Unit 4 (Radiation Effect)

genetic effects

somatic effects

long term (late; delayed; latent) effects

short term (early) effects

stochastic effects

• increase
• (stochastic effects)

stochastic effect

• cancer
• embrylogic effects (birth defects)

nonstochastic (deterministic) effects

nonstochastic (deterministic) effects

• skin erythema
• cataracts
• sterility          
• reduced fertility
• loss of parenchymal cells
• organ atrophy
• fibrosis

nonthreshold

• nonthreshold
• (stochastic)

threshold

threshold

threshold dose

nonthreshold relationship

absolutely safe

chronic radiation exposure

acute radiation exposure

• –atomic bombs at Nagasaki, Hiroshima, and 3-Mile Island 1954
• –1986 Chernobyl nuclear radiation accident
• total body irradiation with radiation therapy patients

the amount of radiation that can be lethal to 50% of the exposed population within 30 days

the amount of radiation that can be lethal to 50% of the exposed population within 60 days

• –LD 10/30
• LD 50/60
• LD 100/60

• diagnostic radiology
• (acute radiation syndrome: no recorded cases)

• acute radiation syndrome (ARS)
•  within a few days or weeks of the exposure

• —prodromal syndrome
• latent period
• manifest illness
• recovery or death

prodromal

• exposure: 50 rads & above whole body produce initial symptoms within minutes to hours of the exposure
• symptoms: nausea, vomiting, diarrhea, and leukopenia (NVD syndrome)
• length: few hours to 2 days

• during this time the subject is free of visible symptoms, but there is the beginning of recovery and death
• length: few hours to weeks (period is shorter at  higher doses)

• this stage follows the latent period and symptoms vary according to the body system affected
• example: the hematopoietic system is   more sensitive than the skeletal system or   CNS system. Symptoms will vary due to the   systems sensitivity to radiation exposure

• —hematopoietic syndrome
• gastrointestinal syndrome
• central nervous syndrome

• aka: bone marrow syndrome;hematopoietic syndrome
• dose & survival time: 100-1000 rads; 200 rads may die within 6-8 weeks; 200-1000 rads will die sooner; 100-200 rads considered non-lethal and may recover within 3 weeks to 6 months post irradiation
• prodromal: within a few hours of irradiation and may last several days
• latent: may last up to four weeks
• manifest: severe NVD; decrease in RBC, WBC, and platelets in the circulating blood, hemorrhage, infection
• cause of death: generalized infection, electrolyte imbalance, dehydration

• survival time: with doses of 600-1000 rads may die within 3-10 days
• prodromal: severe nausea, vomiting, and diarrhea for as long as 24 hours
• latent: 5 days
• manifest: severe nausea, vomiting, may induce fever, fatigue, loss of appetite, lethargy, anemia, leukopenia, hemorrhage, infection, electrolyte imbalance, and emaciation
• cause of death: damage to cells lining the GI tract; these crypt cells are very sensitive to radiation because they have a high turnover rate of 3-5 days

• dose & survival: above 5000 rads; 3-5 days
• prodromal: begins within minutes of exposure and may include confusion and nervousness
• latent: lasts up to 12 hours
• manifest: disorientation, shock, periods of agitation alternating with stupor, ataxia, edema in the cranial vault, loss of equilibrium, fatigue, lethargy, convulsive seizures, electrolyte imbalance, meningitis, prostration, respiratory distress, vasculitis, and coma
• cause of death: unknown, thought to be due to increased intracranial pressure

late somatic effects

late nonstochastic (deterministic) somatic effects

late stochastic (probabilistic) somatic effects

• carcinogenesis
• cataractogenesis
• embryologic effects (birth defects)

• at high doses, like that seen in atomic bomb survivors, the risk is measurable in human populations
• at low doses, like that seen in occupational exposure or diagnostic studies, the risk is not directly measurable in population studies (risk is overshadowed by the naturally occurring cancers)

absolute risk model

relative risk model

absolute risk model

relative risk model

• radium watch dial painters (1920s-1930s)
• uranium miners (1950s-1960s)
• early medical radiation workers (1896-1910)
• patients injected with thorotrast (1925-1945)
• infants irradiated for large thymus glands(1954)
• japanese atomic bomb survivors (1945)
• evacuees of Chernobyl nuclear power disaster (1986)

• paint consisted of zinc sulfide (ZnS) mixed with radium (²²⁶Ra)
• radium is an alpha-particle emitter that is chemically similar to calcium, and is therefore a 'bone seeker' 
• ²²⁶Ra that accumulated in the bone marrow irradiated nearby tissue, and produced bone cancer and other genetic damage

• thomas edison's assistant, clarence dally, who died in 1904
• after documentation of his struggle with burns, serial amputations, and extensive lymph node involvement

—the shadows of the parapets were imprinted on the road surface of the Yorozuyo Bridge, 1/2 a mile south-south-west of the hypocenter

200 rads

1 rad

• physicist who worked on the cyclotron
• japanese atomic bomb survivors

• preimplantation: 0-9 days after conception
• organogenesis: 10 days to 6 weeks (after conception)
• fetal: 6 weeks (after conception) to term

• first eight weeks: equivalent doses in excess of 20 rem frequently results in death
• preimplantation: 5 to 15 rads can cause embryonic death
• organogenesis: very susceptible to radiation-induced congenital abnormalities
• third trimester: fetus less sensitive to radiation, but this later stage can still experience congenital abnormalities and functional disorders such as sterility

• only 1 rem
• not considered dangerous to the unborn

"genetic effects"

• brought on by damage to the DNA in the sperm or ova
• allows for faulty genetic information to be carried on to the offspring.

natural spontaneous mutations

• hemophilia
• huntington's chorea
• down's syndrome (mongolism)
• duchenne's muscular dystrophy
• sickle cell anemia
• cystic fibrosis
• hydrocephalus

10%

• elevated temperature
• ionizing radiation
• viruses
• chemicals

after radiation interacts with DNA, the molecules can experience chromosomal breakage or change in the amount of DNA belonging to the cell or an alteration in the sequence of nitrogenous bases.  All of which can lead to genetic mutations in subsequent generations

• if the enzymes are able to repair, the cells function as normal
• if the enzymes are unable to repair, the cells may suffer functional impairment or die

mutant genes

sickle cell anemia

sickle-cell anemia

points mutations

recessive

both parents must have the same genetic defect

• –allergies
• slight alteration in metabolism
• decreased intelligence
• predisposition of certain diseases

may be rising

fruit flies and mice

• genetic effects do not have a threshold
• implies no such thing as a safe dose of radiation

• the information is contradictory and inconclusive
• test groups include children conceived after exposure at Nagasaki and Hiroshima.  As of third generation, no radiation-induced genetic effects are known
• Crow, a geneticist, states genetic induced effects may include higher embryonic death, shorter life-span, increase in disease and decreased fertility

doubling dose concept

• 156 rem
• (–stillbirths, childhood mortality, sex chromosome aneuploidy)