Long-term survival of cardiac xenografts in fully xenogeneic (mouse --> rat) bone marrow chimeras.

BACKGROUND: The shortage of human hearts remains a major barrier to the efficacy of heart transplantation for the treatment of end-stage heart disease. One potential solution to the supply problem would be the use of hearts from nonhuman donors (xenografts). We have established a model of mouse to rat xenogeneic bone marrow chimerism, and in this study we have hypothesized that such chimeric rats will accept both donor and recipient specific heart grafts while rejecting third-party mouse and rat grafts. We also investigated humoral responses in naive and chimeric rats with and without donor murine cardiac grafts. METHODS: Recipient Lewis rats (n = 22) were given 1100 cGy lethal total body irradiation and the same day received 300 x 10(6) donor B10.BR mouse bone marrow cells intravenously. Peripheral blood of surviving rats (n = 18) was typed at 4 weeks and then monthly thereafter. Donor and recipient specific and third-party heterotopic heart transplantations were performed at 6 to 8 weeks after reconstitution with bone marrow. RESULTS: Multilineage bone marrow chimerism was produced in all experimental animals with complete replacement of recipient marrow by donor cells. Murine donor and rat recipient strain hearts transplanted in chimeric rats survived indefinitely. Third-party rat and mouse hearts were rejected, though at a slower rate than bone marrow matched naive controls. High levels of antimouse antibodies were detected in rats with rejected hearts. These antibodies were absent in chimeric animals with long-term surviving heart grafts. CONCLUSIONS: Long-term multilineage bone marrow chimerism can be produced in a mouse --> rat bone marrow transplant model. Long-term survival of donor specific and recipient specific vascularized cardiac grafts can be produced in these chimeric animals. These animals are clinically normal but show signs of subclinical immunosuppression regimen as they reject third-party hearts later than naive animals. Our results suggest that antibodies also play a significant role in concordant xenograft rejection, and induction of bone marrow chimerism can overcome this barrier.

Extra-anatomic bypass grafting for aortoesophageal fistula: a logical operation.

Aortoesophageal fistula (AEF) is an uncommon cause of upper gastrointestinal hemorrhage. Usually, but not always, patients present with a small sentinel bleed followed by a variable interval of apparent resolution, and then they experience a massive exsanguinating hemorrhage. The variable interval of time after the sentinel bleed is the period in which most AEFs resulting from thoracic aortic aneurysm have been successfully treated. Although only a few successful cases have been reported in the literature, most describe an in situ repair. We describe treatment of a late-presenting AEF due to a thoracic aneurysm with an extra-anatomic bypass graft for the aortic repair.

Establishment of fully xenogeneic (mouse-->rat) bone marrow chimeras: evidence for normal development and clonal deletion of mouse T cells.

BACKGROUND: Xenotransplantation is a potential solution to the critical shortage of transplantable organs. However, conventional immunosuppressive agents do not control the vigorous cellular and humoral rejection across species disparities. The induction of donor specific tolerance via bone marrow chimerism may be a method to avoid xenograft rejection. In xenogeneic chimeras, T cell repertoire selection plays an important role in the induction of tolerance. Until now a model of mouse-->rat multilineage chimerism has not been reported. This study reports the establishment of fully xenogeneic mouse-->rat multilineage chimeras and evaluates the role of T cell development and repertoire selection in tolerance induction in a xenogeneic environment. METHODS: Recipient rats were irradiated at a dose of total body irradiation ranging between 800-1100 cGy and injected with 120-300x10(6) donor mouse bone marrow cells. Chimeras were typed for engraftment at 4 weeks and then monthly thereafter. T cell repertoire was evaluated in chimeras using two-color flow cytometry and monoclonal antibodies directed against the variable portion of the beta chain of the T cell receptor. RESULTS: Fully xenogeneic multilineage bone marrow chimerism was produced in a mouse-->rat model by using ablative radiation and a high dose of donor cells. Mouse T cells develop in a phenotypically normal fashion in chimeric rats and the host rat is capable of deleting T cells that are reactive to the donor mouse strain. CONCLUSION: Long-term multilineage bone marrow chimerism can be produced in a mouse-->rat bone marrow transplant model. Mouse T cells develop in a phenotypically normal fashion and negative selection of specific T cell receptor-Vbeta occurs in a xenogeneic environment in a predictable fashion paralleling that for syngeneic or allogeneic transplantation.

