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Ionizing radiations in Earths atmosphere and in space near earth
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equatorial geomagnetic
field at Earth’s surface (14). During geomagnetic
storms, charged particles injected into the Van Allen
radiation belts from the outer magnetosphere cause a
sharp increase in the ring current, with a corresponding
decrease in Earth’s equatorial magnetic field (18). The
injected particles precipitate out of the magnetosphere
into the upper atmosphere at high latitudes, causing
auroral activity and interference with electromagnetic
communications.
GALACTIC COSMIC RADIATION
Composition and Sources
Earth is continuously irradiated from all directions by
high-energy charged particles of GCR. GCR particles lose
kinetic energy principally by ejecting orbital electrons
from the atoms with which they interact. The particle
intensity in free space varies from 1.5 particles/(cm2 ·
second) near sunspot maximum to about 4 particles/(cm2 ·
second) near sunspot minimum. All the natural elements
in the periodic table are present in GCR. Outside the
geomagnetic field, the composition of the GCR is 98%
hydrogen nuclei (protons) plus heavier nuclei stripped
of orbital electrons and 2% electrons and positrons (10).
The nuclei component of the radiation, in the energy
range 100 MeV to 10 GeV per nucleon (where intensity
is highest), consists of 87% protons, 12% helium nuclei
(alpha particles), and 1% nuclei with an atomic number
(Z) higher than helium. GCR nuclei with a Z higher than
helium are called HZE particles (high Z and high energy)
(27). Iron-56 is an important HZE particle because of
its significant contribution to the GCR dose and its high
LET (described in the section entitled Expressing Amounts
of Ionizing Radiation) (27). HZE particles are a concern
for space travelers because the particles can injure the
central nervous system (26). HZE particles are not a
concern at airline flight altitudes; they are broken apart
at higher altitudes in the atmosphere.
The principle source of GCR in our galaxy is stellar
material and surrounding interstellar gas, accelerated by
exploding stars (supernovae).
Star formation is initiated by the gravitational attraction
of particles from a molecular cloud, which is a dense
concentration of cold gas (mostly hydrogen) and dust in
space. As the mass of the core of a future star (protostar)
increases, the increased pressure fuses hydrogen into
helium, releasing thermal energy. The thermal energy
increases the temperature of the gases, and they expand
and create an outward pressure that balances the gravitational
forces. After the hydrogen is exhausted the star
begins to contract. What happens next depends on the
mass of the star. There are two ways a star can become
a supernova.
A star at least 8 times the mass of the Sun can evolve directly
into a supernova by the following procedure. As the star
contracts, the pressure in its core created by gravitational forces
increases. When the pressure becomes great enough, fusion of
helium to carbon occurs and thermal energy is released. This
raises the temperature of the gases, temporarily halting the
collapse of the star. When the helium runs out, the star begins
to collapse again, and increasingly heavier elements are fused
but with progressively less thermal energy produced. Fusion
processes culminate with production of nickel-56, which
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produces iron-56 by radioactive decay. Iron and elements of
higher atomic weight do not emit heat on formation. When
nuclear sources are almost exhausted and outward pressure
by the gases is not sufficient to balance gravitational forces,
the core of the star suddenly collapses. This is followed by
collapse of the outer layers of the star, and the star explodes
as a supernova.
A supernova can also evolve from a white dwarf, which
is what remains of a low-mass star after fusion has stopped
and the star has begun to cool. If the white dwarf and
another star orbit each other and the white dwarf accretes
enough matter from the other star to start uncontrolled
fusion of carbon and oxygen, it will explode as a supernova.
A white dwarf may also accumulate enough mass
and explode as a supernova by colliding with another star.
A supernova shines for weeks to months. The star’s
luminocity increases by as much as 20 magnitudes. Li,
Chornock, Leaman, et al. (29) estimated that there are
about 2.8 supernovae in the Milky Way galaxy every
hundred years. This estimate is based on a telescopic
survey of more than 1,000 supernovae in nearby galaxies.
Shock waves of a supernova surge out through space,
occasionally initiating new star formations. These shock
waves are thought to be the primary accelerators of most
GCR particles. However, supernovae are not thought to
be powerful enough to generate the highest-energy GCR
particles. Such particles are believed to come from nearby
galaxies with central black holes. The black holes eject
jets of plasma (a gas with a portion of its components
ionized) into intergalactic space (30).
Hydrogen and helium were probably the most abundant
elements in the early universe, with most of the
rest made inside stars and during supernovae explosions.
Galactic Cosmic Radiation in Earth’s Atmosphere
GCR levels in Earth’s atmosphere vary with latitude
(because of Earth’s magnetic properties), with altitude
(because of Earth’s atmosphere), and with solar activity.
Figure 2 (calculated with CARI-6P [23]) shows effective
dose rates in the atmosphere during solar activity cycles
from January 1958 through December 2008, at several
altitudes at geographic coordinates 0o N, 20o E (where
geographic and geomagnetic equators overlap), and at
80o N, 20o E.
At the high-latitude location, cyclic variation in the
radiation level is evident at 30 kft, which indicates that
low-energy GCR particles reach Earth’s atmosphere
and penetrate down to this altitude. At the equator, the
geomagnetic field repels most low-energy GCR particles
that might otherwise enter the atmosphere during low
solar activity. Consequently, there is little variation in
dose rate at equatorial altitudes.
With increasing depth in the atmosphere, the dose
rate from particles that enter the atmosphere (primary
particles) decreases, whereas the dose rate from particles
created in the atmosphere (secondary particles) increases.
This complex situation results in a maximum dose rate
at the so-called Pfotzer maximum, discovered in the mid-
1930s by the German scientist for whom it is named.
From the altitude of the Pfotzer maximum to the Earth’s
Figure 2. Effective dose rates from GCR in the atmosphere during
several solar activity cycles.
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surface, the dose rate decreases continuously. Using effective
dose rates calculated by LUINNCRP (31): at the
equator, during both the July 1989 solar maximum and
the May 1996 solar minimum, the Pfotzer maximum
was at 56 kft; at the high-latitude location, the altitude
of the Pfotzer maximum varied with solar activity and
was 68 kft during the July 1989 solar maximum and
77 kft during the May 1996 solar minimum.
The next two figures (calculated with CARI-6P [23])
show the proportional contribution to the mean effective
dose rate of each of the principle types of cosmic radiation
particles as related to altitude, at the geographic equator
(Figure 3) and at the high-latitude location (Figure 4),
from January 1958 through December 2008.
The equatorial and high-latitude data both show
that at 20-40 kft, where subsonic air carrier aircraft
commonly cruise, 88-97% of the mean effective dose
rate was from neutrons, protons, and electromagnetic
showers (electrons, positrons, and photons). At sea level,
at the equator, and at the high latitude, more than 67%
of the mean effective dose rate was from muons.
Figure 3. At the geographic equator (0o, 20o E), contribution of the
principal GCR particles to the mean effective dose rate as related to
altitude.
Figure 4. At a high geographic latitude (80o N, 20o E), contribution of
the principal GCR particles to the mean effective dose rate as related
to altitude.
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THE SUN AND ITS EMISSIONS
Layers of the Sun’s Atmosphere
The photosphere is the Sun’s atmospheric layer visible
in white light. Above the photosphere is the chromosphere,
a major source of UV radiation. Above the chromosphere
is the corona, a region of very hot gas.
