unintentional radiation disasters have occurred throughout the world in recent decades. The most recent was the Fukushima Daiichi nuclear power plant incident that occurred following the March 2011 Great East Japan Earthquake (Great Sendai Earthquake) and Tsunami. The tsunami waves damaged the power plant and back-up generators, resulting in a reactor core failure and the release of radioactive material. This incident continues to be a threat due to persistently high radiation levels around the destroyed reactors, hundreds of unsecured fuel rods, and the continued contamination of underground water.
Children are a vulnerable population in radiation emergencies.
The National Response Framework’s Emergency Support Function #8 outlines the public health and medical services coordinated and provided by the U.S. Department of Health and Human Services (HHS) following a mass casualty incident.
Despite children’s unique vulnerability, there is a lack of clinical guidance around use of the radiation MCMs available commercially and in the SNS to support immediate dispensing to the pediatric population. To better understand the current pediatric capabilities and shortfalls to effectively utilize radiation MCMs, a review of the literature and gap analysis were performed. This article enumerates the key gaps to help public health officials, healthcare preparedness planners, emergency managers, researchers, and emergency medicine and pediatric clinicians better prepare for children’s needs in the event of a radiation emergency.
A comprehensive review of available medical literature, Food and Drug Administration (FDA)-approved product inserts, FDA summary reviews, medical references, and educational resources related to radiation MCMs for children was performed between May 2016 and February 2017. The search included information on the radiation MCMs available in the SNS, as well as those available commercially.
A medical librarian searched Medline, Ebscohost, Google Scholar, and the Disaster Information Management Research Center for relevant articles in English. Search terms focused on radiation illness, radiologic or nuclear events, anti-neutropenics, myeloid cytokines, medical countermeasures, and pediatrics. Manuscripts lacking pediatric-specific content were excluded from review. FDA-approved product inserts and summary reviews were obtained and reviewed for all radiation MCMs. Clinical and educational resources related to pediatric radiation MCMs, developed for both healthcare providers and the public, were identified through searches of the CDC, FDA, National Institutes of Health (NIH), Department of Defense (DOD), Radiation Emergency Assistance center/Training Site (REAC/TS), National Library of Medicine’s Radiation Emergency Medical Management (REMM), U.S Department of Energy (DOE), World Health Organization (WHO), WebMD® (New York, New York), and UpToDate® (Wolters Kluwer, Alphen aan den Rijn, Netherlands) websites.
For the purposes of this analysis, MCMs are divided into two broad categories based upon the scenarios in which they are utilized. The first category includes MCMs used in radiological dispersal device (RDD) incidents or nuclear power plant accidents. This category includes chelators and blocking products that reduce morbidity and mortality by inhibiting body tissue uptake, accelerating renal elimination, or enhancing gastrointestinal elimination of radioactive materials that have entered the body. The second category includes MCMs used in nuclear emergencies after the detonation of a nuclear weapon or improvised nuclear device (IND). This category of MCMs would also be useful in scenarios involving partial or whole body external exposure as seen with radiological exposure device (RED) incidents. This category includes myeloid cytokine products that prevent or mitigate H-ARS through accelerating white blood cell production, thereby reducing the time that the patient is vulnerable to life-threatening infections.
Four chelating or blocking MCMs were identified: calcium diethylene triamine pentaacetic acid (Ca-DTPA, Hameln, Gloucester, United Kingdom); zinc diethylene triamine pentaacetic acid (Zn-DTPA, Hameln, Gloucester, United Kingdom); Prussian Blue (Radiogardase®, Heyltex, Katy, Texas); and potassium iodide sold as Iosat® (Anbex, Williamsburg, Virginia), ThyroSafe® (Recipharm, Stockholm, Sweden), ThyroShield® (Arco, Sharon Hill, Pennsylvania), and Liquid KI® (Mission Pharmacal, San Antonio, Texas).
Five myeloid cytokine agents were identified: filgrastim (Neupogen®, Amgen, Thousand Oaks, California), pegfilgrastim (Neulasta®, Amgen, Thousand Oaks, California), sargramostim (Leukine®, Sanofi, Paris, France), tbo-filgrastim (Granix®, Teva, Petah Tikva, Israel), and filgrastim-sndz (Zarxio®, Sandoz, Holzkirchen, Germany).
For each MCM, data were collected on pharmacologic characteristics and educational resources and references for clinicians, parents and families, and pharmacists. Data were abstracted in Microsoft® Excel and reviewed by an interdisciplinary team of 3 pediatric healthcare providers, 3 public health professionals, and 3 radiation experts to identify and prioritize gaps. Gaps were identified by comparing the MCM to ideal characteristics for pediatric use—namely, that the MCM was indicated for all ages < 18 years, was available in appropriate pediatric formulations, included dosing and administration instructions for children, that pediatric clinical guidelines and references were available for healthcare providers and pharmacists, and that educational and informational resources for parents and families were readily accessible. After gaps were identified, they were evaluated for their potential impact on pediatric morbidity and mortality, clinical management, parental and family support, and the evidence base for the use of radiation MCMs in children.