Risk factors for clinically important adverse events after protamine administration following cardiopulmonary bypass.

OBJECTIVES: The purpose of this study was to determine risk factors for adverse events following protamine administration after cardiopulmonary bypass. BACKGROUND: Intravenous protamine administration is associated with a risk of severe systemic reactions. However, risk factors for these events have not been well delineated, thus hampering development of preventive strategies. METHODS: A case-control study nested within a cohort of consecutive patients undergoing surgery requiring cardiopulmonary bypass was performed. The primary case definition included those events (pulmonary hypertensive and systemic hypotensive) occurring within 10 min of protamine administration in the absence of other measurable causes of hemodynamic compromise. RESULTS: Comparing the 53 cases to the 223 control subjects, three risk factors were independently associated with events (multivariable odds ratio [95% confidence interval]): neutral protamine Hagedorn insulin use (8.18 [2.08, 32.2]); fish allergy (24.5 [1.24, 482.3]), and a history of nonprotamine medication allergy (2.97 [1.25, 7.07]). These risk factors demonstrated an increasingly strong association with progressively more specific case definitions. An estimated 39% of cardiopulmonary bypass patients had one or more of these risk factors. Prior intravenous protamine, central venous pressure prior to protamine, preoperative ejection fraction and the need for inotropes when coming off bypass did not exhibit statistically significant associations with events (all p > 0.15). Prior protamine allergy was associated specifically with an increased risk of pulmonary hypertension (multivariable odds ratio 189; 95% confidence interval 13, 2,856). CONCLUSIONS: Immunologic factors are important in predisposing individuals to protamine reactions, and a substantial proportion of patients are at considerably increased risk Strategies to reduce the risk of protamine-associated events are needed.

Cardiac xenotransplantation.

Heart failure is an important medical and public health problem. Although medical therapy is effective for many people, the only definitive therapy is heart transplantation, which is limited severely by the number of donors. Mechanical devices presently are used as "bridges" to transplantation. Their widespread use may solve the donor shortage problem, but at present, mechanical devices are limited by problems related to blood clotting, power supply, and foreign body infection. Cardiac xenotransplantation using animal donors is a potential biologic solution to the donor organ shortage. The immune response, consisting of hyperacute rejection, acute vascular rejection, and cellular rejection, currently prevents clinical xenotransplantation. Advances in the solution of these problems have been made using conventional immunosuppressive drugs and newer agents whose use is based on an understanding of important steps in xenoimmunity. The most exciting approaches use tools of molecular biology to create genetically engineered donors and to induce states of donor and recipient bone marrow chimerism and tolerance in xenogeneic organ recipients. The successful future strategy may use a combination of a genetically engineered donor and a chimeric recipient with or without nonspecific immunosuppressive drugs.

Effects of vesnarinone, a novel orally active inotropic agent with an immunosuppressive action, on experimental cardiac transplantation in rats.

