Radioprotective Effects of Two Traditional Chinese Medicine Prescriptions: Si-Wu-Tang and Si-Jun-Zi-Tang

We performed this study to determine the effect of Si-Wu-Tang, a basic prescription of traditional Oriental medicine as a blood-building decoction (Chinese medical concept: Bu-Xie), Si-Jun-Zi-Tang, a basic prescription as an energy tonic (Chinese medical concept: Bu-Qi) and its major ingredients on jejunal crypt survival, endogenous spleen colony formation, and apoptosis in jejunal crypt cells of mice irradiated with high and low dose of γ-irradiation. Si-Wu-Tang administration before irradiation protected the jejunal crypts (p < 0.0005), increased the formation of endogenous spleen colonies (p < 0.05) and reduced the frequency of radiation-induced apoptosis (p < 0.05). In an experiment on the effect of ingredients of Si-Wu-Tang, the result indicated that extract of Danggui and Baishaoyao might have a major radioprotective effect. The radioprotective effect of Si-Jun-Zi-Tang and its ingredients were not as significant as that of Si-Wu-Tang. Although the mechanisms of this inhibitory effect remain to be elucidated, these results indicate that Si-Wu-Tang might be a useful radioprotector, especially since it is a relatively nontoxic natural product. Further studies are needed to characterize better the protective nature of Si-Wu-Tang extract and its ingredients.

The factors controlling stem cell recirculation. i. Migration of hemopoietic stem cells in adrenalectomized mice

The influence of bilateral adrenalectomy on hemopoietic stem cell (CFU) migration in mice has been studied. Formation of endogenous spleen colonies in lethally irradiated, leg-shielded mice was sharply increased by prior adrenalectomy, and this increase was not dependent on the volume of shielded bone marrow. Adrenalectomy was shown to increase endogenous spleen colony formation in sublethally irradiated mice as well. However, it had no affect on formation of spleen colonies in lethally irradiated mice injected with syngeneic bone marrow. The CFU content of murine bone marrow decreased acutely after removal of the adrenals, and this decrease was accompanied by a concomitant increase in the peripheral blood and splenic CFU. Thus, adrenalectomy appeared to have no affect on the splenic plating efficiency or proliferative rate of hemopoietic stem cells, but it did result in increased migration of stem cells from the bone marrow to the blood, and thence to the spleen. It is concluded that the adrenal steroids may be of physiologic importance in the regulation of ehmopoietic stem cell migration.

The factors controlling stem cell recirculation. i. Migration of hemopoietic stem cells in adrenalectomized mice

The influence of bilateral adrenalectomy on hemopoietic stem cell (CFU) migration in mice has been studied. Formation of endogenous spleen colonies in lethally irradiated, leg-shielded mice was sharply increased by prior adrenalectomy, and this increase was not dependent on the volume of shielded bone marrow. Adrenalectomy was shown to increase endogenous spleen colony formation in sublethally irradiated mice as well. However, it had no affect on formation of spleen colonies in lethally irradiated mice injected with syngeneic bone marrow. The CFU content of murine bone marrow decreased acutely after removal of the adrenals, and this decrease was accompanied by a concomitant increase in the peripheral blood and splenic CFU. Thus, adrenalectomy appeared to have no affect on the splenic plating efficiency or proliferative rate of hemopoietic stem cells, but it did result in increased migration of stem cells from the bone marrow to the blood, and thence to the spleen. It is concluded that the adrenal steroids may be of physiologic importance in the regulation of ehmopoietic stem cell migration.

Patterns of Proliferation and Differentiation of Hematopoietic Stem Cells After Compartment Depletion

The time of onset and rate of self-replication in the irradiation depleted pluripotential hematopoietic stem cell compartment of mice was measured by a split-dose irradiation method. Mice were irradiated to reduce the compartment size and at daily intervals thereafter were again irradiated; 10 days after the second irradiation the number of endogenous spleen colonies was determined. As irradiation interval was lengthened, colonies increased in an exponential fashion with no apparent lag interval after the first irradiation. The doubling time of the colony-forming cell compartment was calculated as 16 hr if severely reduced in size by 300 R or more but was slower if less irradiation was given. The time of resumption of erythropoiesis following irradiation was measured after 100-900 R by determining uptake of radioactive iron into marrow, spleen, and circulating red cells each day after irradiation. With 200 R or less, erythropoiesis was not abolished. With higher doses there was an interval of no apparent erythropoiesis which increased by 1.6 days for each increment of 100 R. These results are compatible with a pluripotential stem cell compartment, which (1) begins self replication almost immediately following compartment size reduction, and (2) will not differentiate if reduced in size below approximately 10% of normal.