units Ionizing radiation deposits energy in the matter being irradiated. The quantity used to express this is the
absorbed dose, a physical dose quantity that is dependent on the level of incident radiation and the absorption properties of the irradiated object. Absorbed dose is a physical quantity, and is not a satisfactory indicator of biological effect, so to allow consideration of the stochastic radiological risk, the dose quantities equivalent dose and effective dose were devised by the
International Commission on Radiation Units and Measurements (ICRU) and the ICRP to calculate the biological effect of an absorbed dose. To obtain an effective dose, the calculated absorbed organ dose is first corrected for the radiation type using factor to give a weighted average of the equivalent dose quantity received in irradiated body tissues, and the result is further corrected for the tissues or organs being irradiated using factor , to produce the effective dose quantity . The sum of effective doses to all organs and tissues of the body represents the effective dose for the whole body. If only part of the body is irradiated, then only those regions are used to calculate the effective dose. The tissue weighting factors summate to 1.0, so that if an entire body is radiated with uniformly penetrating external radiation, the effective dose for the entire body is equal to the equivalent dose for the entire body.
Use of tissue weighting factor The ICRP tissue weighting factors are given in the accompanying table, and the equations used to calculate from either absorbed dose or equivalent dose are also given. Some tissues like bone marrow are particularly sensitive to radiation, so they are given a weighting factor that is disproportionately large relative to the fraction of body mass they represent. Other tissues like the hard bone surface are particularly insensitive to radiation and are assigned a disproportionally low weighting factor. Calculating from the equivalent dose: :E = \sum_T W_T \cdot H_T = \sum_T W_T \sum_R W_R \cdot \overline{D}_{T,R}. Calculating from the absorbed dose: :E = \sum_T W_T \sum_R W_R \cdot \frac{\displaystyle \int_{T}D_R (x,y,z)\rho(x,y,z)dV}{\displaystyle \int_{T}\rho(x,y,z)dV} Where :E is the effective dose to the entire organism :H_T is the equivalent dose absorbed by tissue :W_T is the tissue weighting factor defined by regulation :W_R is the radiation weighting factor defined by regulation :\overline{D}_{T,R} is the mass-averaged absorbed dose in tissue by radiation type :D_R (x,y,z) is the absorbed dose from radiation type as a function of location :\rho(x,y,z) is the density as a function of location :V is volume :T is the tissue or organ of interest The ICRP tissue weighting factors are chosen to represent the fraction of health risk, or biological effect, which is attributable to the specific tissue named. These weighting factors have been revised twice, as shown in the chart above. The United States
Nuclear Regulatory Commission still uses the ICRP's 1977 tissue weighting factors in their regulations, despite the ICRP's later revised recommendations. ==By medical imaging type==