Literature DB >> 953389

Effects of fractionated irradiation on mouse lung and a phenomenon of slow repair.

S B Field, S Hornsey, Y Kutsutani.   

Abstract

The LD/50 between 40 and 180 days after irradiation of the thorax has been taken as a measure of lung damage in mice. The method has been used to derive the relationship between total dose, number of fractions (N) and overall treatment time (T). For X rays the results fit an Ellis type of relationship, i.e. total dose alphaN0-25 T0-07. This only applies for more than 8 fractions, below which N0-39 becomes a good fit to the results. For neutrons, the best fit is total dose alphaT0-07. Various possible explanations for the T factor are discussed, but for lung damage we attribute it to a slow repair process which possibly may only be observed in slowly proliferating tissues. Slow repair is about 100 times less rapid than Elkind-type of repair of sublethal damage and whereas Elkind repair is greatly reduced for irradiation with fast neutrons, relative to X rays, slow repair is not.

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Year:  1976        PMID: 953389     DOI: 10.1259/0007-1285-49-584-700

Source DB:  PubMed          Journal:  Br J Radiol        ISSN: 0007-1285            Impact factor:   3.039


  10 in total

1.  Cell survival assays in a slowly dividing normal tissue.

Authors:  H Walker; R Ahier; P Coultas
Journal:  Br J Cancer Suppl       Date:  1986

2.  Early and late effects of fractionated irradiation of the thorax of WAG/Rij rats.

Authors:  E van Rongen; C Tan; C Zurcher
Journal:  Br J Cancer Suppl       Date:  1986

3.  The linear quadratic fit for lung function after irradiation with X-rays at smaller doses per fraction than 2 Gy.

Authors:  C S Parkins; J F Fowler
Journal:  Br J Cancer Suppl       Date:  1986

Review 4.  The first James Kirk memorial lecture. What next in fractionated radiotherapy?

Authors:  J F Fowler
Journal:  Br J Cancer Suppl       Date:  1984

5.  Tissue repair capacity and repair kinetics deduced from multifractionated or continuous irradiation regimens with incomplete repair.

Authors:  H D Thames; H R Withers; L J Peters
Journal:  Br J Cancer Suppl       Date:  1984

Review 6.  All for one, though not one for all: team players in normal tissue radiobiology.

Authors:  Marjan Boerma; Catherine M Davis; Isabel L Jackson; Dörthe Schaue; Jacqueline P Williams
Journal:  Int J Radiat Biol       Date:  2021-07-01       Impact factor: 2.694

7.  Detection and early phase assessment of radiation-induced lung injury in mice using micro-CT.

Authors:  Shigeyoshi Saito; Kenya Murase
Journal:  PLoS One       Date:  2012-09-24       Impact factor: 3.240

Review 8.  Radiation effects in the lung.

Authors:  J E Coggle; B E Lambert; S R Moores
Journal:  Environ Health Perspect       Date:  1986-12       Impact factor: 9.031

9.  Development of a small animal model to simulate clinical stereotactic body radiotherapy-induced central and peripheral lung injuries.

Authors:  Zhen-Yu Hong; Sung Ho Eun; Kwangwoo Park; Won Hoon Choi; Jung Il Lee; Eun-Jung Lee; Ji Min Lee; Michael D Story; Jaeho Cho
Journal:  J Radiat Res       Date:  2014-02-20       Impact factor: 2.724

10.  Quantitative assessment of radiation dose and fractionation effects on normal tissue by utilizing a novel lung fibrosis index model.

Authors:  Cheng Zhou; Bleddyn Jones; Mahmoud Moustafa; Christian Schwager; Julia Bauer; Bing Yang; Liji Cao; Min Jia; Andrea Mairani; Ming Chen; Longhua Chen; Juergen Debus; Amir Abdollahi
Journal:  Radiat Oncol       Date:  2017-11-07       Impact factor: 3.481
  10 in total

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