Sunspots
A sunspot is an area on the photosphere that is seen
as a dark spot in contrast with its surroundings. Sunspots
appear dark because the area is cooler than the
surrounding photosphere.
Sunspots occur where areas of the Sun’s magnetic field
loop up from the surface of the Sun and disrupt convection
of hot gases from below. The sunspot number is
an index of solar activity which is based on the number
of sunspots and groups of sunspots visible on the Sun
(19). For the last 280 years, the sunspot cycle has been
about 11 years, with solar activity increasing for about
4.8 years and decreasing for about 6.2 years (19).
The Sun initiates disturbances in the geomagnetic
field, and disturbances are more common and more
intense when sunspots can be seen. However, intense
geomagnetic disturbances have occurred when no sunspots
were observed, and high sunspot numbers have
accompanied a low level of geomagnetic disturbances
(32).
Solar Wind
The solar wind boils continuously off the Sun,
producing an interplanetary magnetic field. The mass
of the solar wind is about 80% protons, 18% alpha
particles, and traces of heavier charged particles (33).
Discontinuities in the magnetic field carried by the solar
wind (called scattering centers) deflect away from Earth
some low-energy GCR particles that might otherwise
enter the atmosphere (21). During the active phase of
the Sun’s activity cycle, the solar wind is at its most
intense, and this reduces GCR in Earth’s atmosphere to
its lowest levels. At its highest intensity, the solar wind
can adversely affect telecommunication systems, but
particle energies are too low to increase radiation levels
at aircraft flight altitudes (34). Any environmental effect
from increased intensity of charged particles from the
Sun is called space weather.
Coronal Mass Ejection and Solar Flare
Occasionally a magnetic disturbance in the Sun results
in an explosive ejection of huge amounts of matter and
embedded magnetic fields from the solar corona, and
this is called a coronal mass ejection (CME). A CME usually
originates in a magnetically active region around a
visible sunspot group. A large CME can blast billions of
tons of charged particles into space at speeds of 1,700
km per second (33). When a fast CME plows through
the slower moving solar wind, it produces interplanetary
shock waves, which are responsible for showers of highenergy
particles impacting Earth’s atmosphere (19). These
particles impact the atmosphere from all directions (flying
at night is no benefit), and they interact with air atoms
in the same way as GCR particles.
The term solar flare refers to the electromagnetic energy
and particles released suddenly from a relatively small
volume of the Sun (19). CMEs and solar flares have often
been associated (19), but the relationship between them,
if any, is not known. The amount of energy and matter
released during a solar flare is relatively small, compared
to the amount released during a CME. Most CMEs and
solar flares are not directed at the Earth (33). Particles
associated with a solar flare may not have enough energy
to increase radiation levels in Earth’s atmosphere. Photons
from a solar flare begin arriving about 8 minutes after
departing the Sun. The most energetic charged particles
from a CME or from a solar flare reach Earth in 15-20
minutes. The difference in arrival time between photons
and charged particles is due to the longer path the particles
must follow to reach Earth.
Solar Proton Event
A surge of subatomic particles from the Sun is defined
as a solar proton event (SPE) by the Space Weather
Prediction Center of the U.S. National Oceanic and
Atmospheric Administration (NOAA) if instruments on
a Geosynchronous Operational Environmental Satellite
(GOES) measure in three consecutive 5-minute periods
an average solar proton flux ≥10 particles/(cm2 · steradian
· second) with all proton energies >10 MeV (35).
A particle surge that meets these characteristics is most
likely the result of a CME.
RECOMMENDED IONIZING
RADIATION DOSE LIMITS
U.S. Federal Aviation Administration
The FAA accepts the most recent recommendations
of the American Conference of Government Industrial
Hygienists (ACGIH) (36, 37). For a non-pregnant air
carrier crewmember, the FAA-recommended limit for
exposure to ionizing radiation is a 5-year average of 20
mSv per year, with no more than 50 mSv in a single
year. For a pregnant air carrier crewmember, starting
when she reports her pregnancy to management, the
FAA-recommended ionizing radiation exposure limits
for the conceptus are 0.5 mSv in any month and 1 mSv
during the remainder of the pregnancy.
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Radiation exposure as part of a medical or dental procedure
is not subject to recommended limits. However,
any radiation exposure of a pregnant woman should
consider the conceptus.
International Commission on Radiological
Protection
For a non-pregnant, occupationally exposed person, the
ICRP 2007-recommended limit for exposure to ionizing
radiation is a 5-year average of 20 mSv per year (100 mSv
in 5 years), with no more than 50 mSv in a single year.
Annual equivalent dose limits are recommended for the
lens of the eye, 150 mSv; for skin, 500 mSv (averaged
over a 1 cm2 area); each hand, 500 mSv; and each foot,
500 mSv (11).
For a pregnant worker, starting when she reports
her pregnancy to management, the working conditions
should be such that the additional dose to the conceptus
would not exceed about 1 mSv during the remainder of
the pregnancy (11).
Radiation exposure as part of a medical procedure
is not subject to recommended limits. However, before
any pregnant woman is irradiated, the exposure of the
conceptus should be considered.
National Council on Radiation Protection and
Measurements
For a non-pregnant, occupationally exposed person,
the NCRP-recommended limit for exposure to ionizing
radiation is 50 mSv per year, with no more than 10 times
the person’s age in mSv cumulative dose. Annual equivalent
dose limits are recommended for the lens of the eye, 150
mSv; for skin, 500 mSv (averaged over a 1 cm2 area); for
each hand, 500 mSv; and for each foot, 500 mSv (24).
For a pregnant worker, starting when she reports
her pregnancy to management, the working conditions
should be such that the dose to the conceptus does not
exceed 0.5 mSv per month during the remainder of the
pregnancy (24).
For space missions in low-Earth orbit, NCRP recommends
a career limit excess-lifetime-risk of fatal cancer
of 3% and uses sex and age-dependent risk coefficients
(10). NASA follows NCRP recommendations.
The risk coefficients for chronic exposures to low-
LET ionizing radiation (lifetime percent increased risk
of fatal cancer per 100 mSv) are (10): for males (% per
100 mSv) = 0.895 + (-0.0177 x age) + (0.0000750 x age2)
for females (% per 100 mSv) = 1.60 + (-0.0339 x age) +
(0.000172 x age2).
Thus, for a male at least 25 years old but not yet 26,
the risk coefficient would be:
0.895 + (-0.0177 x 25) + (0.0000750 x 252) = 0.499
% per 100 mSv 0.499 % per 100 mSv = 0.00499 per
100 mSv.
If exposed to 32 mSv during that year, his increased
lifetime risk of fatal cancer would be:
32 mSv x 0.00499 per 100 mSv = 1.60 in 1,000 =
160 in 100,000 = 1,600 in 1,000,000.
For acute or high-LET radiation exposure, the risk is
doubled (3,200 in 1,000,000).
Table 8 shows recommended organ dose limits for
space missions in low-Earth orbit.
European Union
According to a Directive issued by the Commission
of the European Communities (39) and an associated
document regarding its implementation (40), assessments
of occupational radiation exposure should be made for
crewmembers likely to be occupationally exposed to more
than 1 mSv in a year. These assessments should include
radiation received on the job from natural sources. Work
schedules for crewmembers should be arranged to keep
annual exposures below 6 mSv. For workers whose annual
exposure exceeds 6 mSv, medical surveillance and record
keeping is recommended. For a pregnant crewmember,
starting when she reports her pregnancy to management,
her work schedule should be such that the equivalent
dose to the child to be born will be as low as reasonably
achievable and unlikely to exceed 1 mSv, either for the
remainder of the pregnancy or for the whole pregnancy,
according to how Article 10 is implemented in national
legislation.
