urine activity concentration to body burden.
integrating Eq.

Equation 3 was obtained by

(2).

Equations (1) and (2) were used to determine the dietary removal rate constant Ke and then the initial daily activity ingestion rate required to produce
the measured or derived body burden,

Equation (3) was used to determine the num-

ber of disintegrations that occurred in the body during the residence interval
of an individual Living on Rongelap or Utirik Atoll.
If the mean residence time in the diet is much much longer than the resi-

dence interval, then constant continuous uptake is achieved.

Equations (1) and

(2) can be converted to the constant continuous equations by replacing K, with
-A.

Single uptake expressions are obtained by setting P® equal to zero.

In

some cases only radioactive decay may remove the nuclide from dietary items; for
these cases Kg would equal zero.

In the case of the former Bikini residents,

the maturing of coconut trees during residence on Bikini Atoll caused a
continuously increasing dietary uptake of }
negative value.

Cs.

Thus, K, was found to have a

In the case of Rongelap and Utirik, K, was found to have a posi-

tive value for 13766 O54, 6064, and 906,

This indicated that in addition to

radioactive decay, some other removal mechanism decreased the radioactivity in
dietary items during the residence interval.

For the nuclide Fe, only one mea~

surement in blood was published by theBNL Medical Program (Be72); thus an estimate of KE was not possible.
K. was determined by using Eq.

(1) or (2) and the population subgroup

mean body burdens or urine activity concentrations.

A portion of these bioassay

data are illustrated for adult males and females in Figures 2 to 6.

Two consecu-

tive urine or body-burden data points were used to eliminate the unknown ingestion rate from the equation.

This method yields n-1 estimates of Ke where n was

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