Radiation exposure (disaster): Difference between revisions

Latest revision as of 15:18, 14 October 2019

Background

“Ionizing” radiation is electromagnetic or particulate which can create charged particles or ions
"Non-ionizing radiation" ( e.g., light, microwaves, and radiowaves) does not have sufficient energy to eject an electron from another atom
Ionization of biologically important molecules, e.g., DNA, can cause cellular death
Ionizing radiation at higher doses can cause damage to actively dividing and undifferentiated cell types, e.g., stem and progenitor cells in the bone marrow, gastrointestinal system, and skin

Radiological and Nuclear Scenarios of Concerns

Radiological exposure devices
Radiological dispersal devices
Nuclear power plant incidents/accidents
Improvised nuclear devices

Radiological Exposure Devices (RED)

A RED is a device that can cause exposure to ionizing radiation without the knowledge of the person being exposed
Surreptitious placement of a RED could delay discovery and notification of the healthcare community
Injury is based on the radiation dose received, whether accidental or intentional in nature
A concealed RED scenario could result in serious injuries

Radiological Dispersal Devices (RDD)

Any device used to spread radioactive material; more commonly thought of as an explosive device or “dirty bomb"
Do not necessarily need to explode in order to spread radiological material into the environment
- Non-explosive RDD could cause environmental contamination that could lead to human contamination (e.g. use in facility ventilation systems, fumigation systems, etc.)
Explosion of an improvised explosive devices (IED) with radioactive material could cause additional injury, internal contamination, and panic
Persons near the epicenter of an explosion of a dirty bomb will sustain physical trauma, thermal burns, and embedded foreign bodies including radioactive shrapnel.
Amount of physical damage from RDD would depend on amount and type of explosives used; additional radiological consequences would depend on source and physical properties as well as explosive device
Removal of foreign bodies would require healthcare providers wear PPE and have access to radiation monitoring equiment (e.g. ring dosimeters)
Management of internal contamination via inhalation or wounds might be required for some patients

Nuclear Power Plant (NPP) Incident/Accident

The Fukushima Japan nuclear power plant disaster in March of 2011 was highly unusual and the first time that such a serious situation at a nuclear power plant resulted from an environmental disaster.
Nuclear power plants use the energy created by the fissioning of atomic nuclei ("splitting" of the atom) to generate electricity. *Heat generated during fission process converts water to steam, which then is used to drive electricity-generating turbines
Loss of power to coolant pumps can allow reactor core to overheat, which can then cause the radioactive core to "melt-down".

Nuclear Device Detonation

3 forms of energy released by nuclear detonation^[1]
- Heat (35% of total)
- Shock or bomb blast (50%)
- Radiation (15%)
The detonation of any kind or size of nuclear weapon would be expected to cause massive physical damage to a community and untold psychological devastation to its population. In 2009, the National Security Staff released the first edition of Planning Guidance for the Response to a Nuclear Detonation10 In this document, planners categorized the devastation, types of physical damage, and types of human injuries based upon distance from the detonation epicenter in zones. The second edition of this document, released in June 2010, updated recommendations and guidance based on intensive modeling efforts to try to further quantify the effects of a nuclear detonation in an urban American city. Part of the updates to the guidance includes further refinement of the proposed damage zones. The document’s authors called the area closest to the epicenter the Severe Damage (SD) zone; the adjacent area the Moderate Damage (MD) zone; and the affected area furthest away from the epicenter, the Light Damage (LD) zone. In addition, a dangerous fallout (DF) radiation zone, which is determined by the scattering of radiological material, is also defined3. The presumed “safe” and “dangerous” distances away from the epicenter vary from scenario to scenario in modeling efforts and would be made after-the-fact by the incident commander based upon types of damage found on the ground. Zone determinations would depend upon:
The yield of the weapon
Whether the detonation was at a height or at ground level, and
The topographical features of the terrain and its structures.

Basic Principles

Physical Properties

Radiation Types
- Gamma and xrays - deep penetration
- Alpha - hazard only if ingested/ inoculated since penetration only ~0.1mm
- Beta/electrons - penetrate only a few centimeters
Dose
- Rads - dose absorbed by specific tissue.
- Gray (Gy) - international unit for absorbed dose. (1 Gy = 100 rads)
- REM - "Effective Dose" (100 rem = 1 sievert = 1 Gy)
Principles of exposure
- Different radioactive particles have diff effects at same absorbed dose- so use effective dose for comparison
- Effect of radiation based on time of exp, distance and shielding
- Dose decreases rapidly with square of distance and decreases on 1/9th if triple distance
- Lead is an effective shield
Radiation decays with time
- Iodine isotopes are short lived
- Cesium, stontium, cobalt are longer-lived
- Rate of decay also effects dose of exposure and may effect management decisions

Biological Principles

Some cells may die but if cells role not critical for survival, may not see effect
Rapidly dividing cells (e.g. GI and bone marrow) are most vulnerable
Dose ~1Gy, cells survive but get cancer later
Radiation-induced cancer dose related
Leukemia within 2 yrs, solid tumors 5-10 or more yrs
Beta rays from fallout only burn exposed skin

Clinical Features

Presentation dependant on nature of exposure
- See acute radiation syndrome, blast injuries
- May be asymptomatic
Radiation burn like thermal burn but signs can occur after a few days, vascular insufficiency after several months and causing necrosis of previously healed skin