Table 8. Organ dose limits in Sv a recommended by the
NCRP for space missions in low-Earth orbit (38).
Bone Marrow Eye Skin
career Men: 1.5 - 4 x (200 + 7.5 x (age - 30))
Women: 1 - 3 x (200 + 7.5 x (age - 38))
4.0
4.0
6.0
6.0
1 year 0.50 2.0 3.0
30 days 0.25 1.0 1.5
a NASA uses the same numerical limits for dose equivalent in Sv and gray
equivalent in Gy-Eq (10).
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IONIZING RADIATION EXPOSURE
DURING AIR AND SPACE TRAVEL
Radiation Doses Received During Air Travel
The effective dose of GCR to an adult on an aircraft
flight at altitudes <60 kft can be estimated using a computer
program such as CARI-6, which can be run on
the Internet (jag.cami.jccbi.gov/cariprofile.asp). Two
DOS versions of CARI-6 (CARI-6 and CARI-6M) may
be downloaded from the FAA’s Radiobiology Research
Team Web pages (www.faa.gov/data_research/research/
med_humanfacs/aeromedical/radiobiology/). CARI-6P
and CARI-6PM are research-oriented versions available on
request from the authors. CARI-6 and CARI-6P assume
a geodesic flight path; CARI-6M and CARI-6PM follow
user-entered waypoints. The “P” designation indicates
that in the output, the doses from the most important
particles are listed individually, and the effective dose is
reported two ways for protons, using wR
= 2 (current
ICRP and NCRP recommendation) (10, 11) and wR
= 5
(old ICRP recommendation) (12). Information required
for CARI-6 and CARI-6P:
(1) Date of flight;
(2) ICAO code of origin airport;
(3) ICAO code of destination airport;
(4) Number of en route altitudes;
(5) Minutes climbing to first en route altitude;
(6) First en route altitude, in feet;
(7) Minutes cruising at first en route altitude;
(8) Additional en route altitudes (if any), in feet;
(9) For each en route altitude (if any) after the first:
Minutes changing to the en route altitude plus
minutes cruising at the en route altitude;
(10) Minutes descending to destination airport.
Table 9 shows the effective dose (sieverts) from GCR
received on single nonstop one-way air carrier flights
calculated with CARI-6P, using wR
(protons) = 2. Data
in Table 9 and risk coefficients in Tables 10-12 can be
used to estimate cancer risk and genetic effects from
GCR exposure during a career of flying.
From 1 January 1986 through 1 January 2008, there
were 170 solar proton events. During 169 of these events,
Copeland, Sauer, Duke, et al. (22) estimated doses of SCR
and GCR received on simulated high-latitude aircraft
flights. To estimate SCR, they used GOES measurements,
near sea-level neutron-monitor data, and Monte
Carlo calculations. For GCR, they used CARI-6P, with
wR
(protons) = 2.
For each event, they calculated the highest combined
GCR + mean SCR dose received by an adult and the
highest received by a <3-month-old conceptus, in 1, 3,
5, and 10 hours, at altitudes of 30, 40, 50, and 60 kft.
Thus, for each of the 169 events, there were 16 adult
categories and 16 conceptus categories. The highest
value for each of the 32 categories (shown in Table 13)
occurred either during the 29 September 1989 event or
the 16 January 2005 event.
The GCR + mean SCR dose to an adult was always
less than 20 mSv, the annual occupational limit (5-year
average) recommended by the ICRP (12) and the FAA
(36). During 10 of the 169 events, in one or more of the
16 categories for the conceptus, the GCR + mean SCR
dose exceeded the 0.5 mSv monthly limit recommended
by the NCRP (24) and the FAA (36).
The most severe solar proton event for which a record
is available occurred in 1859 (44). Magnetic compasses
went haywire, telegraph systems failed, and auroras were
seen as far south as the Caribbean in the Americas. In
the current high-technology environment, the high levels
of SCR could have damaged electronics on spacecraft,
disabled radio communications, and caused widespread
electrical blackouts. Intense solar activity can heat the
atmosphere, causing it to heat and expand. For a satellite
in low-Earth orbit, such an atmospheric change would
increase the drag on the satellite, causing it to slow
down and change its orbit to lower altitudes. However,
even during the 1859 event, the radiation dose to space
travelers in low-Earth orbit would probably not have
been life-threatening (44).
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Table 9. Flight data and effective dose from low-LET radiation and from high-LET radiation
(calculated with CARI-6Pa) on single nonstop one-way air carrier flights.
1 2 3 4 5 6
Highest In-air Block b Effective dose (mSv)
Origin – Destination alt.(kft) hours hours low-LET high-LET
Solar Minimum (May 1996)
Houston TX – Austin TX 20 0.5 0.6 0.000058 0.0001
Miami FL – Tampa FL 24 0.6 0.8 0.00012 0.00024
St. Louis MO – Tulsa OK 35 0.9 1.1 0.0005 0.0012
London UK – Los Angeles CA 39 10.5 11. 0.017 0.046
Chicago IL – London UK 37 7.3 7.7 0.012 0.032
London UK – Chicago IL 39 7.8 8.3 0.013 0.036
Athens Greece – New York NY 41 9.4 9.7 0.019 0.041
Average Solar Activity in 51 years (1958-2008)
Houston TX – Austin TX 20 0.5 0.6 0.000055 0.000094
Miami FL – Tampa FL 24 0.6 0.8 0.00012 0.00023
St. Louis MO – Tulsa OK 35 0.9 1.1 0.00047 0.001
London UK – Los Angeles CA 39 10.5 11. 0.016 0.039
Chicago IL – London UK 37 7.3 7.7 0.011 0.027
London UK – Chicago IL 39 7.8 8.3 0.012 0.030
Athens Greece – New York NY 41 9.4 9.7 0.017 0.036
Solar Maximum (July 1989)
Houston TX – Austin TX 20 0.5 0.6 0.000053 0.000088
Miami FL – Tampa FL 24 0.6 0.8 0.00011 0.00021
St. Louis MO – Tulsa OK 35 0.9 1.1 0.00044 0.00091
London UK – Los Angeles CA 39 10.5 11. 0.015 0.032
Chicago IL – London UK 37 7.3 7.7 0.010 0.022
London UK – Chicago IL 39 7.8 8.3 0.011 0.025
Athens Greece – New York NY 41 9.4 9.7 0.016 0.031
a CARI-6P output is the effective dose from muons, electromagnetic showers (photons, electrons, and positrons), protons, pions,
and neutrons. For risk estimates, protons, charged pions, and neutrons were considered high-LET radiation; muons and
electromagnetic showers were considered low-LET radiation. Protons, usually considered low-LET radiation, are more damaging
than other low-LET radiation, causing damage similar to that produced by heavy ions (41). Therefore, we included protons with
high-LET radiation, which may overestimate risk.
b Block hours start before takeoff from the origin airport, after the aircraft door is closed and the brake is released. Block hours
end after landing at the destination airport, the last time the brake is set before the aircraft door is opened.
