Pre-treatment of donor with 1-deamino-8-d-arginine vasopressin could alleviate early failure of porcine xenograft in a cobra venom factor treated canine recipient.

OBJECTIVE: Unlike cardiac or renal xenotransplants, the depletion of complement using cobra venom factor (CVF) does not improve pulmonary xenograft survival. Several cases suggest that the swine von Willebrand factor (vWF) may play a major role in presenting a different pathogenesis of pulmonary xenograft dysfunction from other organs. To evaluate the role of vWF and the complement system in mediating hyperacute vascular injury of pulmonary xenografts and elucidate pathogenesis of the injury, we performed swine-to-canine orthotropic single lung xenotransplantation after pre-treatment of 1-deamino-8-d-arginine vasopressin (DDAVP) and CVF. METHODS: We set up three groups for lung xenotransplantation: group I served as the control group; group II, recipients pre-treated with CVF; group III, donors pre-treated with DDAVP (9 mg/kg, 3 days)/recipients pre-treated with CVF (60 u/kg). Hemodynamic data, coagulation and complement system parameters, and grafted lung pathologies were examined serially for 3h after transplantation. RESULTS: DDAVP infusion reduced the vWF content in swine lung tissue in vivo (7.7+/-2.4 AU/mg vs 16.0+/-5.6 AU/mg, P < 0.0001). Infusion of CVF 24 h prior to transplantation effectively depleted the recipient's serum C3 and complement hemolytic activity below the detectable range. Regardless of the use of CVF, both groups I and II transplanted with unmodified grafts showed an immediate drop in leukocytes and platelet counts after transplantation. However, in group III, in recipients transplanted with DDAVP pre-treated swine lung, the platelet count did not decrease after transplantation (P = 0.0295). The decrease of plasma antithrombin and fibrinogen tended to be attenuated in group III. Light microscopic examination revealed extensive vascular thromboses in both capillary and larger vessels, as well as early pulmonary parenchymal damage in groups I and II, but were rarely observed in group III. CONCLUSIONS: Complement inhibition alone was not enough to alleviate intravascular thrombosis, the main pathology in pulmonary xenotransplantation. Pre-infusion of DDAVP to the donor animal was effective in preventing platelet sequestration and attenuated intravascular thrombosis. It is suggested that the strategies targeting vWF would be promising for successful pulmonary xenotransplantation.     

Characterization of a pig-to-goat orthotopic lung xenotransplantation model to study beyond hyperacute rejection.

BACKGROUND: A pig-to-goat orthotopic lung xenograft model was developed to test whether depletion of goat xenoreactive antibodies against pig red blood cells would prolong pig lung xenograft survival. METHODS: Adult goats with anti-pig xenoreactive antibodies underwent left pneumonectomy followed by orthotopic transplantation of pig left lung (group 1) or immunodepletion of their xenoreactive antibodies by extracorporeal right pig lung perfusion before transplantation without (group 2) or with (group 3) complete clampage of the right pulmonary artery. In group 4, goat left lungs were orthotopically transplanted into pigs and served as negative controls (pig serum does not have anti-goat xenoreactive antibodies). Each study group included 5 animals. Immunosuppression in surviving recipients included cyclosporine and azathioprine. RESULTS: Group 1 recipients died 7 +/- 3 hours after xenograft reimplantation of severe pulmonary hypertension and dysfunction and vasogenic shock, with little evidence of histologic xenograft injury. Group 2 xenografts had a stable circulatory and respiratory function on reperfusion and survived 9 +/- 4 days. Group 3 animals also tolerated complete occlusion of the right pulmonary artery, and xenografts assured the total respiratory support for 4 +/- 1 days. After immunodepletion, goat serum showed no detectable titers of xenoreactive antibodies, which began to reappear by postoperative day 2, where xenografts showed histologic stigmata of acute (humoral and cellular-mediated) rejection that evolved to a complete xenograft necrose at death. Group 4 xenografts showed scattered features of acute rejection 5 +/- 1 days after the operation. CONCLUSIONS: Pig left lung xenografts can provide prolonged and complete respiratory support after depletion of goat xenoreactive antibodies, but they ultimately necrose once recipient xenoreactive antibodies return to pretransplantation values.     