BACKGROUND: Vesnarinone (VES) has been used for treatment of patients with congestive heart failure. In addition to inotropic effects, it seems to have immunosuppressive action. We tested the hypothesis that VES suppresses graft rejection, inotropic dysfunction caused by early rejection, and chronic coronary obstruction in a heterotopic rat cardiac transplantation model. METHODS: (1) To study acute rejection, hearts from Lewis-Brown Norway (LBN) rats were transplanted into Lewis rats, which were treated with or without VES (50 or 100 mg/kg/day orally). (2) In a functional study, LBN hearts with or without VES (100 mg/kg/ day) were isolated and perfused on day 3 after transplantation to assess inotropic response to isoproterenol (3 x 10(-8) M). (3) To study chronic rejection, Lewis hearts were transplanted into Fisher 344 rats, which were treated with or without VES (50 mg/kg/day) for 90 days. Coronary obstructive disease was assessed by morphometric analysis. There were five to six animals in each group. RESULTS: (1) VES (100 mg/kg/day) prolonged LBN heart survival (11.7 +/- 0.7 vs. 9.6 +/- 0.7 days in control; P < 0.05). (2) Left ventricular developed pressure was depressed in transplanted hearts regardless of VES treatment (84 +/- 12, 90 +/- 8 vs. 144 +/- 16 mmHg in untransplanted hearts; P < 0.01). The developed pressure after administration of isoproterenol in VES-treated hearts (184 +/- 20 mmHg) was higher than transplanted hearts without VES (118 +/- 16 mmHg; P < 0.05), and similar to untransplanted hearts (203 +/- 27 mmHg; P = NS). (3) Transplanted hearts treated with or without VES showed similar grades of rejection (2.0 +/- 0.3 vs. 2.6 +/- 0.2; P = NS), intimal area (6,996 +/- 3,186 vs. 13,441 +/- 5,165 microns2; NS), and coronary luminal obstruction (45 +/- 16% vs. 67 +/- 14%; NS). CONCLUSIONS: VES produces mild prolongation in survival of rat heart grafts, but has no significant effect on chronic graft atherosclerosis. VES preserves the positive inotropic effects of isoproterenol that are otherwise deteriorated by early acute rejection.

Fetal inoculation with donor cells in cardiac xenotransplantation.

BACKGROUND: In utero fetal inoculation with allogeneic cells has produced subsequent tolerance to experimental cardiac allografts. We attempted to extend this observation to a model of xenogeneic cardiac transplantation. METHODS: Lewis rat fetuses were inoculated with Golden Syrian hamster thymocytes (n = 5) or whole spleen cells (n = 5) on the tenth day of intrauterine life. Six weeks after the birth of pretreated fetuses, heterotopic cardiac transplantation using a hamster donor was performed. Three to 4 weeks after parturition, we performed heterotopic cardiac transplantation using hamster donors in the female Lewis rats whose fetuses had been treated in utero. RESULTS: Animals treated in utero with either thymocytes or whole spleen cells had graft survival of 3 days, not different from that in untreated Lewis rats (n = 5) (p = not significant). Maternal Lewis rats whose fetuses were treated with thymocytes (n = 5) or whole spleen cells (in = 4) had markedly reduced survival of xenogeneic cardiac grafts (range, 3 to 20 hours; mean, 15 hours; p < 0.01; and range, 5 to 15 minutes; mean, 10 minutes; p < 0.01, respectively). Female Lewis rats without intrauterine inoculation (n = 5) had expected xenograft survival time (3 days) (p = not significant). Immunohistochemical staining of hyperacutely rejected grafts showed deposits of immunoglobulin M as well as immunoglobulin G and complement. In normally rejected xenografts, no immunoglobulin M was detected. CONCLUSIONS: These studies reveal the surprising observation that fetal exposure to xenogeneic cells sensitizes the maternal rat without tolerizing the fetal rat as observed in an allograft model. In addition, whole spleen cells produce a more vigorous hyperacute rejection than thymocytes, suggesting that B cells or macrophages may be the sensitizing agents. The accelerated rejection observed has the characteristics of an immunoglobulin M antibody-mediated hyperacute rejection response with deposition of complement.

Induction of tolerance to an experimental cardiac allograft through intrathymic inoculation of class II major histocompatibility complex disparate antigens.