14
Table 9 continued
Example 1 A crewmember worked 700 block hours per year for 25 years flying between Athens, Greece and New York, NY
(block hours defined in footnote b). Assuming average solar activity for each flight, what is the crewmember's increased lifetime
risk of fatal cancer? Flight data are in Table 9. Risk coefficients for fatal cancer are in Table 10.
Risk from low-LET radiation (doses in column 5):
700 block hours per year x 25 years = 17,500 block hours in 25 years
0.017 mSv per flight / 9.7 block hours per flight = 0.00175258 mSv per block hour
0.00175258 mSv per block hour x 17,500 block hours in 25 years = 30.67015 mSv in 25 years
fatal cancer risk = 3.1 in 100,000 per mSv x 30.67015 mSv in 25 years = 95.077465 in 100,000 = 95.08 in 100,000
Risk from high-LET radiation (doses in column 6):
0.036 mSv per flight / 9.7 block hours per flight = 0.00371134 mSv per block hour
0.00371134 mSv per block hour x 17,500 block hours in 25 years = 64.94845 mSv in 25 years
fatal cancer risk = 6.3 in 100,000 per mSv x 64.94845 mSv = 409.175235 in 100,000 = 409.18 in 100,000
Risk from low-LET radiation + high-LET radiation = 95.08 in 100,000 + 409.18 in 100,000 = 504.28 in 100,000 = 5 in 1,000
****
Example 2 Before conceiving children, one parent worked 700 block hours a year for 5 years flying between Athens, Greece,
and New York, NY, and the other parent did not fly. Assuming average solar activity for each flight, what is the risk of genetic
defects in the first two successive generations? Flight data are in Table 9. Risk coefficients for genetic defects are in Table 11.
Risk from low-LET radiation (doses in column 5):
700 block hours per year x 5 years = 3,500 block hours
0.017 mSv per flight / 9.7 block hours per flight = 0.00175 mSv per block hour
0.00175 mSv per block hour x 3,500 block hours in 5 years = 6.125 mSv in 5 years
genetic risk = 1.2 in 1,000,000 per mSv x 6.125 mSv in 5 years = 7.35 in 1,000,000
Risk from high-LET radiation (doses in column 6):
0.036 mSv per flight / 9.7 block hours per flight = 0.0037 mSv per block hour
0.0037 mSv per block hour x 3,500 block hours in 5 years = 12.95 mSv in 5 years
genetic risk = 2.4 in 1,000,000 per mSv x 12.95 mSv = 31.08 in 1,000,000
Risk from low-LET radiation + high-LET radiation = 7.35 + 31.08 = 38.43 in 1,000,000 = 4 in 100,000
Table 10. Increased lifetime risk of fatal cancer from
ionizing radiation (11).
Whole population a Age group 18-64 years
---- 8.0 in 100,000 per mSv 6.3 in 100,000 per mSv
DDREF = 2 4.0 in 100,000 per mSv 3.1 in 100,000 per mSv
a In the U.S in 1998, cancer caused 23.2% of deaths among persons of all ages and
10.6% of deaths among children ages 1-14 years (42).
Table 11. Increased risk of genetic effects in first two
successive generations (children and grandchildren), from
ionizing radiation exposure prior to conception (11).a
Whole population a Age group 18-64 years
---- 0.4 in 100,000 per mSv 2.4 in 1,000,000 per mSv
DDREF = 2 0.2 in 100,000 per mSv 1.2 in 1,000,000 per mSv
a In the general population, 2-3% of live-born children have harmful abnormalities
at birth (43).
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Table 12. Increased lifetime risk of cancer (non-fatal or
fatal) from ionizing radiation (11).
Whole population a Age group 18-64 years
---- 34 in 100,000 per mSv 23 in 100,000 per mSv
DDREF = 2 17 in 100,000 per mSv 12 in 100,000 per mSv
Table 13. Highest GCR + mean SCR effective doses to an adult
and highest GCR + mean SCR equivalent doses to a
<3-month-old conceptus, on simulated high-latitude aircraft
flights during 169 solar proton events.
Effective dose to an adult (Equivalent dose to Altitude a conceptus) (mSv)
(kft) 1 h a 3 h 5 h 10 h
29 September 1989 event
30 --- 0.098 (0.11) 0.14 (0.16) 0.20 (0.22)
40 --- 0.27 (0.30) 0.39 (0.43) 0.57 (0.63)
50 --- --- 0.84 (0.90) 1.3 (1.4)
60 --- --- --- 2.6 (2.4)
16 January 2005 event
30 0.048 (0.050) --- --- ---
40 0.16 (0.17) --- --- ---
50 0.42 (0.44) 0.68 (0.72) --- ---
60 0.90 (0.83) 1.5 (1.4) 1.8 (1.7) ---
a 1, 3, 5, or 10 hours of continuous exposure
Radiation Doses Received During Space Travel
Commercial space flights, in the next decade or so,
are expected to be limited to suborbital flights and trips
to the ISS, with suborbital flights the more common.
Travelers on suborbital flights are exposed to trapped
radiation, GCR, and SCR.
It is expected that the suborbital flights will be primarily
like that of SpaceShipOne, a rocket carried aloft
and launched at high altitude from a carrier aircraft, or
else something like the early ballistic flights of the Mercury
program. These kinds of flights usually spend ≤15
minutes at high altitudes and in space. GCR should be
the primary source of ionizing radiation exposure. The
flight path can be chosen to avoid the trapped radiation
of the South Atlantic Anomaly and the timing selected
to avoid SCR hazards. Doses to vehicle occupants are
expected to be quite low during the rocket-powered and
freefall portions of the flight. For example, the effective
dose (calculated with LUINNCRP [31] from the flight
profile) to Alan Shepard on the Mercury 3 mission was
0.00031 mSv.
For tourists going to the ISS, the trip is typically 7-10
days, and doses will be considerably higher than on
suborbital flights. The trapped radiation of the South
Atlantic Anomaly cannot be avoided. Also, the orbit of
the ISS is at a high inclination, so for part of each orbit,
it is outside latitudes well-protected by Earth’s magnetic
field, and ISS occupants receive little protection from
GCR. While of low probability, SCR is also a possible
radiation hazard.
An example of a trip to the ISS orbit is STS-91, a
9.8-day space shuttle mission, during which the effective
dose equivalent to the astronauts, based on in-flight
measurements, was 4.1 mSv (45).
HEALTH EFFECTS OF
IONIZING RADIATION
Deterministic Effects (Non-Stochastic Effects,
Tissue Reactions)
Most tissues of the body can lose a substantial number
of cells without an observable decrease in tissue or organ
function. However, if the number of cells lost is sufficiently
large, harm will be observed. Harm from ionizing radiation
is called deterministic if the harm increases with radiation
dose above a threshold dose (12). The threshold dose is
the dose below which no harm is observed, or the harm
is not clinically significant. For most deterministic effects
16
from low-LET radiation, the threshold dose is higher if
the exposure time required to reach the dose is more than
a few hours (46). Deterministic effects can occur soon
(sometimes minutes) after radiation exposure if the dose
is sufficiently high and delivered at a high rate.
The effect of radiation on the hematopoietic system
is largely dependent on damage to the bone marrow.
The bone marrow contains three cell renewal systems:
erythropoietic, myelopoietic, and thrombopoietic. Normally,
a steady-state condition exists between production
of new cells by the bone marrow and the number of
mature, functional cells in the circulating blood. The
erythropoietic system produces mature erythrocytes (red
blood cells) with a lifespan of approximately 120 days.