These gaps were then prioritized into high, medium, and low categories. High priority gaps were those which, if addressed, had a significant potential to decrease morbidity and mortality rates, improve clinical management of pediatric victims, strengthen parent and family education, and/or significantly enhance the ability to increase the evidence base for use of radiation MCMs in children. Medium and low priority gaps were those which met these same criteria, but to a moderate or lesser extent, with low priority gaps including those which impact only a small segment of the pediatric population, affect fewer healthcare professionals, and address pediatric issues focused on long-term—rather than acute—effects of radiation emergencies.
Pharmacologic characteristics that were abstracted included elements such as available formulations (e.g. suspension, crushable tablet, capsule), regulatory status (e.g. approved for use in children, not approved for use in children), dosing, and mechanism of action. Appropriate pharmacologic characteristics are critical when a MCM needs to be administered to a child—for example, an MCM that is approved for children must come in an oral suspension, crushable tablet, or other form that can be easily swallowed, or otherwise administered.
Educational resources and references for clinicians included items such as pediatric-specific clinical guidelines, pocket guides, handheld applications, online just-in-time training, and fact sheets. These resources are particularly important for clinicians who have little, or no, experience with radiation emergencies and MCMs. It is vital that healthcare providers have readily accessible clinical guidelines and information regarding MCMs, if appropriate and timely care are to be achieved in a radiation emergency.
Educational resources and references for parents and families included items such as pediatric specific dosing and administration instructions, infographics, frequently asked questions (FAQs), and instructional videos. Accurate and accessible resources about radiation MCMs for parents and families will be crucial to ensuring appropriate response to—and home-based management of—possible radiation injuries, and for the minimization of false information and undue emotional distress.
Educational resources and references for pharmacists included pediatric-specific FAQs, online training, and toolkits. Pharmacists may serve a vital function in radiation emergencies in which mass dispensing of MCMs is necessary. In such cases pharmacists will require information on pediatric formulations, dosing, and appropriate administration. In addition, pharmacists may become an important resource on radiation MCMs for clinicians, parents, and patients alike, and may need to fill that role with little or no prior experience in radiation emergencies.
A total of 114 manuscripts were identified through a literature search (n = 70) and by additionally reviewing reference lists of relevant articles (n = 44). Seventy-six articles were excluded, for the reasons noted in the
Of the 4 MCMs that block or chelate radioisotopes, 3 (75%) are available in pediatric formulations, butonly 1 (25%) is available over-the-counter. All 4 (100%) are FDA-approved for children < 18 years—except for Prussian Blue in children < 2 years of age—and available in the SNS. Three (75%) of the MCMs provide complete pediatric dosing instructions, and all 4 (100%) have pregnancy and breastfeeding recommendations. See
For the 5 MCMs that treat H-ARS, 4 (80%) are available in pediatric formulations. None is available over-the-counter, 3 (60%) are available in the SNS (as well as the commercial market), and 2 (40%) are FDA-approved for use in all children < 18 years with H-ARS. CDC has a Pre-Emergency Use Authorization (EUA)
Of the 4 chelating or blocking MCMs, all 4 (100%) had information on use in pediatric populations for clinicians, available in handheld apps, fact sheets, online just-in-time training (JITT), online MCM-specific training, pocket guides, tool kits, and triage guidelines. One (25%) had pediatric-specific clinical guidelines, 2 (50%) had references on the WebMD® website, and 1 (25%) had a reference on the UpToDate® website. There were no (0%) MCM-specific clinician resources on pregnancy or breastfeeding recommendations.
For the 5 myeloid cytokine MCMs, all 5 (100%) had information for clinicians on use in pediatric populations available in pocket guides and general radiation triage guidelines, as well as references on the WebMD® and UpToDate® websites—although none (0%) listed H-ARS as an indication for use. None (0%) had online pediatric-specific MCM training, online JITT for use in children, pediatric-specific toolkits, or pediatric-specific clinical guidance for use in H-ARS. There were no (0%) MCM-specific clinician resources on recommendations for use during pregnancy or while breastfeeding.
Of the 4 chelating or blocking MCMs, 1 (25%) provided pediatric dosing guidance for parents and families and 1 (25%) provided administration instructions. Four (100%) had a set of FAQs, guidance for use while breastfeeding, and online educational videos. Two (50%) MCMs had fact sheets and infographics.