Indefinite donor-specific tolerance to a cardiac allograft can be induced through pretransplantation intrathymic injection of donor spleen cells and a single intraperitoneal injection of antilymphocyte serum. This study was designed to determine whether this phenomenon was reproducible with grafts differing in either class I major histocompatibility complex only or class II MHC only. Donors of cells and hearts in all experiments were RP rats. Class I MHC disparate grafts were performed by placing an RP heart into a Lewis recipient, and class II disparate grafts were performed with RP donors and Wistar Furth recipients. Lewis (n = 10) and Wistar Furth (n = 10) recipients underwent intraperitoneal injection of 1 ml antilympocyte serum and intrathymic injection of 5 x 10(7) RP spleen cells. Three weeks later, heterotopic cardiac transplantation was done with a heart from an RP rat. Control rats had no pretreatment or received antilympocyte serum alone. Without pretreatment, RP hearts survived 7 to 9 days (mean 8 days) in Lewis recipients (n = 5) and 9 to 14 days (mean 12 days) in Wistar Furth recipients (n = 5). Antilymphocyte serum alone produced slight prolongation of graft survival. Lewis rats pretreated with class I disparate RP splenocytes and antilympocyte serum had graft survivals of 8 to 27 days (mean 14 days), not significantly different from the results with antilympocyte serum alone. Class II disparate RP grafts placed in pretreated Wistar Furth rats had significant prolongation of graft survival, with four of five grafts surviving longer than 60 days (p < 0.01 vs antilympocyte serum alone). These results suggest that a disparity at the class II locus of the major histocompatibility complex is critical for the induction of cardiac allograft tolerance after intrathymic inoculation of allogeneic cells.

Different immune effects on cardiac allografts and xenografts induced by neonatal intrathymic inoculation with allogeneic and xenogeneic antigens.

BACKGROUND: In a previous study we demonstrated that intrathymic exposure of neonatal rats to both alloantigens and xenoantigens produced tolerance only to subsequent cardiac allografts and not to xenografts implanted when the animals were 6 weeks old. Interestingly, graft recipients were not sensitized to the xenografts as observed in the adult model. This study was designed to investigate whether earlier grafting would produce tolerance to cardiac xenografts in animals pretreated by neonatal intrathymic inoculation with allogeneic and xenogeneic cells. METHODS: All recipient animals were Lewis rats. Donors were either Lewis Brown Norway rats or Golden Syrian hamsters. Lewis Brown Norway rat and hamster splenocytes (25 x 10(6) cells in a volume of 0.01 ml) were inoculated percutaneously into the thymus of neonatal recipients (n = 22). At age 4 weeks, five pretreated recipients underwent cervical heterotopic heart transplantation with rat hearts, and 2 weeks later abdominal heterotopic transplantation was done with hamster donors. A second group ( n = 6) received hamster hearts as the first graft and then grafts from rat donors. The third group underwent rat followed by hamster heart transplantation at age 6 to 7 weeks. RESULTS: Mean rat allograft survival time for groups 1,2, and 3, respectively was 49.8 days with 4 of 5 surviving indefinitely, 4.3 days with 2 of 3 surviving indefinitely, and 42 days with 7 of 11 surviving indefinitely (p < 0.01 versus untreated control animals, 7.8 days, n = 5). In rats undergoing transplantation at 4 weeks, cardiac xenografts were rejected in 2.5 days 2.3 days, which was significantly shorter than xenograft survival (3.3 days) in rats that underwent transplantation at an older age (p < 0.02), in naive rats (p < 0.05), and in rats treated with hamster cells alone (p < 0.05). Mixed lymphocyte reaction showed a diminished proliferative response to Lewis Brown Norway rat cells in pretreated rats, which retained the ability to respond in culture to hamster cells (p < 0.05). CONCLUSIONS: Earlier grafting in rats pretreated as neonates produces allograft tolerance but may accelerate rejection of xenografts. Preliminary mixed lymphocyte reaction results suggest that only the alloimmune cellular proliferative response is abrogated by this pretreatment.