Red blood cells carry oxygen from the lungs to the rest
of the body and carry away some of the carbon dioxide.
The myelopoietic system produces mature leukocytes
(white blood cells) with a lifespan of approximately 8
days. White blood cells are important in combating
infection. The thrombopoietic system produces platelets
with a lifespan of 8-9 days. If the endothelial lining of a
blood vessel is traumatized, platelets are stimulated to go
to the site of injury and form a plug, which helps reduce
blood loss. Platelet deficiency causes one to bruise easily
and even hemorrhage.
The intestines are highly vulnerable to radiation
damage. The mucosal layer that lines the intestines is
completely renovated every 72 hours. Injury of the microvasculature
of the mucosa and submucosa, together
with epithelial-cell denudation, results in hemorrhage
and marked loss of fluids and electrolytes. These events
normally occur within 1-2 weeks after irradiation.
Early deterministic effects of ionizing radiation are
called Acute Radiation Syndrome (ARS). Symptoms during
the first stage of this illness (nausea, fatigue, vomiting,
and diarrhea) occur within minutes to days after exposure;
they may come and go for several days, unless the
dose is totally incapacitating or lethal before then. The
irradiated individual usually looks and feels healthy for
short periods of time. During the next stage, there may
be a loss of appetite, nausea, fatigue, vomiting, diarrhea,
fever, seizures, and coma. This seriously-ill stage may last
from a few hours to several months and end with death
from infection and/or internal bleeding. The symptoms
and time to onset of symptoms, and their severity and
duration, generally depend on the absorbed dose. There
are significant differences among individuals. The cause
of death is usually from infections and internal bleeding
because of bone marrow damage. Some late deterministic
effects are cataracts and a decrease in germ cells.
To date, cataract formation is the only deterministic
effect associated with exposure to ionizing radiation in
space (26). Excess cataracts have been seen in former
astronauts who received <2 Gy of high-LET radiation
(47). Table 14 lists deterministic effects in young adults
from an acute whole-body dose of ionizing radiation.
Survivors of deterministic effects are at risk of stochastic
effects (48).
Table 14. Deterministic effects in young adults from a whole-body Gy-Eq a of ionizing radiation received
in <1 day.
Gy-Eq Effects
0.15 Threshold dose for temporary sterility in males (46).
0.35 Within a few hours, some suffer nausea, weakness, and loss of appetite. Symptoms disappear a few hours after
appearing (46).
1-2 After 2-3 hours, nausea and vomiting in 33-50% (48).
1.5 Threshold dose for mortality (27).
2 Permanent sterility in premenopausal females (9). Minimum cataract dose (10).
2-4 Mild headache in about 50%. Almost constant nausea and vomiting in 70-90% (49). There may be initial
granulocytosis, with pancytopenia 20-30 days after irradiation. Possible later effects are infections, hemorrhage,
and impaired healing (49). The latent period for cataracts is normally about 8 years, after 2.5-6.5 Gy (9).
3.5-6 Threshold dose for permanent sterility in males (11).
4 About 50% die within 60 days from hematopoetic failure (11). It has been reported for adult males, that shielding
10% of the active (red) bone marrow will result in almost 100% survival (48). Locations and percent of total bone
marrow in adults are in Table 15.
5-7 Up to 100% vomit within 2 days (27). Mortality about 90% within 60 days (11).
>8 Within minutes, there may be severe nausea, vomiting, and watery diarrhea. After 1-2 hours, there is almost
constant severe headache (49). There may be renal failure and cardiovascular collapse. Mortality 100%, usually
within 8-14 days (49).
>20 Often, burning sensation within minutes. Nausea and vomiting within 1 hour, followed by prostration, ataxia, and
confusion (49). Mortality 100%, usually within 24-48 hours (49).
a Described in the section entitled Ionizing Radiation Terminology.
17
Stochastic Effects
Harm from ionizing radiation is called a stochastic
effect (expressed in sieverts) if the probability (risk), but
not the severity of the effect, is a function of the effective
dose. It is believed that there is no threshold dose for
stochastic effects (9). Stochastic effects include cancer,
genetic disorders in succeeding generations, and loss of
life from such effects. The risk is cumulative and persists
throughout the life of the exposed person. Thus, individuals
exposed to ionizing radiation have an increased
lifetime risk of cancer, and their progeny have an increased
risk of inheriting genetic disorders.
Radiation-induced cancers cannot be distinguished
from cancers of the same type in the unirradiated population,
and it cannot be predicted which individuals in
an irradiated group will develop cancer (43). Regardless
of age when irradiated, radiation-induced tumors tend
to appear when tumors of the same type occur in the
unirradiated population (9).
In Tables 10, 11, and 12 are estimates of the increased
lifetime risk of cancer and of heritable effects from a
whole-body dose of ionizing radiation for a member of
the whole population and for a member of the workingage
population (18-64 years). If the radiation is low LET
(electrons, photons, positrons, or muons) and <200 mSv
and/or <100 mSv/hour, then the estimated risk is half
that found by linear extrapolation from the high-dose
region, and the DDREF = 2 (DDREF is the dose and
dose-rate effectiveness factor) (12, 11).
Thus, for a person in age group 18-64 years who receives
a single acute dose of whole-body radiation <200
mSv: (a) the increased lifetime risk of fatal cancer from
high-LET radiation is 6.3 in 100,000 per mSv (Table
10) and is about 52% of the increased lifetime risk of
cancer (non-fatal or fatal) from low-LET radiation, which
is 12 in 100,000 per mSv (Table 12); (b) the increased
lifetime risk of fatal cancer from low-LET radiation is
3.1 in 100,000 per mSv (Table 10) and is about 26% of
the increased lifetime risk of cancer (non-fatal or fatal),
which is 12 in 100,000 per mSv (Table 12).
Commonly occurring cancers, induced as stochastic
effects of ionizing radiation, are shown in Table 16.
Prenatal Irradiation
Exposure to a high dose of ionizing radiation in the
first 3 weeks after conception may kill a conceptus but
is not likely to cause deterministic or stochastic effects
in a live-born child. However, irradiation in the period
from 3 weeks after conception until the end of pregnancy
may cause deterministic and stochastic effects in a liveborn
child (12).
A dose <100 mGy to a conceptus is not considered a
justification for terminating a pregnancy (48).
RADIOACTIVE CONTAMINATION IN
EARTH’S ATMOSPHERE
Regions of the atmosphere sometimes become contaminated
with radioactive gases and particles released
from a nuclear reactor (as the result of an accident or terrorist
attack) or from a detonated dirty bomb or nuclear
weapon. These radioactive contaminants may travel long
distances in the wind. Radioiodines are the chief gaseous
isotopes of concern after nuclear explosions, and inhalation
problems with fission products other than iodine
are minor (51). In Belarus (formerly part of the Soviet
Union), in the 10-year period before the Chernobyl
reactor accident, 1,342 adult and 7 childhood thyroid
cancers were diagnosed, whereas during the 9-year period
after the accident 4,006 adult and 508 childhood thyroid
cancers were reported (52).
Potassium iodide (KI) blocks iodine uptake by the
thyroid gland. It should be taken daily at the doses recommended
in Table 17, from the first warning of the possible
release of radioactive iodine until the risk of significant
inhalation or ingestion of radioactive iodine no longer
exists. Potassium iodide protects the thyroid gland for
approximately 24 hours. Treatment is most effective if it
begins between 2 days before and approximately 8 hours
after inhalation or ingestion of radioactive iodine (54).