For the 5 myeloid cytokine MCMs, none (0%) had pediatric-specific dosing guidance or administration instructions for parents and families. However, two (40%) package inserts contain information on self-administration, which could potentially serve as caregiver instructions. None (0%) provided online educational videos about the use of the agent in treating children with H-ARS. Only 1 (20%) offered a fact sheet and 1 (20%) a set of FAQs. None (0%) of the MCMs had infographics, or guidance for use during pregnancy or while breastfeeding.
Of all 9 MCMs reviewed, there were no (0%) FAQs, toolkits, online JITT, or any other pediatric-specific educational resources for pharmacists.
We identified 15 key gaps related to the use of radiation MCMs in the pediatric population. These were categorized as high (n=5), medium (n=5), or low priority (n=5). The high priority gaps included areas lacking clinical guidelines, patient and family information, indications for the youngest children, and pre-established research protocols to improve the knowledge base (see
Large-scale radiation and nuclear disasters are uncommon, but when they occur, children are expected to be disproportionately affected. Identifying and addressing information gaps in the effective use of radiation MCMs in children is an important step in improving our nation’s preparedness and response to a significant radiation emergency.
No clinical guidelines or guidance statements for using myeloid cytokines to treat children with H-ARS were identified. Most clinicians will not encounter radiation casualties in their entire career, let alone a child with H-ARS. However, despite the low frequency of these events, the results of an inadequate response or delayed treatment could have negative consequences. Many clinicians are unfamiliar with basic treatment principles for radiation injuries, and treating children in these rare circumstances will require direction and guidance—particularly regarding the use of myeloid cytokines.
Similarly, limited clinical guidelines or guidance statements exist for using MCMs to treat children who have internalized specific radioactive materials. While there is some guidance available for the use of potassium iodide
There is very little information available for the public about the use of myeloid cytokines in treating H-ARS—and no pediatric-specific information designed for parents and families. Each of the drug manufacturers provide online instructional videos for the self-administration of their product, but none of these specifically addresses pediatric dosing or administration. While the CDC has a public information page on the use of Neupogen® it provides little information regarding the treatment of children with myeloid cytokines.
Prussian blue is the MCM of choice for treating radiation exposure from Cesium (Cs-137), a radioisotope used in radiation therapy, industrial radiography, and a byproduct of nuclear power plants.
Fortunately, large-scale radiation emergencies are infrequent, and events affecting children are even rarer. Our present understanding is largely limited to data collected from events such as those in Hiroshima and Nagasaki, Japan; Chernobyl, Ukraine
There were 10 additional gaps identified which, although of lesser-anticipated impact to children’s outcomes in radiation emergencies, are worth further consideration. The medium priority gaps include: 1) determining if there is a preferred myeloid cytokine MCM for treating H-ARS in children; 2) information on the use of commercially available myeloid cytokine MCMs, that are not FDA-approved for the radiation indication, in a large-scale radiation emergency involving children; 3) updating the most commonly used medical reference websites to include “Hematopoietic Sub-syndrome of Acute Radiation Syndrome” as an indication for currently available myeloid cytokines; 4) updating the most-commonly used medical reference websites with information on DTPA and Prussian Blue; 5) guidance for breastfeeding mothers taking radiation MCMs during a radiation emergency. The low priority gaps include: 1) guidelines and training in the use of pediatric radiation MCMs for pharmacists; 2) information regarding the short- and long-term effects/toxicity of radiation MCMs in infants and children; 3) laboratory diagnostic and monitoring challenges associated with the use of radiation MCMs in children; 4) public health messaging about the long-term effects and risks of radiation exposure and contamination in children; 5) identified subject matter experts in pediatric radiation emergencies and MCMs.
The conclusions in this report are subject to some limitations. Although the literature search included widely accepted and reputable sources, additional resources and references relevant to the review may have been missed. There are other documents, correspondence, and resources shared and exchanged among governmental entities and partners that are not available in the public domain. These may provide valuable insight and help augment radiation emergency preparedness measures. In addition, the search was limited to the English language and additional sources of information (e.g., from Chernobyl, Ukraine or Goiânia, Brazil) may have been overlooked. Finally, the paucity of research and published manuscripts regarding the use of radiation MCMs in children limited our ability to draw conclusions based on broad clinical evidence or experience, but further supported the need for this analysis and future study.
Key gaps exist in information to support the safe and successful use of MCMs in children in the event of radiation emergencies; failure to address these gaps may have negative consequences for families and communities. There is a clear need for pediatric-specific guidance to ensure clinicians can appropriately identify, triage, and treat children who have been exposed to radiation and a need for resources for clinicians, parents and families, and pharmacists to ensure clear, accurate communication about the safety and utility of administering radiation MCMs to children.
Potential next steps include: developing clinical guidance for treating children with exposure to radioactive material and H-ARS, developing a robust suite of communication tools on the safety and utility of radiation MCMs for all key audiences, developing a comprehensive implementation plan including crisis standards of care guidance, and encouraging further research into the use of radiation MCMs in the pediatric population.
