Late Deterministic and Stochastic Radiation Effects on Organ Systems PDF

Summary

This document discusses the late deterministic and stochastic effects of radiation on organ systems. It includes a classification of biological effects, and various sources of ionizing radiation, such as X-rays and radioactive materials. It also covers the risk estimate for human cancer from low-level radiation exposure.

Full Transcript

Late Deterministic and Stochastic
Radiation Effects on Organ Systems
■ By
■ Dr. Mohsen Dashti
■ 432 Radiation Protection & Radiobiology

SOMATIC EFFECTS
■ When living organisms that have been exposed to radiation sustain biologic damage, the
effects of this exposure are classified as somatic (i.e., body) effects
– An example of a non- somatic effect is irradiation of an individual’s genetic material
(sperm or eggs) leading to a genetic malformation in offspring.
This lecture focuses on organic damage from ionizing radiation that occurs months or years following
radiation exposure.

STOCHASTIC


The probability of the
effect, rather than its
severity, ↑ with dose
 No dose respond threshold
below which risks cease to
exist (modern radiation
program) ALARA, as low as
reasonably achieved.
 The principal health risk
from low-dose radiation
 Radiation-induced cancer
and genetic effects

LATE SOMATIC EFFECTS: are consequences of
radiation exposure that appear months or years after
such exposure.
 These effects may result from the following:


Previous whole- or partial-body acute exposure



Previous high radiation doses



Long-term low-level doses sustained over
several years.

 The three major types of late effects are:


Carcinogenesis (STOCHASTIC)



Embryologic effects (STOCHASTIC)



Cataractogenesis (DETERMINSTIC)









DETERMINISTIC
Threshold dose below which
the effect is not seen.
Associated with relatively
high doses(>2 Gy)
Severity of the effect, rather
than its probability, ↑ with
dose.
Predominant biologic effect
is cell killing resulting in
degenerative changes to the
exposed tissue
Cataracts, erythema, fibrosis,
and hematopoietic damage
are some deterministic
effects

 Risk Estimate for Cancer from Low-Level Radiation Exposure(stochastic effect)

 LOW-LEVEL RADIATION has been defined as “an absorbed dose of
0.1 Sv or less delivered over a short period of time” and as “a larger
dose delivered over a long period of time—for instance, 0.5 Sv in 10
years.”
 Does the dose in radiography considered as low-level exposure??
 The effective dose of a typical routine two-view chest radiograph is approximately 0.06 (can be greater or
lesser, depending on the patient’s body habitus), so this is considered far lower than what is considered a
low-level exposure.

 Low-level radiation defined in broad terms to include the
various sources of ionizing radiation, such as:
 X-rays and radioactive materials used for diagnostic purposes in the healing
arts
 Employment-related exposures in medicine and industry
 Natural background exposure

 The risk estimate for humans getting cancer from low-level
radiation exposure is still controversial.
 No conclusive proof exists that low-level ionizing radiation
doses below 0.1 Sv cause a significant increase in the risk of
malignancy.
 The risk, in fact, may be negligible or even nonexistent.
 Using all data available on high radiation exposure, members
of the scientific and medical communities determined that three
categories of adverse health consequences require study at
low levels of exposures:
 Cancer induction
 Damage to the unborn from irradiation in utero
 Genetic (hereditary) effects

Risk Estimates for Cancer.
 At low doses, below 0.1 Sv, which includes groups such as occupationally exposed
individuals and virtually all patients in diagnostic radiology, this risk is not directly
measurable in population studies. Either the risk is overshadowed by other causes (e.g.,
environmental exposures, genetic predisposition, lifestyle factors such as smoking) of cancer
in humans or the risk is zero.
 Current radiation protection philosophy assumes that risk still exists and may be determined by
EXTRAPOLATING (SCALING DOWN THE RISK-VERSUS-DOSE CURVE) FROM HIGH-DOSE DATA,
in which risk has been directly observed, down to low doses, in which it has not been
observed. This remains a very controversial concept.

MODELS FOR EXTRAPOLATION OF CANCER RISK
FROM HIGH-DOSE TO LOW-DOSE DATA.
■ Researchers commonly use two models for
extrapolation of risk from high-dose to lowdose data
– linear
– linear-quadratic models.

 RADIATION DOSE-RESPONSE RELATIONSHIP
■ Radiobiologists engaged in research have a common goal to establish relationships between
radiation and dose response. The information obtained can be used to attempt to predict the
risk of occurrence of malignancies in human populations that have been exposed to low levels of
ionizing radiation.
■ Radiation dose-response relationship is demonstrated graphically through a curve that maps the
observed effects of radiation exposure in relation to the dose of radiation received.
■ The curve is either linear (straight line) or nonlinear (curved to some degree), and it depicts either
a threshold dose or a nonthreshold dose ( Fig. 9-1 ).

 Risk Model Used to Predict High Dose Cellular Response



THRESHOLD (DETERMENSTIC) below a certain radiation level or dose, no biologic effects are
observed. Biologic effects begin to occur only when the threshold level or dose is reached.


LINEAR THRESHOLD DOSE-RESPONSE CURVE



SIGMOID, OR S-SHAPED ( NONLINEAR ), THRESHOLD CURVE

 Risk Models Used to Predict Cancer Risk and Genetic (Hereditary) Damage in Human Populations (low level
radiation)
 NONTHRESHOLD: indicates that any radiation dose has the capability of producing a biologic effect.
–

NO RADIATION DOSE CAN BE CONSIDERED ABSOLUTELY “SAFE.”