Differential Diagnosis

Mass casualty incident

Radiation exposure (disaster)
Dirty bomb
Bioterrorism
Chemical weapons
Mass shooting
Natural Disaster (e.g. Hurricane, Earthquake, Tornado, Tsunami, etc)
Unintentional large-scale incident (e.g. building collapse, train derailment, etc)
Major pandemic
Explosions

Evaluation

Evaluate and stabilize any life threatening physical injuries (ABC's)
Decontaminate after stabilized
- Check for external contamination
  - document location, dose rate and/or count measurements initial and after decontamination, and description of decontamination methods/agents used
- Check for internal contamination
  - swab both nostrils
  - 24-hour stool and 24-hour urine samples
  - Identify radionuclide (chemical form), solubility and particle character
  - Document suspected route of contamination.
- External exposure to ionizing radiation
  - document location and position of patient relative to source of radiation at time of exposure, as well as time and duration of exposure (including dosimeter information if applicable)
CBC q6-8h x 2-3 days
Amylase; baseline and at 24h post exposure

Management

Can be localized or whole body, internal or external deposition and contamination
Mostly not emergency, just treatment symptoms and supportive care
Consider contacting health physicist and/or radiation safety officer for help

Localized Exposure

Treat wounds symptomatically
- Close wounds within 35-48 hours
By direct handling. patient survives even though dose high since exposure drops rapidly with distance
Treat burns with pain control, prophylactic antibiotics, vasodilator treatment, surgery, skin graft,
- Extent of penetration important factor in outcome

Whole Body Exposure

Acute Radiation Syndrome

Those persons who receive a significant exposure from radiation may experience acute radiation syndrome (ARS), a systemic illness caused by exposure to a level of ionizing radiation sufficient to cause damage to the hematopoietic, gastrointestinal, cardiovascular or central nervous system

Dose	SubSyndrome	Potential Signs and Symptoms
	N/A	Subclinical
1 GY (100 rad)	Hematopoietic	Lymphocytopenia – 24-48 hours (worsens with increasing dose) Thrombocytopenia, Anemia - weeks
6 Gy (600 rad)	Gastrointestinal	Nausea/vomiting, diarrhea with resulting hypovolemia and electrolyte shifts,
10 Gy (1000 rad)	Neurovascular	Nausea, headache, lethargy, ataxia, confusion, seizures

- Within 12hr, nausea/vomiting for 48hr
- Dose >30 gy: cardiovascular and CNS effects - hypotension, cerebral edema, seizure, nausea/vomiting/diarrhea, ataxia, death
- Dose 10-30 gy: GI syndrome: nausea and vomiting/diarrhea, then latent for 1 week, then recurrent nausea and vomiting/diarrhea this time with sepsis and death
Hematopoietic symptoms- dose 2gy or higher- lymphocyte reduction within 48 hrs is indicator for rad exposure. get leukopenia and thrombocytopenia- bleeding and infection- may enhance recovery by hematopoietic factors
Cutaneous symptoms- damaged skin may interact with other organ damage
Amifostine- prophylactic radiation drug- causes hypotension as side effect
Androstenediol- boosts immune system
Bone marrow transplant not helpful
Even if treatment and survive hematopoetic symptoms, still die from radiation pneumonitis, denuded GI tract, hepatic and renal dysfunction

Internal Contamination

May enter thru burns, wounds, inhale, ingest
Need to know type of radionuclide and chemical form
Need to treatment quickly to be effective
Reduce absorption, dilute, blockage, displacement by nonradioactive materials, mobilization, chelation
Potassium iodine for nuc weapon detonation or reactor breach- prevents radioiodine from accumulating in thyroid. take shortly after exp to be effective- if give too much get iodism
Dose- 130mg adults, 65mg 3- 18ys, 32mg 1mo- 3yr, 16mg for age< 1mo
Chelators- calcium, zinc, only for plutonium or americium

External Contamination

Clothes and exp skin- just clean up and prevent spread
Clean with soap and water
If extremis- stabilize first, then decontam
Do not abraid skin while cleaning

Contaminated Burns and Wounds

Irrigate
Excise only if long acting radionuclides
If whole body dose >1gy, close wound asap to prevent portal of infc
In burns, radioactivity comes off with eschar and exudate

Disaster Management

Preparation, crisis management, consequences
FBI is lead agency in terrorist incident
During consequence management, FEMA fed emerg management agency takes over
Intervention- action to reduce exposure and dose of radiation
If dose 1 rem- stay in doors up to 2 days- evacuate for 1 wk if dose of 5 rem or more
Temperature relocation if dose 3 rem in first month or 1 rem in subsequent month
Permanent resettlement if lifetime dose 100 rem
Potassium iodine only if thyroid dose 100mgy or more
EMS occupational dose of 5 rem per yr dose not apply- allowable dose goes up for lifesaving event
At dose of 0.1 gy/hr- ems may go in for short time but dose may be life threatening

References

↑ Waselenko JK, MacVittie TJ, Blakely WF, et al. Medical management of the acute radiation syndrome: recommendations of the Strategic National Stockpile Radiation Working Group. Ann Intern Med. 2004 Jun 15;140(12):1037-51.

Authors:

[SNSRWG-1] Waselenko JK, MacVittie TJ, Blakely WF, et al. Medical management of the acute radiation syndrome: recommendations of the Strategic National Stockpile Radiation Working Group. Ann Intern Med. 2004 Jun 15;140(12):1037-51.

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