The hemodynamic effects of propofol in children with congenital heart disease

We studied the hemodynamic effects of propofol during elective cardiac catheterization in 30 children with congenital heart disease. Sixteen patients were without cardiac shunt (Group I), six had left-to-right cardiac shunt (Group II), and eight had right-to-left cardiac shunt (Group III). The mean (+/-SD) ages were 3.8+/-3.1 yr (Group I), 3.2+/-3.7 yr (Group II), and 1.0+/-0.6 yr (Group III). After sedation and cardiac catheter insertion, hemodynamic data and oxygen consumption were measured before and after the administration of propofol (2-mg/kg bolus, 50- to 200-microg x kg(-1) x min(-1) infusion), and values were compared by using a paired t-test (significance: P < 0.05). After the propofol administration, systemic mean arterial pressure and systemic vascular resistance decreased significantly and systemic blood flow increased significantly in all patient groups; heart rate, pulmonary mean arterial pressure, and pulmonary vascular resistance were unchanged. Pulmonary to systemic resistance ratio increased (Group I, P = 0.005; Group II, P = 0.03; Group III, P = 0.10). In patients with cardiac shunt, propofol resulted in decreased left-to-right flow and increased right-to-left flow; the pulmonary to systemic flow ratio decreased significantly (Group II, P = 0.005; Group III, P = 0.01). Clinically relevant decreases in Pao2 (P = 0.008) and Sao2 (P = 0.01) occurred in Group III patients. We conclude that propofol can result in clinically important changes in cardiac shunt direction and flow. IMPLICATIONS: The principal hemodynamic effect of propofol in children with congenital heart defects is a decrease in systemic vascular resistance. In children with cardiac shunt, this results in a decrease in the ratio of pulmonary to systemic blood flow, and it can lead to arterial desaturation in patients with cyanotic heart disease.     

Therapeutic regulation of systemic inflammation in xenograft recipients

Inflammation is known to preclude tolerance after transplantation. We have previously shown that systemic inflammation in xenograft recipients (SIXR) precedes activation of coagulation in the absence of T cell responses. Accordingly, SIXR may amplify innate and adaptive immune responses against xenografts after pig‐to‐primate xenotransplantation, even with efficient immunosuppressive therapy. We evaluated the impact of anti‐inflammatory agents on pro‐inflammatory cytokines and chemokines in pig artery patch and heart xenograft recipients. Baboons received an artery patch (Group1, n=8) or heart (Group2, n=4) from genetically engineered pigs. All baboons received lymphodepletion with thymoglobulin (ATG) and costimulation blockade‐based immunosuppression (anti‐CD40 and/or CTLA4Ig). In Group1, baboons received either (i) no anti‐inflammatory agents (n=2), (ii) cobra venom factor (CVF, n=2), (iii) α1‐antitrypsin (AAT, n=2), or (iv) interleukin (IL)‐6 receptor antagonist (IL‐6RA, n=2). In Group2, all baboon received corticosteroids, either without (n=2) or with (n=2) IL‐6RA. Serum IFN‐γ, TNF‐α, IL‐1β, IL‐17, IL‐6, IL‐8, MCP‐1, and sCD40L levels were measured by Luminex. Fibrinogen, D‐dimers, and C‐reactive protein (C‐RP) were also measured. Recipient baboon T cell proliferation was evaluated by mixed lymphocyte reaction (MLR) before and after transplantation. Pig and baboon tissue factor (TF) mRNA levels in heart xenografts were measured by RT‐PCR. In no recipient was a marked increase in T cell response to pig cells observed after transplantation. In Groups 1 and 2, post‐transplantation levels of IFN‐γ, TNF‐α, IL‐1β, and IL‐17 remained comparable to or lower than pre‐transplant levels, except in one heart recipient that succumbed to CMV infection. In Group1, when no anti‐inflammatory agent was administered, post‐transplant levels of IL‐6, IL‐8, and MCP‐1 were elevated. After CVF, IL‐6, IL‐8, and MCP‐1 remained low. After IL‐6RA, IL‐6 and MCP‐1 were elevated. After AAT, IL‐8 was elevated. sCD40L became elevated intermittently in most recipients irrespective of the administered anti‐inflammatory agent. In Group2, IL‐6 was transiently elevated, particularly after IL‐6RA administration. MCP‐1 gradually increased by 2 months in Group2 recipients. sCD40L generally remained low except in one recipient. In Group1 and Group2 recipients, C‐RP levels were elevated except after IL‐6RA administration, while D‐dimers were elevated regardless of administration of anti‐inflammatory agent. In Group2, pig TF mRNA levels were increased in heart xenografts compared to naive pig hearts, irrespective of IL‐6 receptor antagonist administration. Additionally, baboon TF mRNA levels were detectable in heart xenografts, but not in naive pig hearts. Some pro‐inflammatory cytokines and chemokines are elevated in xenograft recipients, even with efficient T cell‐directed immunosuppressive therapy. Persistent elevation of D‐dimers, and individual cytokines and chemokines suggest a continuous inflammatory response, despite administration of anti‐inflammatory agents. Systemic administration of combined anti‐inflammatory agents as well as complement regulation may be essential to prevent SIXR after xenotransplantation.     

