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ASSESSMENT OF OCCUPATIONAL EXPOSURE DUE TO INTAKES OF RADIONUCLIDES

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Title: ASSESSMENT OF OCCUPATIONAL EXPOSURE DUE TO INTAKES OF RADIONUCLIDES


1
ASSESSMENT OF OCCUPATIONAL EXPOSURE DUE TO
INTAKES OF RADIONUCLIDES
Interpretation of Measurement Results
2
Introduction
3
Measurements for internal dose assessment
  • Direct measurement - the use of detectors placed
    external to the body to detect ionizing radiation
    emitted by radioactive material contained in the
    body.
  • Indirect measurement - the analysis of excreta,
    or other biological materials, or physical
    samples to estimate the body content of
    radioactive material.

4
Measurements for internal dose assessment
  • Direct or indirect measurements provide
    information about the radionuclides present in
  • The body,
  • Parts of the body, e.g specific organs or
    tissues,
  • A biological sample or
  • A sample from the working environment.
  • These data are likely to be used first for an
    estimation of the intake of the radionuclide

5
Measurements for internal dose assessment
  • Biokinetic models are used for this purpose.
  • Measurements of body activity can also be used to
    estimate dose rates directly
  • Calculation of committed doses from direct
    measurements still involves the assumption of a
    biokinetic model,
  • If sufficient measurements are available to
    determine retention functions, biokinetic models
    may not be needed

6
Interpretation of monitoring measurements
7
Estimate of intake
  • Where M is the measured body content or excretion
    rate, m(t) is the fraction of the intake retained
    in the whole body (direct measurement) or having
    been excreted from the body in a single day
    (indirect measurement) retention or excretion
    fraction - at time t (usually in days) after
    intake.

8
Estimate of intake
  • The ICRP has published default values of m(t) in
    Publication 78
  • When significant intakes may have occurred, more
    refined calculations based on individual specific
    parameters (special dosimetry) should be made
  • If multiple measurements are available, a single
    best estimate of intake is obtained by the method
    of least squares.
  • When more than 10 of the measurements could be
    attributed to previous evaluated intakes a
    correction should be performed.

9
Implementing biokinetic models
  • The ICRP Publication 78 Individual Monitoring
    for internal exposure of workers - replacement of
    ICRP Publication 54 provides a general guidance
    on the design of individual monitoring programmes
    and the interpretation of results of estimates of
    intakes of radionuclides by workers.
  • A reference worker is assumed in relation to the
    biokinetic models and the parameter values
    describing the scenario of contamination.
    Radionuclides are selected for their potential
    importance in occupational exposure.
  • This publication replaces the previous one ICRP
    Publication 54 Individual Monitoring for intakes
    of radionuclides by workers design and
    interpretation taking into account
  • - new protection quantities and new set of
    exposure conditions (ICRP 60)
  • - new general principles for radiation
    protection of workers (ICRP 75)
  • - respiratory tract model of ICRP 66
  • - revised biokinetic models when available for
    selected radionuclides

10
Implementing biokinetic models
ICRP 78 CURVES AND DATA
  • Basic assumption for a reference worker in ICRP
    78
  • Adult male
  • Normal nose breathing at light work
  • Breathing rate 1.2 m3/h
  • Inhaled aerosol with Activity Median
    Aerodynamic Diameter (AMAD) 5 µm
  • Regional Deposition
  • ET1 34
  • ET2 40
  • BB 1.8
  • BB 1.1
  • AI 5.3
  • total 82

The data and curves available in ICRP 78 refers
to these specific conditions of exposure!
11
Implementing biokinetic models
ICRP 78 CURVES AND DATA
  • General information

Description of the model
Standard assumption for transfer into
systemic phase
Dose coefficients
e(50)
Other informations
ALI0.02/e(50)
In relation to the radionuclide other significant
information are available monitoring techniques
(as for Pu), etc.
12
Caesium
  • Model Non-recycling model

