Comparison of fractionated to single-dose total body irradiation in conditioning canine littermates for DLA-identical marrow grafts.

We explored the ability of fractionated total body irradiation (TBI) given at a rate of 7 cGy/min from opposing dual 60Co sources at otherwise lethal doses of 450, 600, 700, 800, and 920 cGy to condition dogs for marrow grafts from DLA-identical littermates. Results were compared with those of a previously reported study using single-dose TBI administered under otherwise identical conditions. Fractionated TBI was less immunosuppressive than single-dose TBI, as evidenced by a significantly higher rate of graft rejection (P = .001). Specifically, sustained allogeneic engraftment was observed in only two of 18 (11%) dogs that received 600 to 800 cGy fractionated TBI as compared with 11 of 17 (65%) dogs that received comparable doses of single-dose TBI. Only at 450 cGy (none of the ten dogs studied had sustained engraftment) and at 920 cGy (four of five dogs that received fractionated and 20 of 21 dogs that received single-dose TBI engrafted) were we unable to find differences between the two modes of radiation. Most dogs that rejected their graft survived with autologous recovery (13 of 22 that received fractionated and eight of 12 that received single-dose TBI; P = .49), presumably the result of extended support provided by the transient allogeneic grafts. We conclude that at equivalent doses fractionated TBI is significantly less effective than single-dose TBI to condition DLA-identical littermate dogs for marrow transplantation. These findings have implications for the design of conditioning programs in clinical transplantation, especially when T-cell-depleted marrow grafts are used.

[1]  H. Deeg,et al.  Single dose or fractionated total body irradiation and autologous marrow transplantation in dogs: effects of exposure rate, fraction size, and fractionation interval on acute and delayed toxicity. , 1988, International journal of radiation oncology, biology, physics.

[2]  R. Evans,et al.  Modification of radiation-induced damage to bone marrow stem cells by dose rate, dose fractionation, and prior exposure to cytoxan as judged by the survival of CFUs: application to bone marrow transplantation (BMT). , 1988, International journal of radiation oncology, biology, physics.

[3]  B. Sandmaier,et al.  What radiation dose for DLA-identical canine marrow grafts? , 1988, Blood.

[4]  T. MacVittie,et al.  Improved survival of dogs exposed to fission neutron irradiation and transplanted with DLA identical bone marrow. , 1987, Bone marrow transplantation.

[5]  K. Bradstock,et al.  Resistance to engraftment in irradiated dogs receiving T cell-depleted bone marrow transplants. , 1987, Transplantation proceedings.

[6]  W. Wilmanns,et al.  Hyperfractionation of total-body irradiation and engraftment of marrow from DLA-haploidentical littermates. , 1987, Transplantation proceedings.

[7]  H. Deeg,et al.  JOINT REPORT OF THE THIRD INTERNATIONAL WORKSHOP ON CANINE IMMUNOGENETICS: II. ANALYSIS OF THE SEROLOGICAL TYPING OF CELLS , 1987, Transplantation.

[8]  J. Gribben,et al.  Graft rejection following HLA matched T‐lymphocyte depleted bone marrow transplantation , 1986, British journal of haematology.

[9]  Nitin R. Patel,et al.  ALGORITHM 643: FEXACT: a FORTRAN subroutine for Fisher's exact test on unordered r×c contingency tables , 1986, TOMS.

[10]  H. Deeg,et al.  Joint report of the Third International Workshop on Canine Immunogenetics. I. Analysis of homozygous typing cells. , 1986, Transplantation.

[11]  H. Deeg,et al.  The canine major histocompatibility complex. Population study of DLA-D alleles using a panel of homozygous typing cells. , 2008, Tissue antigens.

[12]  D. V. van Bekkum,et al.  Factors controlling the engraftment of transplanted dog bone marrow cells. , 2008, Tissue antigens.

[13]  F. Khan,et al.  Radiobiological basis of total body irradiation with different dose rate and fractionation: repair capacity of hemopoietic cells. , 1981, International journal of radiation oncology, biology, physics.

[14]  H. Deeg,et al.  High-dose total-body irradiation and autologous marrow reconstitution in dogs: dose-rate-related acute toxicity and fractionation-dependent long-term survival. , 1981, Radiation research.

[15]  R. Storb,et al.  HEMOPOIETIC GRAFTS BETWEEN DLA‐IDENTICAL CANINE LITTERMATES FOLLOWING DIMETHYL MYLERAN: EVIDENCE FOR RESISTANCE TO GRAFTS NOT ASSOCIATED WITH DLA AND ABROGATED BY ANTITHYMOCYTE SERUM , 1977, Transplantation.

[16]  H. Withers,et al.  Response of mouse jejunum to multifraction radiation. , 1975, International journal of radiation oncology, biology, physics.

[17]  H. Withers,et al.  Four R's of radiotherapy , 1975 .

[18]  H. Withers,et al.  The kinetics of recovery in irradiated colonic mucosa of the mouse , 1974, Cancer.

[19]  H. Withers,et al.  Radiation survival and regeneration characteristics of spermatogenic stem cells of mouse testis. , 1974, Radiation research.

[20]  R. Storb,et al.  MARROW GRAFTS BETWEEN DL‐A‐MATCHED CANINE LITTERMATES , 1973, Transplantation.

[21]  R. Storb,et al.  Marrow infusions in dogs given midlethal or lethal irradiation. , 1970, Radiation research.

[22]  J. Till,et al.  REPAIR PROCESSES IN IRRADIATED MOUSE HEMATOPOIETIC TISSUE * , 1964, Annals of the New York Academy of Sciences.

[23]  J. Till,et al.  A direct measurement of the radiation sensitivity of normal mouse bone marrow cells. , 1961, Radiation research.

[24]  T. Puck,et al.  ACTION OF X-RAYS ON MAMMALIAN CELLS : II. SURVIVAL CURVES OF CELLS FROM NORMAL HUMAN TISSUES , 1957 .

[25]  T. Puck,et al.  ACTION OF X-RAYS ON MAMMALIAN CELLS , 1957, The Journal of experimental medicine.