Complement depletion in a porcine model of septic acute respiratory disease

In a porcine model of severe septic acute respiratory failure produced by continuous infusion of live Pseudomonas aeruginosa, the role of the complement system was studied by pretreating animals with cobra venom factor (CVF) to deplete C3. Three groups of spontaneously breathing animals were monitored with Swan-Ganz and arterial thermodilution catheters. Group I was pretreated with 80 U/kg of CVF iv 16-18 hours before testing. Group II received Ps. aeruginosa iv (2 X 10(8)/20 kg/minute). Group III was pretreated with CVF and later given the Pseudomonas infusion. The CH50 as a measure of complement activity was less than 7% of normal level in Groups I and III. No changes in respiratory variables occurred in Group I. In Group II, the mean pulmonary artery pressure doubled, intrapulmonary shunt fraction (Qs/Qt) increased, PaO2 decreased, and extravascular lung water doubled in 4 hours. In Group III, the pulmonary hypertension, hypoxemia, increase in Qs/Qt, and increase in EVLW were all significantly less than in Group II. Neutropenia occurred with the Pseudomonas infusion in Groups II and III.     

Mechanism of delayed rejection in transgenic pig-to-primate cardiac xenotransplantation

BACKGROUND: Pig-to-primate cardiac xenografts undergo hyperacute rejection (HAR), in which primate IgM bind to porcine endothelial alpha-Gal molecules and activate membrane attack complex (MAC) deposition. Prolonged graft survival can be achieved by using transgenic pig donors, which express human complement regulatory proteins (hCRP) to inhibit MAC. However, these xenografts invariably fail from delayed xenograft rejection (DXR). We sought to investigate the poorly understood DXR process. MATERIALS AND METHODS: Wild-type (n = 3) and transgenic (n = 3) porcine hearts were heterotopically transplanted into baboons. Biopsies were analyzed by histology and by immunohistochemistry for porcine endothelial markers (vWF, alpha-Gal, and beta-Gal) and primate IgM and MAC deposition. RESULTS: Wild-type xenografts survived 60-80 min but succumbed to rapid IgM/MAC deposition and microvascular thrombosis. Transgenic xenografts avoided HAR but showed increasing IgM/MAC deposition before rejection on days 5, 7, and 11. Serum from baboons after transgenic xenograft rejection showed increased activity against porcine endothelial cells, and in vitro incubation of untransplanted porcine cardiac sections with sensitized baboon serum showed elevated microvascular IgM binding. Increased IgM deposition appeared specific to alpha-Gal, since it competes specifically with alpha-Gal-specific GS-4 lectin, but not with beta-Gal-specific RCA-1 lectin. Competition with GS-4 was not seen if na?ve baboon serum was used. CONCLUSION: DXR may be mediated by increasing baboon IgM binding on porcine microvascular endothelial alpha-Gal molecules.     

Disseminated intravascular coagulation in association with pig-to-primate pulmonary xenotransplantation

BACKGROUND: Profound coagulopathy has been proposed as a barrier to xenotransplantation. Disseminated intravascular coagulation (DIC) has been observed with the rejection of renal and bone marrow xenografts but has not yet been described in pulmonary xenografts. METHODS: This study examined the coagulation parameters in five baboons that received pulmonary xenografts and one baboon that was exposed to porcine lung during an extracorporeal perfusion. Platelet counts, prothrombin times (PT), and levels of fibrinogen, D-dimers, and thrombin-antithrombin III complex (TAT) were analyzed. In addition, serum levels of plasminogen activator inhibitor-1 (PAI-1), thrombomodulin (TM), tissue plasminogen activator (tPA), and tissue factor (TF) were determined. RESULTS: Hyperacute pulmonary xenograft dysfunction, which occurred within 0-9 hr of graft reperfusion, was associated with clinically evident DIC. This coagulopathy was characterized by thrombocytopenia, decreased fibrinogen levels, elevations in PT, and increases in D-dimers and TAT. Furthermore, transient increases in PAI-1, increases in TM, and increases in tPA were observed in the serum of some but not all recipients. None of the baboons demonstrated measurable increases in soluble TF. CONCLUSIONS: Although DIC in renal or bone marrow xenotransplantation develops over a period of days, DIC associated with hyperacute pulmonary xenograft dysfunction develops within hours of graft reperfusion. Thus, the DIC in pulmonary xenotransplantation may represent a unique and/or accelerated version of the coagulopathy observed with renal and bone marrow xenotransplantation.     

