Absorbed dose

Several additional terms related to the absorption of x-radiation require definition energy of a x-ray photon is properly represented in joules but more conveniently reported in eV fluence is the sum of the energy in a unit area intensity or flux is the fluence per unit time and the exposure is a measure of the number of ions produced in a mass of gas. The unit of exposure in medicine is the Rn ntgen, R, defined as the quantity of radiation required to produce 2.58 x C/kg of air. The absorbed dose for a tissue is a measure of energy dissipated per unit mass. The measure of absorbed dose most... 

Approximately 50% of an absorbed dose is transformed to fluoride ion, dichloroacetic acid, methoxydifluoroacetic acid, and oxaHc acid (50). 

Fig. 3. Schematic representation showing the anatomical basis for differences in the quantitative supply of absorbed material to the Hver. By swallowing (oral route), the main fraction of the absorbed dose is transported direcdy to the Hver. FoUowing inhalation or dermal exposure, the material passes to the pulmonary circulation and thence to the systemic circulation, from which only a portion passes to the Hver. This discrepancy in the amount of absorbed material passing to the Hver may account for differences in toxicity of a material by inhalation and skin contact, compared with its toxicity by swallowing, if metaboHsm of the material in the Hver is significant in its detoxification or metaboHc activation.

It is important to appreciate that the magnitude of the absorbed dose, the relative amounts of bio transformation product, and the distribution and elimination of metaboUtes and parent compound seen with a single exposure, may be modified by repeated exposures. For example, repeated exposure may enhance mechanisms responsible for biotransformation of the absorbed material, and thus modify the relative proportions of the metaboUtes and parent molecule, and thus the retention pattern of these materials. Clearly, this could influence the likelihood for target organ toxicity. Additionally, and particularly when there is a slow excretion rate, repeated exposures may increase the possibiUty for progressive loading of tissues and body fluids, and hence the potential for cumulative toxicity. 

It is clear from the above considerations that the absorbed dose, and the distribution, excretion, and relative amounts of the absorbed material and its metabohtes may be quantitatively different for acute and repeated exposures. This modifies the potential for the absorbed material to produce adverse effects by a given route of exposure. 

Pharmacokinetic studies are designed to measure quantitatively the rate of uptake and metaboHsm of a material and determine the absorbed dose to determine the distribution of absorbed material and its metaboHtes among body fluids and tissues, and their rate of accumulation and efflux from the tissues and body fluids to determine the routes and relative rates of excretion of test material and metaboHtes and to determine the potential for binding to macromolecular and ceUular stmctures. 

Pharmacokinetic studies should allow an assessment of the relationship between the environmental-exposure conditions and the absorbed dose, and how these influence the doses of test material and metaboHtes received by various body tissues and fluids, and the potential for storage. Numerous texts are available on the design and conduct of metaboHsm and pharmacokinetic studies (117—119). 

The gray is also used for the ionising radiation quantities, specific energy imparted, kerma, and absorbed dose index, which have the SI unit joule per kilogram. 

Ra.dia.tlon Units. Units in use for activity of a radionucHde, ie, the curie, the roentgen (exposure to x and gamma rays), the rad (absorbed dose), and the rem (dose equivalent), should eventually be replaced by the becquerel (Bq), coulomb per kilogram (C/kg), gray (Gy), and the sievert (Sv), respectively. 

Where data permit, slope factors listed in IRIS are based on absorbed doses, although to date many of them ha c been based on administered doses. 

Absorbed Dose Equivalent to intake multiplied by an absorption factor... 

Keeping the composition of copolymerization media constant the total comonomer concentration of which is varied. The absorbed dose was kept constant at 0.14 KGy for the AM-AANa and at 0.35 KGy for the AM-DAEA-HCl systems. The results are shown in Figs. 4 and 5, which show the rate of polymerization, Rp, the degree of polymerization, and the intrinsic viscosity increase with increasing monomer concentration. At comonomer concentration >2.1 M/L, DPn decreases with increasing comonomer concentration. From the logarithmic plots, exponents of the comonomer concentration for the AM-AANa system were determined to be [17,54]. 

The influence of temperature on the copolymerization was investigated at constant absorbed dose of 0.12 and 0.16 KGy for copolymerization of AM-AANa [17,54] and AM-DAEA-HCl [22], respectively. The results are shown in Figs. 9 and 10, which show that the Rp values increase while the intrinsic viscosity and the degree of polymerization decrease with increasing the polymerization temperature. However, the increase in the temperature of the polymerization medium increases the swell-... 

The extent of damage from radiation depends mainly on two factors. These are the amount of radiation absorbed and the type of radiation. The former is commonly expressed in rads (radiation absorbed dose). A rad corresponds to the absorption of 10 z J of energy per kilogram of tissue ... 

The recombination of fragments stemming from one macromolecule, at times shorter than the diffusion time, prevents the linear increase in RD with the absorbed dose per pulse, as not all main-chain scissions result in the formation of fragments. The effect of molecular oxygen on RD in the case of PBS can be interpreted by formation of peroxyl radicals, e.g. 

An alternative explanation suggested by the authors for the non-linearity of R° with dose is the formation of reactive solvent species capable of intercepting the scission reaction, with a yield which becomes greater the higher the absorbed dose per pulse. However, this mechanism does not explain the effect of oxygen. 

The absorbed dose of radiation is the energy deposited in a sample (in particular, the human body) when it is exposed to radiation. The SI unit of absorbed dose is the gray, Gy, which corresponds to an energy deposit of 1 J-kg. The original unit used for reporting dose was the radiation absorbed dose (rad), the amount of... 

The former (non-SI) unit of dose equivalent was the roentgen equivalent man (rem), which was defined in the same way as the sievert but with the absorbed dose in rad thus, 1 rem = 10 2 Sv. 

Human exposure to radiation is monitored by reporting the absorbed dose and... 

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