H, P, Cr, Mn, Co, Zn, Rb, Zr, Ru, Ag, Sb, Ce,
Hg, Cf are as well
13
Implementing biokinetic models
ICRP 78 CURVES AND DATA
  • Data

m(t)
t
Special monitoring (inhalation)
Special monitoring (ingestion and injection)
Routine monitoring (inhalation)
T
m(T/2)
  • Retention (Bq per Bq intake)
  • Excretion (Bq/d per Bq intake)

14
Retention or excretion fraction m(t)
  • Depends on
  • Route of intake
  • Absorption type, i.e. chemical form Type F
    (fast), Type M (moderate), or Type S (slow)
  • Measurement and sample type

15
Retention fraction example 60Co
  • Intake may be through inhalation, ingestion or
    injection (wounds)
  • Assigned two absorption types M and S
  • Assigned two f1 values for ingestion 0.01 and
    0.05
  • ICRP 78 considers 4 possibilities for measurement
  • Direct
  • Whole body
  • Lungs
  • Indirect
  • Urine
  • Faeces

16
60Co Routine Monitoring Retention
FractionsInhalation
17
60Co Retention Fractions - Inhalation
Type M
Type S
18
60Co Routine Special Retention FractionsInhalatio
n
19
60Co Retention Fractions - Ingestion
Special Monitoring
f1 0.1
f1 0.05
20
60Co Retention Fractions - Injection
Special Monitoring
21
Intake Estimates - An Example
22
Estimate of intake - an example
  • Occupational exposure to radioiodine occurs in
    various situations
  • I-131 is a common short lived iodine isotope
  • Half-life 8 d
  • ? particles - average energy 0.19 MeV
  • ? - main emission 0.364 MeV
  • Rapidly absorbed in blood following intake
  • Concentrates in the thyroid
  • Excreted predominantly in urine

23
Estimate of intake - an example
  • After intake, I-131 may be detected directly in
    the thyroid, or indirectly in urine samples
  • If occupational exposure to I-131 can occur, a
    routine monitoring programme is needed
  • Based on direct thyroid measurement or
  • Indirect monitoring of urine or workplace samples

24
Estimate of intake - an example
  • Choice of monitoring method depends on various
    factors
  • Availability of instrumentation
  • Relative costs of the analyses
  • Sensitivity that is needed
  • Direct measurement of activity in the thyroid
    offers the most accurate dose assessment
  • Other methods may be adequate and may be better
    suited to the circumstances

25
Estimate of intake - an example
  • Chemical form of the radionuclide is a key
    parameter in establishing biokinetics
  • All common forms of iodine are readily taken up
    by the body
  • For inhalation of particulate iodine, lung
    absorption type F is assumed
  • Elemental iodine vapour is assigned to class SR-1
    with absorption type F
  • Absorption of iodine from the gastrointestinal
    tract is assumed to be complete, i.e. f1 1.

26
Dose coefficients
1.4 E-08
2.0 E-08
(a) For lung absorption types see para. 6.16 of
RS-G-1.2 (b) For inhalation of gases and
vapours, the AMAD does not apply for this form.
27
Biokinetic model for systemic iodine
28
Radioiodine biokinetics
  • 30 of iodine reaching the blood is assumed
    transported to the thyroid
  • The other 70 is excreted directly in urine
  • Biological half-time in blood is taken to be 6 h
  • Iodine incorporated into thyroid hormones leaves
    the gland with a biological half-life of 80 d and
    enters other tissues

29
Radioiodine biokinetics
  • Iodine is retained in these tissues with a
    biological half-life of 12 d.
  • Most iodine (80) is subsequently released and
    available in the circulation for uptake by the
    thyroid or direct urinary excretion
  • Remainder is excreted via the large intestine in
    the faeces
  • The physical half-life of I-131 is short, so this
    recycling is not important for committed
    effective dose.

