Sublethal damage repair in two radioresistant human tumor cell lines irradiated as multicellular spheroids.

ABSTRACT

Melanoma and lung adenocarcinoma may be amenable for radiotherapy if it were possible to increase the presently used total dose. In order to investigate this, spheroids from two cell lines of human origin, one obtained from a BRO melanoma and one from an NCI-H125 lung adenocarcinoma were exposed to graded doses (3-9 Gy) of radiation with 18-MV photons. Radiation was applied either as a single dose or as split doses with an interval of 6 h to determine the extent of sublethal damage repair. Radiation response was quantified in terms of spheroid cure and specific growth delay. Both cells lines have previously been shown to be less sensitive than a neuroblastoma and a squamous cell carcinoma cell line grown as spheroids. Data obtained from the growth delay analysis were used to calculate the extent of split-dose recovery. Repaired dose for BRO spheroids did not increase after 7 Gy, whereas in NCI-H125, the repaired dose showed a steady increase. Recovery ratios did not differ between the two cell lines, but were lower than reported for normal tissues. Both cell lines revealed a low repair capacity was expressed by the beta-value of the linear-quadratic (LQ) equation. However, repair capacity for sublethal damage as expressed by the dose repaired and the beta-value of the LQ equation was not different from values reported earlier by us for neuroblastoma and squamous cell carcinoma when grown as spheroids. This indicates that the low radiosensitivity for the cell lines used in this study is determined by the alpha-value of the LQ equation. Our results support the clinical finding that the application of increased total radiation doses in the treatment of melanoma and lung adenocarcinoma may be feasible if radiation is applied in multiple small fractions to ensure normal tissue sparing.