Starting treatment 16 or more hours after radioactive
iodine exposure provides little protection (54). It probably
should not be taken for more than 10 days. After
leaving a contaminated area, potassium iodide should
be taken for at least another day to allow the kidneys
time to eliminate radioactive iodine that is in the blood.
For persons <20 years of age, the risk of thyroid cancer
decreases with increase in age at the time of irradiation.
There is little risk of thyroid cancer after age 40 (52).
However, if the dose to the thyroid is 200-300 Gy or
more, the thyroid parenchyma (functional tissue) will
Table 15. Distribution of active (red)
bone marrow in adults (48).
Percent
sternum 3
cervical vertebrae 4
upper limbs 4
skull 7
thoracic vertebrae 10
lumbar vertebrae 11
lower limbs 11
ribs 19
pelvis 30
18
Table 17. Recommended daily dose of
potassium iodide, if radioactive iodine has been
released into the atmosphere (52).
Persons at risk a
Daily dose of
potassium iodide
(mg)
pregnant or breast feeding 130
>18 years 130
>12 years through 18 years and ≥70 kg. 130
>12 years through 18 years and <70 kg 65
>3 years through 12 years 65
>1 month through 3 years 32
birth through 1 month 16
a Protects for approximately 24 hours.
Table 16. Commonly occurring cancers with ionizing radiation as a risk factor (stochastic effects).
Leukemia Shortest latent period of radiation-induced cancers (9). Minimum latent period 2-3 years (46). Peak
incidence 5-7 years after irradiation, with most cases in first 15 years (9). Acute leukemia and chronic
myeloid (myelocytic) leukemia are the main types in irradiated adults (9). Susceptibility to acute lymphatic
leukemia (stem-cell leukemia, leukemia too premature to classify) is highest in childhood and decreases
sharply during maturation (9). Chronic lymphocytic leukemia (CLL) is not radiation-induced (9).
Lung cancer Most common cancer worldwide and the major cause of death from cancer (7). With increase in age at
exposure, the latent period decreases and the risk increases (10). Dose-fractionation decreases risk (based on
low-LET radiation) (10) Radon causes about 10% of lung cancer deaths in the U.S. (9).
Breast cancer Among women world-wide, the most common cancer and one of the leading causes of death from cancer
(7). Risk highest if irradiated before age 15 years, with little or no risk if irradiated at age 50 or older (9).
Family history is a strong predictor of risk (7). Dose-fractionation data conflicting (10). Risk reduced by
ovariectomy (oophorectomy) or pregnancy at an early age (10).
Gastrointestinaltract
cancer
(esophagus,
stomach, colon, and
rectum)
15-20% of benign colorectal tumors become malignant (10). In the general U.S. population, lifetime risk of
developing gastrointestinal-tract cancer is 2.5-5%, but is 2-3 times higher in persons with a first-degree
relative (father, mother, brother, sister, child) who had colon cancer or an adenomatous polyp (50).
Bone cancer External X-radiation may cause bone cancer, but the numbers are small and the risk estimates are poor (9).
Liver cancer Risk from high-LET radiation, but uncertain if risk from low-LET radiation (10).
Kidney and bladder
cancer
Risk from radiation (10).
Skin cancer Most common cancer in Caucasians in the U.S. Latent period about 25 years. Skin exposed to low-LET
radiation and sunlight (presumably from ultraviolet radiation) is at greater risk than skin protected from
sunlight by hair, clothing, or pigmentation. Ionizing radiation causes basal-cell and squamous-cell
carcinomas, but no unequivocal association has been found for ionizing radiation exposure and melanoma
(the most malignant skin cancer). In fair-skinned individuals, radiation from sunlight or sunlamps is a risk
factor for melanoma and other skin cancers. Skin cancer can develop in areas not exposed to sunlight. Skin
cancer can develop in dark-skinned individuals. Family history is a predictor of risk (27).
Thyroid cancer Risk to a child is significant if dose ≥0.05 Gy. Little or no risk if 30 years or older. Most likely radiation
source is radioactive iodine (I-131) released into the atmosphere from a nuclear reactor, as the result of an
accident or terrorist attack. Radioactive iodine is also a major constituent of detonated nuclear weapons.
Radioactive iodine is incorporated by the thyroid gland and the radiation increases the risk of thyroid cancer
(10).
19
be destroyed (48). A person >40 years of age should
take potassium iodide only if the predicted dose is >5
Gy, to prevent hypothyroidism (53). The risk to a child
is significant if the dose to the thyroid is ≥0.05 Gy (53).
Radioactive iodine easily crosses the placenta (48),
and the fetal thyroid begins to accumulate iodine at
about 10 weeks of gestational age. After 8 weeks postconception,
giving the mother 60-130 mg of potassium
iodide within 12 hours of radioactive iodine intake will
reduce uptake of radioactive iodine by the fetal thyroid
(48). Health risks from stable iodine, a component of
potassium iodide, include sialadenitis (inflammation of
the salivary gland), gastrointestinal disturbances, allergic
reactions, and minor rashes. Persons with iodine sensitivity
should avoid potassium iodide, as should individuals
with dermatitis herpetiformis and hypocomplementemic
vasculitis (rare conditions associated with increased risk
of iodine hypersensitivity) (52).
Because radioactive iodine has a physical half-life of
8.04 days, food affected by radioactive iodine fallout poses
very little risk if stored 2 months or longer.
Other possibly important radioactive substances that
could be released into the atmosphere from a nuclear
reactor, detonated nuclear weapon, or dirty bomb, along
with the annual allowable levels of intake (ALIs) for U.S.
radiation workers, are listed in Table 18. Some possible
therapies are listed in Table 19. The ALI for each isotope
is the intake of that isotope that results in a committed
effective dose approximately equal to the NRC limit for
radiation workers and the FAA recommended limit for
any one year (50 mSv) (55).
If possible, flying through radioactively contaminated
air space should be avoided. If crewmembers are exposed
to multiple isotopes, the ALI for each isotope should
be reduced to keep the total committed effective dose
at or below the FAA-recommended limit. A pregnant
crewmember should avoid any exposure that results
in the dose to the conceptus exceeding recommended
limits (0.5 mSv in any month and 1 mSv total during
her declared pregnancy). The maximum dose rate from
radioactive materials on board the aircraft should not
exceed 0.02 mSv per hour in any occupied space (57).
Table 18. Nuclear Regulatory Commission Annual Allowable Levels of Intake
(ALI)a,b for Selected Radionuclides (55).
Ingestion (μCi) Inhalation (μCi)
Isotope <10 d 10-100 d >100 d <10 d 10-100 d >100 d
Americium-241 0.8 0.006
Cesium-137 100 200
Cobalt-60 ---- 500 200 ---- 200 30
Iodine-125 40 60
Iodine-131 30 50
Iridium-192 900 300 400 200
Palladium-103 6000 6000 4000 4000
Phosphorus-32 600 900 400 ----
Plutonium-239 0.8 ---- 0.006 0.02
Radium-226 2 0.6
Strontium-90 30 20 ---- 4
Tritium (hydrogen-3) 80000 80000
Uranium-233 10 1 0.7 0.04
Uranium-234 10 1 0.7 0.04
Uranium-235 10 1 0.8 0.04
Yttrium-90 400 ---- 700 600
a One ALI gives an effective dose of about 50 mSv. The radiation worker is assumed to be doing light labor
while wearing no protective gear.
b If more than one isotope is involved, the procedure to find whether or not the exposure exceeds the intake
limit is to divide each intake by its respective ALI and then sum the resulting fractions. If the sum is >1, the
ALI has been exceeded.
c The various compounds incorporating these isotopes have different lifetimes in the body. In this table
allowable levels of intake for these isotopes are subdivided into 3 groups, based on their retention times in the
body: “D” < 10 days; “W” 10-100 days; and “Y” > 100 days. If there is no D, W, or Y, then the allowable
level of intake is applicable to all compounds which incorporate that isotope, whatever their lifetime in the
body.
