The Effect of the Amount of Isologous Bone Marrow Injected on the Recovery of Hematopoietic Organs, Survival and Body Weight after Lethal Irradiation Injury in Mice

The relation between the amount of isologous bone marrow injected into a lethally irradiated mouse and its 30 day survival, its bone marrow response, the histology of the bone marrow in its left femur, its peripheral blood leukocyte count, the weight of its thymus, spleen, and body, and its appearance showed that quicker recovery of these end points occurred with increasing amounts of bone marrow administered.

The bone marrow parameter was the quickest to respond to the varying amounts of bone marrow injected. In addition, no optimum dose of bone marrow was found in these experiments for this end point. This indicates that the bone marrow of an irradiated mouse could be made to show even quicker return to normal by injection of greater amounts of cells.

The peripheral blood leukocyte count and the spleen weight also showed very quick recovery with the massive doses of bone marrow injected. For both end points, however, an optimum response was reached, which in the leukocytes, was 64.4 x 10⁶ -237.9 x 10⁶ cells injected, and in the spleen weight, 12.8 x 10⁶ -237.9 x 10⁶. An optimum response for thymus weight was also found with bone marrow doses of 64.4 x 10⁶ - 237.9 x 10⁶ cells. The cell dose for the optimum response in recovery of body weight was 12.8 x 10⁶ - 237.9 x 10⁶.

Optimum 30 day survival was reached with injection of 64.4 x 10⁶ bone marrow cells in these experiments. However, doses from 12.8 x 10⁶ to 64.4 x 10⁶ cells were not tested. The dose of bone marrow cells that was calculated to give 50 per cent 30-day survival was 0.42 x 10⁶ (0.17 x 10⁶, 1.92 x 10⁶) cells for the males and 1.06 x 10⁶ (0.42 x 10⁶, 2.51 x 10⁶) cells for the females. The calculated dose of bone marrow cells that would give 1 per cent 30-day survival of the males was 0.008 x 10⁶ (0.0008 x 10⁶, 0.0284 x 10⁶) and for the females 0.0102 x 10⁶ (0.001 x 10⁶, 0.040 x 10⁶) cells. These point estimates seem to be unreliable in view of the extremely large 95% confidence intervals. However, in experiments done by other workers at the National Cancer Institute similar to those reported in this paper, M. Schneiderman determined a threshold dose ranging from 0.0026 to 0.0320 x 10⁶ cells by a somewhat different analysis of the data.⁷ Jacobson et al. cite a figure of 3-5 x 10⁶ bone marrow cells from young donor mice as causing 53% 28-day survival in CF No. 1 mice exposed to 900 r.² In using bone marrow from older mice, they found that 5-9.9 x 10⁶ cells caused 54.9% 28-day survival. They also estimate that 50,000 cells are necessary to produce significant recovery of mice after an LD₉₉ exposure. This figure is similar to that determined from the results of the present experiments.

The results obtained from mice injected intravenously with a massive dose of bone marrow 3 days after irradiation indicated that the number of cells in the bone marrow of the right femur can be elevated within a few hours after injection. However, this could be observed only in an irradiated animal where the number of cells in the right femoral bone marrow was already low. A similar observation was made by Graevsky.⁸ This finding gives further support to the hypothesis that intravenously injected bone marrow transplants to bone marrow sites in the irradiated host.⁹