Allocation of Scarce Resources After a Nuclear Detonation: Setting the Context

The purpose of this article is to set the context for this special issue of Disaster Medicine and Public Health Preparedness on the allocation of scarce resources in an improvised nuclear device incident. A nuclear detonation occurs when a sufficient amount of fissile material is brought suddenly together to reach critical mass and cause an explosion. Although the chance of a nuclear detonation is thought to be small, the consequences are potentially catastrophic, so planning for an effective medical response is necessary, albeit complex. A substantial nuclear detonation will result in physical effects and a great number of casualties that will require an organized medical response to save lives. With this type of incident, the demand for resources to treat casualties will far exceed what is available. To meet the goal of providing medical care (including symptomatic/palliative care) with fairness as the underlying ethical principle, planning for allocation of scarce resources among all involved sectors needs to be integrated and practiced. With thoughtful and realistic planning, the medical response in the chaotic environment may be made more effective and efficient for both victims and medical responders.

[1]  Daniel J Weisdorf,et al.  MEDICAL MANAGEMENT OF RADIATION VICTIMS IN THE UNITED STATES , 2010, Health physics.

[2]  Gabor D Kelen,et al.  Refining Surge Capacity: Conventional, Contingency, and Crisis Capacity , 2009, Disaster Medicine and Public Health Preparedness.

[3]  Dan Hanfling,et al.  Radiation Injury After a Nuclear Detonation: Medical Consequences and the Need for Scarce Resources Allocation , 2011, Disaster Medicine and Public Health Preparedness.

[4]  Judith L Bader,et al.  Radiologic and nuclear events: contingency planning for hematologists/oncologists. , 2008, Blood.

[5]  David Marcozzi,et al.  The “RTR” Medical Response System for Nuclear and Radiological Mass-Casualty Incidents: A Functional TRiage-TReatment-TRansport Medical Response Model , 2009, Prehospital and Disaster Medicine.

[6]  Rocco Casagrande,et al.  Triage and Treatment Tools for Use in a Scarce Resources-Crisis Standards of Care Setting After a Nuclear Detonation , 2011, Disaster Medicine and Public Health Preparedness.

[7]  Ann R Knebel,et al.  Resource Allocation After a Nuclear Detonation Incident: Unaltered Standards of Ethical Decision Making , 2011, Disaster Medicine and Public Health Preparedness.

[8]  Lewis Rubinson,et al.  Definitive care for the critically ill during a disaster: a framework for allocation of scarce resources in mass critical care: from a Task Force for Mass Critical Care summit meeting, January 26-27, 2007, Chicago, IL. , 2008, Chest.

[9]  Michael McGeary,et al.  Assessing Medical Preparedness to Respond to a Terrorist Nuclear Event: Workshop Report , 2009 .

[10]  K R Peterson,et al.  Internal dose following a major nuclear war. , 1992, Health physics.

[11]  Bruce M Altevogt,et al.  Guidance for Establishing Crisis Standards of Care for Use in Disaster Situations: A Letter Report , 2009 .

[12]  Roger Anderson,et al.  Homeland Security , 2004, Gov. Inf. Q..

[13]  Kristi L Koenig,et al.  Surge Capacity Concepts for Health Care Facilities: The CO-S-TR Model for Initial Incident Assessment , 2008, Disaster Medicine and Public Health Preparedness.

[14]  I Levanon,et al.  The inhalation hazard of radioactive fallout. , 1988, Health physics.

[15]  Lewis Rubinson,et al.  Summary of Suggestions From the Task Force for Mass Critical Care Summit, January 26–27, 2007 , 2008, Chest.

[16]  G. D. Ledney,et al.  COMBINED INJURY: FACTORS WITH POTENTIAL TO IMPACT RADIATION DOSE ASSESSMENTS , 2010, Health physics.

[17]  R H Vandre,et al.  Electromagnetic pulse (EMP), Part I: Effects on field medical equipment. , 1993, Military medicine.

[18]  Richard McNally,et al.  Scarce Resources for Nuclear Detonation: Project Overview and Challenges , 2011, Disaster Medicine and Public Health Preparedness.

[19]  Forum on Medical FORUM ON MEDICAL AND PUBLIC HEALTH PREPAREDNESS FOR CATASTROPHIC EVENTS , 2013 .

[20]  Brian R. Moyer,et al.  RAPID RADIATION DOSE ASSESSMENT FOR RADIOLOGICAL PUBLIC HEALTH EMERGENCIES: ROLES OF NIAID and BARDA , 2010, Health physics.

[21]  Tia Powell,et al.  Allocation of Ventilators in a Public Health Disaster , 2008, Disaster Medicine and Public Health Preparedness.

[22]  Sandy Bogucki,et al.  Triage, rationing, and palliative care in disaster planning. , 2009, Biosecurity and bioterrorism : biodefense strategy, practice, and science.

[23]  Rocco Casagrande,et al.  Using the Model of Resource and Time-Based Triage (MORTT) to Guide Scarce Resource Allocation in the Aftermath of a Nuclear Detonation , 2011, Disaster Medicine and Public Health Preparedness.

[24]  Anne Wilkinson,et al.  Palliative care considerations in mass casualty events with scarce resources. , 2009, Biosecurity and bioterrorism : biodefense strategy, practice, and science.

[25]  Ronald E. Goans,et al.  Synopsis of Partial-Body Radiation Diagnostic Biomarkers and Medical Management of Radiation Injury Workshop , 2010, Radiation research.