20
Table 19. Drugs used to treat persons contaminated with radioactive materials (56).
Ammonium
chloride
This salt acidifies the patient’s blood, and is useful for the removal of strontium, especially when combined
with intravenous calcium gluconate. Ammonium chloride is given orally, 1-2 gm 4 times per day, for up to
6 consecutive days. While best results occur if given quickly after intake, some effect is seen if used up to
two weeks afterwards. If used promptly with calcium gluconate, strontium levels can diminish 40-75 %.
Nausea, vomiting, and gastric irritation are common. Avoid in patients with severe liver disease.
Calcium (oral) Many oral calcium supplements are available (e.g., Tums®;). Generous doses of oral calcium should be
beneficial, because calcium can interfere with absorption of the other alkaline earths, such as strontium,
barium, and radium, and compete with their deposition in bone.
Ca-DTPA (also
Zn-DTPA)
This is a powerful and stable chelating agent, used primarily to remove plutonium and americium. It
chelates transuranic (Z>92) metals (plutonium, americium, curium, californium, and neptunium), rare earths
(such as cerium, yttrium, lanthanum, promethium, and scandium), and some transition metals (such as
zirconium and niobium). In normal, healthy, non-pregnant adults with normal bone marrow and renal
function, the dose to use is 1 gm in 250 ml normal saline or 5% dextrose in water, intravenously over 1
hour. 1 dose per day should be used, and the dose should not be fractionated. May use for several days to a
week in most cases without toxic effects. Toxicity is due to chelation of needed metals, such as Zn and Mn.
Toxic effects include nausea, vomiting, chills, diarrhea, fever, pruritus, muscle cramps, and anosmia. In
pregnant patients or after a couple of doses, the less toxic Zn-DTPA should be used instead, with the same
dose and dose schedule. These agents are best used as quickly as possible after internal contamination. They
are effective if given later, but therapy may continue for months or years. These agents are only effective if
the metals one wishes to chelate are in ionic form. They are useless for highly insoluble compounds.
Calcium
gluconate
Intravenous calcium gluconate is indicated for Sr-90 contamination, and probably Ra-226 contamination as
well. Five ampoules, each containing approximately 500 mg calcium, may be administered in 0.5 liter 5%
dextrose solution over a 4 hour period daily for 6 consecutive days. It is contraindicated in patients who
have a very slow heart rate and those on digoxin preparations or quinidine.
Dimercaprol
(British
antilewisite,
BAL)
This agent effectively chelates mercury, lead, arsenic, gold, bismuth, chromium, and nickel. It is toxic, and
about 50% of patients given 6 mg/kg intramuscular injections develop reactions. These include systolic and
diastolic hypertension, tachycardia, nausea, vomiting, chest pain, headache, and sterile abscess at the
injection site. The dose to use is 2.5 mg/kg (or less) every 4 hours for 2 days, then twice daily for 1 day, and
then every day for days 5-10. It is available as 300 mg/vial for deep intramuscular injection use (suspension
in peanut oil).
D-Penicillamine This drug chelates copper, iron, mercury, lead, gold, and possibly other heavy metals. The chelated metals
are excreted in the urine. While this drug is relatively non-toxic, it probably has only limited usefulness for
radionuclide decorporation, preventing perhaps only 1/3 of the total radiation absorbed dose that would
have occurred without treatment. The adult dose is 250 mg orally daily between meals and at bedtime. May
increase to 4 or 5 g daily in divided doses. Use caution if patient has a penicillin allergy
Potassium iodide Useful for blocking radioiodine uptake by the thyroid, but needs to be administered within 8 hours of intake
for best effectiveness. See Table 17 for dosing information.
Potassium
phosphate (and
sodium
phosphate)
Used to block uptake of radioactive phosphate. K-Phos® Neutral contains 250 mg phosphorus per tablet.
Usual adult dose is 1-2 tabs orally 4 times per day, with full glass of water each time, with meals and at
bedtime. Pediatric patients over 4y, 1 tab 4 times per day. Contraindicated in hyperphosphatemia, renal
insufficiency, and infected phosphate stones.
Propylthiouracil This drug is useful to decrease the thyroid’s retention of radioiodine, and may be considered if it is too late
for KI to be effective. The adult dose is 50 mg tabs, 2 orally 3 times per day for 8 days.
Prussian blue This drug is indicated for decorporation of cesium, thallium, and rubidium, and has been shown to be highly
effective for Cs-137 contamination. It is benign, with the exception of occasional constipation. Stool turns
blue. Usual dose starts at 0.5 g capsule, 2 caps orally 3 times per day for up to 3 weeks or longer as
required. Doses up to 10-12 g/day for significantly contaminated adults may be used.
Sodium alginate Oral alginates efficiently bind strontium in the gastrointestinal tract, preventing absorption. The dose is 10
gm powder in a 30 cc vial, add water and drink.
Sodium
bicarbonate
Used to protect kidneys from uranium deposition after uranium intake. Oral or intravenous, take as needed
to maintain alkaline urine. The intravenous formulation is 8.9%, 100 or 200 cc vials.
Sodium
phosphate
See potassium phosphate. Also used for radioactive phosphate decorporation.
Zn-DTPA See Ca-DTPA.
21
When an aircraft is contaminated or suspected of contamination
with radioactive materials, it must be removed
from service and not returned to service until the dose
rate from radioactive contaminants at every accessible
surface is <0.005 mSv per hour (58).
Lightning and TErrestrial
Gamma-Ray Flashes
Dwyer, Smith, Uman, et al. (59) recently reviewed
the subject of ionizing radiation emitted from thunderstorms,
citing 66 references. The following is a summary
of the article.
X-rays and gamma rays are emitted by thunderclouds
and are associated with lightning. On average, each commercial
aircraft is struck by lightning about once every
3,000 flight hours. Also, large bursts of gamma rays emanating
from our atmosphere, called terrestrial gamma-ray
flashes (TGFs), have been observed by spacecraft since
1994. In both lightning and TGFs, the high-energy
emissions are believed to occur when electrons in air
traveling at very close to the speed of light collide with
the nuclei of air atoms.
There are many unknowns, including the occurrence
rate of TGFs relative to lightning, the effect of the aircraft
triggering the lightning, and the frequency and lengths
of electron acceleration regions in thunderstorms. The
estimated dose received by an individual in an aircraft
struck by TGF- or lightning-energetic electrons is about
30 mSv. Thus, a significant number of aircraft occupants
may receive a large radiation dose. Direct measurements
have not been made.
CONCLUDING REMARKS
In a Presidential Document, it is recommended that
individuals occupationally exposed to ionizing radiation
be instructed on its health risks (60).
The FAA recommends that air-carrier crews be informed
about their radiation exposure and the associated
health risks (61). The FAA mandates that information on
risks of space travel be provided to space flight participants
prior to their participation on space flights under
its jurisdiction (62).