30
131I intake - Thyroid monitoring
  • A routine monitoring programme
  • 14 day monitoring period
  • Thyroid content of 3000 Bq 131I is detected in a
    male worker
  • Based on workplace situation, exposures are
    assumed due to inhalation of particulates
  • Intakes by ingestion would lead to the same
    pattern of retention and excretion

31
131I intake - Thyroid monitoring
  • Intake pattern is not known
  • Assume an acute intake
  • occurred in the middle of
  • the monitoring period
  • From the biokinetic model, 7.4 of the
    radioactivity inhaled in a particulate (type F)
    form with a default AMAD of 5 is retained in the
    thyroid after 7 d

from table A.6.17 (Thyroid) in ICRP 78
32
131I intake - Thyroid monitoring
Special monitoring
0.074
Vapor particle
Retention, Bq
or table A.6.17 in ICRP 78
7
Time after intake, d
33
131I intake - Thyroid monitoring
  • Thus, m(7) 0.074, and
  • Application of the dose coefficients given in the
    BSS and in the previous table gives,
  • A committed effective dose of 0.45 mSv
  • (4.1104 Bq ? 1.110-8 Sv/Bq ? 103 mSv/Sv)
  • This dose may require follow-up investigation

34
131I intake - Urine measurement
  • One day after the direct thyroid measurement, the
    worker has a 24-h urine sample
  • Sample assay shows 30 Bq of 131I
  • From the biokinetic model for a type F
    particulate, m(8) for daily urinary excretion is
    1.1 E-04

from table A.6.17 (dairy urinary excretion) in
ICRP 78
35
131I intake - Urine measurement
  • A committed effective dose of 3 mSv
  • (2.7105 Bq ? 1.110-8 Sv/Bq ? 103 mSv/Sv)
  • For this example no account is taken of any
    previous intakes

36
131I intake - Workplace air measurements
  • Workplace air measurements showed 131I
    concentrations that were low but variable
  • Maximum concentrations between 10 and 20 kBq/m3
    (12 to 25 times the DAC) for short periods
    several times in several locations
  • At the default breathing rate of 1.2 m3/h, worker
    could receive an intake of 24 kBq in one hour
    without respiratory protection

DAC Derived Air Concentration
37
Derived air concentrations
38
131I intake - Workplace air measurements
  • If worker had worked for one hour without
    respiratory protection, or
  • Somewhat longer with limited respiratory
    protection
  • The intake estimated from air monitoring would be
    consistent with that determined by bioassay
    (direct and indirect) measurements

39
131I intake - Dose assessment
  • Intake discrepancy suggests at least one of the
    default assumptions is not correct
  • Significant individual differences in uptake and
    metabolism cannot generally account for
    discrepancies of nearly a factor of 10
  • The rate of 131I excretion in urine decreases
    markedly with time after intake - a factor of
    more than 1000 over the monitoring period

40
131I - Daily urinary excretion after inhalation
41
131I intake - Dose assessment
  • Assumption of the time of intake is a probable
    source of error
  • If the intake occurred 3 days before the urine
    sample was submitted
  • Intake estimated from the urine measurement would
    be 21 kBq
  • Intake from the thyroid measurement would be 25
    kBq
  • The agreement would be satisfactory

42
131I intake - Dose assessment
  • From the biokinetic model, the fraction of
    inhaled 131I retained in the thyroid only changes
    by about a factor of 3 over the monitoring period
  • Without more information, the new assumption is
    more reliable for dose assessment
  • The committed effective dose for this example
    would then be 0.27 mSv
  • A 2nd urine sample obtained after a few more days
    should be used to verify this conclusion.

43
131I intake - Dose assessment
  • Committed effective dose from thyroid monitoring
    is relatively insensitive to assumptions about
    the time of intake
  • However, there is rapid change in urinary
    excretion with time after exposure
  • Result - direct measurement provides a more
    reliable basis for interpreting routine
    radioiodine monitoring measurements
  • Urine screening may still be adequate to detect
    significant intakes

44
131I intake - Dose assessment
  • Air concentrations that substantially exceed a
    DAC should trigger individual monitoring
  • However, because of direct dependence on
  • Period of exposure
  • Breathing rates
  • Levels of protection and
  • Other factors known only approximately
  • Intake based on air monitoring for 131I are less
    reliable than from individual measurements
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