References
- Downing J. F., Taylor M. W. The effect of in vivo hyperthermia on selected lymphokines in man. Lymphokine Research 1987; 6: 108–109
- Downing J. F., Martinez-Valdez H., Elizondo R. S., Walker E. B., Taylor M. W. Hyperthermia in humans enhances interferon-7 synthesis and alters the peripheral lymphocyte population. Journal of lnterferon Research 1988; 8: 143–150
- Izumi A., Koga S., Maeta M. Effect of in vitro hyperthermia on murine and human lymphocytes. Cancer 1983; 51: 2061–2065
- Kataoka T., Ohashi F., Akabori Y., Sakurai Y., Okabe M., Gomi K. Tumor dependency of concanavalin A-induced potentiation of tumor cell immunogenecity. Japanese Journal of Cancer Research 1983; 74: 412–420
- Neville A. J., Sauder D. N. Whole body hyperthermia (41–42°C) induces interleukin-1. in vivo. Lymphokine Research 1988; 7: 201–206
- Old L. J., Boyse E. A., Clarke D. A., Carswell E. A. Antigenic properties of chemically induced tumors. Annals of the New York Academy of Sciences 1962; 101: 80–106
- Ozawa H., Iwaguchi T., Kataoka T. The Lyt phenotype of the T cells responsible for in vivo tumor rejection in syngeneic mice. Cancer Immunology and Immunotherapy 1986; 23: 73–77
- Ozawa H., Iwaguchi T., Kataoka T. Essential requirement of I-A region-identical host bone marrow or bone marrow-derived cells for tumor neutralization by primed L3T4+ T cells. Journal of Immunology 1987; 139: 3896–3901
- Shen R-N., Hornback N. B., Shidnia H., Lu L., Broxmeyer H. E., Brahmi Z. Effect of whole-body hyperthermia and cyclophosphamide on natural killer cell activity in murine erythroleukemia. Cancer Research 1988; 48: 4561–4563
- Wilkinson D. A., Burholt D. R., Shrivastava P. N. Hypothermia following whole-body heating of mice: effect of heating time and temperature. International Journal of Hyperthermia 1988; 4: 171–182
- Winn H. J. Immune mechanisms in homotransplantation. II. Quantitative assay of the immunologic activity of lymphoid cells stimulated by tumor homografts. Journal of Immunology 1961; 86: 228–239