–

Currently, advocates of this point of view theorize that because all radiation exposure levels possess
the potential to cause biologic damage, then radiographers must never fail to employ aggressive
radiation safety measures whenever humans are exposed to radiation during diagnostic imaging
procedures.



LINEAR NONTHRESHOLD CURVE MODEL (LNT)



LINEAR-QUADRATIC NONTHRESHOLD CURVE ( LQNT )

 LINEAR THRESHOLD DOSE-RESPONSE CURVE


Describe the Deterministic effects of significant
radiation exposure such as skin erythema and
hematologic depression



Biologic response does not occur below a specific
dose level.



Laboratory experiments on animals and data from
human populations observed after acute high doses
of radiation provided the foundation for this curve.

 SIGMOID, OR S-SHAPED ( NONLINEAR ),
THRESHOLD CURVE



Employed in radiation therapy to
demonstrate high-dose cellular response to
the radiation within specific tissues such
as skin, lens of the eye, and various types
of blood cells.



Different effects require different minimal
doses.



The tail of the curve indicates that limited
recovery occurs at lower radiation doses.



At the highest radiation doses, the curve
gradually levels off and then veers
downward because the affected living
specimen or tissue dies before the
observable effect appears.

LINEAR NONTHRESHOLD CURVE MODEL (LNT)


Linear curve implies that biologic response to ionizing
radiation is directly proportional to the dose received.



Currently, Committee on the Biological Effects of Ionizing
Radiation BEIR recommends use of LNT dose-response model
for most types of cancers.



Epidemiologic data about the Hiroshima atomic bomb survivors
also indicate that a linear relationship exists between
radiation dose and radiation-induced leukemia.



But it exaggerate the seriousness of radiation effects at lower
dose levels from low-LET radiation. However, it accurately
reflects the effects of high-LET radiation (neutrons and alpha
particles) at higher doses.



In establishing radiation protection standards, the regulatory
agencies have chosen to be conservative—that is, to use a
model that may overestimate risk but is not expected to
underestimate risk.

LINEAR-QUADRATIC NONTHRESHOLD CURVE ( LQNT )

 LINEAR-QUADRATIC curve states that the equation that best
fits the data has components that depend on dose to the first
power (linear or straightline behavior) and also dose
squared (quadratic or curved behavior).
 (BEIR) committee revealed that, most stochastic effects (e.g.,
cancer) and genetic (hereditary) effects at low dose levels
from low–linear energy transfer (LET) radiation, such as the
type of radiation used in diagnostic radiology, appear to
follow a LQNT curve model.


The following health concerns are presumed to follow this
curve:

–

Leukemia

–

Breast cancer

–

Heritable damage

Carcinogenesis.
■ Cancer is the most important late stochastic effect caused by exposure to ionizing
radiation.
■ Cancer is a random occurrence that does not seem to have a threshold and for which
the severity of the disease is not dose related (e.g., a patient’s leukemia induced
by a low-dose exposure is no different from a person’s leukemia that was caused
by a high-dose exposure).

 Cancer caused by low-level
radiation is difficult to identify.
 Human evidence of radiationinduced carcinogenesis comes
from the observation of irradiated
humans and from epidemiologic
studies conducted many years
after subjects were exposed to
high doses of ionizing radiation.
 Examples of these data are listed in
Box 9-2 .

■ Cataractogenesis.
■ The lens of the eye contains transparent fibers that transmit light. The lens focuses
light on the retina so that as the image forms, it may be transmitted through the optic
nerve.
■ The probability that a single dose of ionizing radiation of approximately 2 Gy will induce
the formation of cataracts (opacity of the eye lens) is high.

■ Cataracts result in partial or complete loss of vision.
■ Laboratory experiments with mice show that cataracts may be induced with doses as low
as 0.1 Gy. Highly ionizing neutron radiation is extremely efficient in inducing cataracts.
■ A neutron dose as low as 0.01 Gy has been known to cause cataracts in mice.
■ Radiation induced cataracts in humans follow a threshold.

Embryologic Effects (Utero)

 Developing embryo is characterized by the rapid cells proliferation, migration,
and differentiation. Thus is extremely sensitive to ionizing radiation.

 Response depends on a number of factors including (1) total dose, (2) dose
rate, (3) radiation quality, and (4) the stage of development at the time of
exposure.
 Effects if any as
Prenatal or neonatal death

Congenital abnormalities
Growth impairment
Reduced intelligence
Genetic aberrations

Increase in future risk of cancer.

The period of gestation during which the embryo-fetus is exposed to radiation governs the effects (death or
congenital abnormality) of the radiation. Three stages of fetal development:

1.

Pre-implantation:


begins with the union of the sperm and egg (conception) and continues through day 9 in humans.



if irradiated with a dose in the range of 0.05 to 0.15 Gy, embryonic death will occur.

 For doses less than 100 mGy, the risks are very low.
 all-or-nothing response.

2. Major organogenesis:


period from second to eighth week after conception.



Congenital Abnormalities occurring as a consequence of irradiation during the period of organogenesis
may include: Growth inhibition, Mental retardation, Microcephaly, Genital deformities and Sense organ
damage


only CNS shown an association between malformations and low-LET radiationin doses less than 250 mGy.

–

The central nervous system in the growing human fetus remains undifferentiated and
does not normally complete development until approximately the twelfth year of life.

3. fetal stage:


from end of 6th week post conception



Fewer abnormalities, decreased incidence of prenatal and postnatal death.

Relative sensitivity for radiation-induced
effects during different stages of fetal
development.