Summary of Pharmacologic Characteristics and Educational Resources for Pediatric Radiation Medical Countermeasures
| MCMs that Block or Chelate Radioisotopes (n=4) | MCMs that Prevent or Mitigate H-ARS (n=5) | |
|---|---|---|
| Pediatric formulations | 3 (75%) | 4 (80%) |
| OTC availability | 1 (25%) | 0 (0%) |
| SNS availability | 4 (100%) | 3 (60%) |
| FDA-approved for adult use | 4 (100%) | 3 (60%) |
| FDA-approved for child use | 4 (100%) | 2 (40%) |
| Adult dosing | 4 (100%) | 5 (100%) |
| Pediatric-specific dosing | 3 (75%) | 4 (80%) |
| Pregnancy recommendations | 4 (100%) | 5 (100%) |
| Breastfeeding recommendations | 4 (100%) | 5 (100%) |
| Handheld app | 4 (100%) | 2 (40%) |
| Fact sheets | 4 (100%) | 3 (60%) |
| Online training (radiation J ITT) | 4 (100%) | 0 (0%) |
| Online training (MCMs) | 4 (100%) | 0 (0%) |
| Clinical guidelines | 1 (25%) | 0 (0%) |
| Pocket guide | 4 (100%) | 5 (100%) |
| Pregnancy guidance | 0 (0%) | 0 (0%) |
| Breastfeeding guidance | 0 (0%) | 0 (0%) |
| Toolkit | 4 (100%) | 0 (0%) |
| Triage guidelines | 4 (100%) | 5 (100%) |
| UpToDate® reference | 1 (25%) | 5 (100%) |
| WebMD reference | 2 (50%) | 5 (100%) |
| Pediatric dosing guidance | 1 (25%) | 0 (0%) |
| Administration instructions | 1 (25%) | 0 (0%) |
| Fact Sheets (MCMs) | 2 (50%) | 1 (20%) |
| FAQs | 4 (100%) | 1 (20%) |
| Infographics | 2 (50%) | 0 (0%) |
| Pregnancy guidance | 0 (0%) | 0 (0%) |
| Breastfeeding guidance | 4 (100%) | 0 (0%) |
| Online educational videos | 4 (100%) | 0 (0%) |
| Online training | 0 (0%) | 0 (0%) |
| FAQs | 0 (0%) | 0 (0%) |
| Online training (JITT) | 0 (0%) | 0 (0%) |
| Toolkit | 0 (0%) | 0 (0%) |
Abbreviations: MCM (medical countermeasure), H-ARS (Hematopoietic sub-syndrome of Acute Radiation Syndrome), OTC (over the counter), SNS (Strategic National Stockpile), FDA (Food and Drug Administration), JITT (just-in-time training), FAQs (frequently asked questions)
potassium iodide, calcium diethylene triamine pentaacetic acid, zinc diethylene triamine pentaacetic acid, Prussian Blue
filgrastim, pegfilgrastim, sargramostim, tbo-filgrastim, filgrastim-sndz
Prioritized Gaps in Pediatric Radiation Medical Countermeasures (MCMs).
Clinical guidelines for treating the Hematopoietic Sub-syndrome of Acute Radiation Syndrome in children with myeloid cytokines. Clinical guidelines for treating children who have internalized specific radioactive materials with MCMs. Information for parents and families about treating the Hematopoietic Sub-syndrome of Acute Radiation Syndrome in children with myeloid cytokines. Indications, dosing, and recommendations for treating children < 2 years of age with Prussian blue. Pre-established research protocols and processes to conduct studies and collect relevant data during radiation emergencies involving children—to better inform the safe and effective use of radiation MCMs in this population. |
Preferred myeloid cytokine MCM for treating the Hematopoietic Sub-syndrome of Acute Radiation Syndrome in children. Information on the use of commercially available myeloid cytokine MCMs, that are not FDA-approved for the radiation indication, in a large-scale radiation emergency involving children. Update to the most commonly used medical reference websites to include “Hematopoietic Subsyndrome of Acute Radiation Syndrome” as an indication for currently available myeloid cytokines. Update to the most-commonly used medical reference websites with information on diethylene triamine pentaacetic acid and Prussian blue. Guidance for breastfeeding mothers taking radiation MCMs during a radiation emergency. |
Guidelines and training in the use of pediatric radiation MCMs for pharmacists. Information regarding the short- and long-term effects/toxicity of radiation MCMs in infants and children. Laboratory diagnostic and monitoring challenges associated with the use of radiation MCMs in children. Public health messaging about the long-term effects and risks of radiation exposure and contamination, as well as the psychological effects, in children. Few identified subject matter experts in pediatric radiation emergencies and MCMs. |
Determinations on prioritization were made as referenced in the