This report can be used as a source book for instruction
on ionizing radiation exposure of air and space travelers.
It provides information on: (a) its basic characteristics,
(b) the types that will be encountered during air and
space travel, (c) its natural sources, (d) exposure levels
and associated health risks.
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NASA Facts
National Aeronautics and
Space Administration
Lyndon B. Johnson Space Center
Understanding Space Radiation
FS-2002-10-080-JSC
October 2002
• Altitude above the Earth – at higher altitudes the Earth’s
magnetic field is weaker, so there is less protection against
ionizing particles, and spacecraft pass through the trapped
radiation belts more often.
• Solar cycle – the Sun has an 11-year cycle, which culminates in
a dramatic increase in the number and intensity of solar flares,
especially during periods when there are numerous sunspots.
• Individual’s susceptibility – researchers are still working to
determine what makes one person more susceptible to the
effects of space radiation than another person.
Measuring Radiation
The absorbed dose of radiation is the amount of energy
deposited by radiation per unit mass of material. It is measured
in units of rad (radiation absorbed dose) or in the international
unit of Grays (1 Gray = 1 Gy = 1 Joule of energy per kilogram
of material = 100 rad). The mGy (milliGray = 1/1000 Gray) is
the unit usually used to measure how much radiation the body
absorbs. However, because different types of radiation deposit
energy in unique ways, an equivalent biological dose is used to
estimate the effects of different types of radiation. Equivalent
dose is measured in milliSieverts (mSv). The mSv, therefore,
takes into account not only how much radiation a person
receives, but how much damage that particular type of radiation
can do – the greater the possibility of damage for the same dose
of radiation, the higher the mSv value.
Crews aboard the space station receive an average of 80 mSv
for a six-month stay at solar maximum (the time period with the
maximum number of sunspots and a maximum solar magnetic
field to deflect the particles) and an average of 160 mSv for a
six-month stay at solar minimum (the period with the minimum
number of sunspots and a minimum solar magnetic field).
Although the type of radiation is different, one mSv of space
radiation is approximately equivalent to receiving three chest
x rays. On Earth, we receive an average of two mSv every year
from background radiation alone.
Crew members could receive higher doses of space radiation
during space walks while outside the protective confines of the
space station; however, NASA plans space walks to avoid the
trapped radiation belts around the Earth, and doses on previous
space walks have been kept very small.
Protecting Current and Future Space Station Crews
To determine acceptable levels of risk for astronauts, NASA
follows the standard radiation protection practices recommended
by the U.S. National Academy of Sciences Space Science
Board and the U.S. National Council on Radiation Protection
and Measurements.
Aboard the space station, improving the amounts and types of
shielding in the most frequently occupied locations, such as the
sleeping quarters and the galley, has reduced the crew’s exposure
to space radiation. Materials that have high hydrogen contents,
such as polyethylene, can reduce primary and secondary
radiation to a greater extent than metals, such as aluminum.
Space station crew members each wear physical dosimeters, and
also undergo a biodosimtery evaluation measuring radiation
damage to chromosomes in blood cells (see figure above).
Active monitoring of space radiation levels also can help reduce
the levels of radiation an astronaut receives by helping the
astronauts locate the best-shielded locations on the station.
The monitoring also serves as a warning should radiation levels
increase due to solar disturbances. Following a healthy diet and
lifestyle, including the use of antioxidants following radiation
exposure, should also reduce risks.
Radiation Measurements Aboard
the International Space Station
Below, in alphabetical order, are the many radiation measurement
devices and experiments that have flown to the
International Space Station.
Bonner Ball Neutron Detector
March – December 2001
A Japanese Space Agency experiment that measured the amount
of neutron radiation that entered the space station. Neutron radiation
can affect the blood-forming marrow in bones.
Charged Particle Directional Spectrometers – CPDS
2001 – present
There are three units mounted outside on the station’s S0 truss
that are designed to record the direction from which radiation
strikes. There is another unit inside the station.
Dosimetric Mapping – DOSMAP
March – August 2001
A German Space Agency/European Space Agency experiment
that consisted of four different types of radiation detectors
located throughout the space station, These measured the
amounts and types of radiation that entered the ISS.
Study of Radiation Doses Experienced by Astronauts
in EVA – EVARM
February 2002 – present
These sensors are being used to determine the levels of radiation
space walkers receive in their skin, eyes and blood-forming
organs. EVARM consists of three active dosimeters (placed on
Normal chromosome No. 2
and No. 4 in a postflight
metaphase sample
Damaged chromosome No. 2
in a postflight metaphase
sample
the leg, torso and near the eye) that are read before and after a
space walk. The EVARM data could be used to devise methods
of reducing the amount of radiation astronauts are exposed to
during space walks.
Passive Dosimetry
1999 – present
There are several types of radiation detectors aboard the space
station. The radiation area monitor (RAM) is a small set of thermoluminescent
detectors encased in Lexan plastic that respond
to radiation – the amount of radiation they absorb can be revealed
by applying heat and measuring the amount of visible light
released. RAM units are scattered inside the space station and
are returned to Earth for measurement after periodic space
shuttle visits. The crew passive dosimeter is very similar to
the RAM and is carried by each member of the crew. The
AN/UDR-13 radiac Set (a high-rate dosimeter) is a compact,
handheld or pocket-carried device capable of quickly measuring
doses of gamma or neutron radiation. Data readout and warning
messages are provided by a liquid crystal display on the set.
Phantom Torso
March – August 2001
This unique experiment
measured the effects of
radiation on organs inside
the human body by using
a torso equivalent in
height and weight to an
average adult male. The
torso contained radiation
detectors that measured
how much radiation the
brain, thyroid, stomach,
colon, and heart and lung area received on a daily basis. The
data are still being analyzed to determine how the body reacts
to and shields its internal organs from radiation, information
that will be very important during longer-duration space flights.
Tissue Equivalent Proportional Counter – TEPC
2000 – present
This radiation detector consists of a 2"-diameter by 2"-long
cylindrical cell that is filled with low-pressure propane gas. The
gas is used to simulate the hydrocarbon content of a human cell
that is two microns in diameter. A plastic jacket covering the cell
simulates the properties of adjacent tissue cells. Particles passing
through the gas release electrons, which are collected, helping to
identify the energy of the particles.
Measuring Space Radiation Between the Earth
and Mars
As the Mars Odyssey spacecraft made its way to Mars between
April and October 2001, the Mars radiation environment
experiment (MARIE) measured the amounts and kinds of space
radiation the spacecraft encountered along the way. These data
are essential to understanding how much and what kinds of
radiation future space travelers might encounter on a long trip
to explore the red planet.
Now in orbit around Mars, MARIE continues to measure the
amount of harmful radiation at the planet itself. Unlike Earth,
Mars does not have a global magnetic field to shield it from
solar flares and cosmic rays. Mars’ atmosphere is also less
than one percent as thick as the Earth’s. These two factors
make Mars very vulnerable to space radiation.
Aboard the International Space Station and in our own solar
system, NASA researchers continue to quantify the amounts
of space radiation our explorers face every day and will face
in the future. Understanding space radiation will not only protect
the crew currently aboard the International Space Station, but
those first humans who will continue the exploration of our
solar system.
Related Web Sites
http://spaceresearch.nasa.gov/research_projects/radiation.html
http://www.spaceflight.nasa.gov/station/science/bioastronautics/