T-cell receptor expression in C57BL/6 mice that reject or are rendered tolerant to bm1 cardiac grafts.

To study the molecular immunologic features of allograft rejection and tolerance induction by intrathymic pretreatment we developed a murine model of cardiac transplantation. In this model the transplant recipient was the C57BL/6 mouse with its major histocompatibility phenotype H-2b. Donors of cells for intrathymic pretreatment and of hearts for grafting were mice of the bm1 mutation. The bm1 mutation involves substitution of three amino acids in one of the alpha helixes of the class I H-2Kb molecule. Because of the discrete molecular configuration of the transplant antigen we hypothesized that there would be limited heterogeneity of receptor expression on C57BL/6 T cells responding to bm1 cardiac grafts and that intrathymic pretreatment would alter the T-cell repertoire of graft recipients by causing elimination of T cells responsible for graft rejection. Mice were given 0.3 ml of antilymphocyte serum intraperitoneally and had intrathymic injection of 25 x 10(6) bm1 splenocytes 12 to 21 days before transplantation with a bm1 cardiac graft. Flow cytometric analysis of lymph node and spleen cells was used to study the V beta T-cell repertoire of graft recipients. Cells were stained with monoclonal antibodies to CD3 and 13 V beta regions (n = 5, each group) of T cells in naive, sensitized, and tolerant animals. Untreated C57BL/6 mice (n = 9) rejected bm1 cardiac grafts a mean of 20.4 days after transplantation. Twelve mice pretreated with antilymphocyte serum and intrathymic bm1 cells had permanent graft survival (> 100 days, p < 0.0001). Animals treated with antilymphocyte serum alone (n = 5) or pretreated animals undergoing third-party BALB/c grafts (n = 4) rejected grafts in the normal time frame. There was significant alteration of percentage receptor expression of V beta 5.1, 7, 12, 13, and 17a in sensitized and tolerant mice. Of interest, V beta 7 expression was increased in the sensitized mice (3.8% to 8.3%,p = 0.005) and was virtually eliminated in tolerant mice (p = 0.005). In conclusion, these data suggest that V beta 7 is a critical receptor in the C57BL/6 response to subcutaneous bm1 cardiac grafts. Pretreatment of graft recipients with one dose of antilymphocyte serum and intrathymic bm1 cells appears to produce permanent tolerance to bm1 grafts with elimination of T cells expressing receptor chain V beta 7.

Tolerance to cardiac allografts requires a time lag between intrathymic treatment and transplantation.

Permanent tolerance to an experimental heterotopic cardiac allograft can be achieved by pretreatment with antilymphocyte serum (ALS) and intrathymic inoculation of donor cells. Most successful experimental protocols have employed a time lag of 2 to 3 weeks between intrathymic pretreatment and transplantation, which makes this treatment strategy impractical for clinical heart transplantation. In these experiments we modified the standard protocol by giving ALS 24 hr prior to both intrathymic injection of donor cells and heterotopic transplantation. Seven Lewis rats had intraperitoneal injection of 1 ml of ALS and 24 hr later underwent intrathymic injection of 5 X 10(7) donor Lewis-Brown Norway (LBN) splenocytes and heterotopic cardiac transplantation using an LBN donor. Mean graft survival was 24.4 days, significantly longer than the 7.8-day graft survival observed in untreated Lewis recipients (n = 5) (P < 0.02). However, graft survival was not different from that observed in Lewis rats pretreated with ALS alone (n = 5) (25.8 days, P = NS). Permanent graft survival was produced in two rats receiving only A-LS and in one rat receiving both ALS and intrathymic inoculation. In these experiments it appears that prolongation of graft survival may have been due to the effect of A-LS alone. These results suggest that there is a critical time period between intrathymic inoculation and transplantation that is needed for permanent tolerance to be induced consistently. This may be due to the kinetics of the effects of ALS on alloreactive T-lymphocytes or to a time-dependent requirement for antigen processing in the thymus.