Comparative hemodynamic effects of selective superior mesenteric arterial and peripheral intravenous glucagon infusions

This experiment was designed to determine whether any hemodynamic benefits attend administration of equal pharmacologic doses of glucagon (1 micrograms/kg/m) by continuous intravenous infusion (Group I, n = 6) versus selective intraarterial infusion (Group II, n = 6) via the superior mesenteric artery (SMA) in dogs. Cardiac output, heart rate, mean arterial pressure, total peripheral resistance, pulmonary vascular resistance, superior mesenteric artery flow (SMAQ), SMA vascular resistance, and portal venous pressure were measured at baseline (BL) and at 5, 15, 30, and 45 min during glucagon infusion. SMAQ virtually doubled at 5 min from a baseline of 570 +/- 60 ml/min to 1158 +/- 146 ml/min in Group I (P less than 0.001), and from a baseline of 527 +/- 171 to 1018 +/- 331 ml/min in Group II (P less than 0.002). SMAQ was significantly higher in Group I at 30 and 45 min compared to Group II (P less than 0.03) despite similar peripheral plasma glucagon levels. SMA vascular resistance was significantly lowered in both groups, with a greater reduction occurring during intravenous glucagon administration at 45 min (P less than 0.05). Changes in systemic hemodynamic parameters, as well as glucagon and glucose levels were not statistically different between Groups I and II at any time period. Glucagon is a potent mesenteric vasodilator and the resultant profound splanchnic hemodynamic effects are as marked during intravenous administration as during selective SMA infusion.     

The role of the porcine von Willebrand factor: baboon platelet interactions in pulmonary xenotransplantation

BACKGROUND: Porcine von Willebrand factor (pvWF) has been shown to bind to human glycoprotein Ib (GPIb) and cause activation of human (or primate) platelets in the absence of shear stress. Pulmonary xenografts develop disseminated intravascular coagulation (DIC) and microvascular thrombosis within hours of reperfusion, and the aberrant interaction between pvWF and human platelets may be a possible cause of xenograft-associated DIC. METHODS: Experimental baboons (n=3) received mouse anti-human GPIb monoclonal antibody before undergoing orthotopic pulmonary xenotransplantation with porcine lungs expressing human membrane cofactor protein (CD46). RESULTS: Blocking the pvWF-GPIb interaction with a monoclonal antibody to GPIb prevented the agglutination of human and baboon platelets by pvWF in vitro. In vivo, the anti-GPIb antibody prevented platelet deposition and prevented the increases in D-Dimers (P=0.011) seen in control xenograft recipients (n=5). However, there was no difference in elevations of prothrombin times (PT) or improvement in the vasoconstriction associated with the loss of xenograft function. CONCLUSIONS: This study indicates that the DIC associated with the hyperacute dysfunction of pulmonary xenografts is a complex phenomenon that is affected by, but not solely dependent on, activation of platelets. Aberrant interactions between pvWF and GPIb play a significant role in DIC associated with pulmonary xenotransplantation.     

Toward a better understanding of the hemodynamic effects of protamine and heparin interaction

Hemodynamic changes have been documented during protamine infusion into heparinized but not unheparinized pigs and suggest that a protamine-heparin interaction might be responsible. This hypothesis was tested in four groups of pigs by varying the dosage and order of administration of these two drugs: Group I (n = 9) received heparin (3 mg/kg) followed by protamine (3 mg/kg); Group II (n = 9) received protamine (3 mg/kg) followed by heparin (3 mg/kg); Group III (n = 9) received protamine (25 mg/kg) followed by heparin (3 mg/kg); and Group IV (n = 16) received protamine-heparin complex (protamine 3 mg/kg and heparin 3 mg/kg mixed immediately prior to injection). Systemic and pulmonary arterial pressures, systemic and pulmonary vascular resistances, left ventricular end-diastolic pressure, central venous pressure, cardiac output, and heart rate were measured before and at 1.0, 2.5, 5.0, and 15 minutes after protamine, heparin, or protamine-heparin complex infusions. Immediately following protamine infusion, Group I pigs exhibited transiently but significantly increased pulmonary artery pressure, pulmonary vascular resistance, systemic vascular resistance, and central venous pressure and decreased cardiac output with (Group Ib, n = 5) or without (Group Ia, n = 4) systemic hypotension. The fact that no hemodynamic changes occurred in Group II confirms that infusion of clinical doses of protamine produces no hemodynamic changes in unheparinized pigs. Protamine alone in high doses (Group III) produced hemodynamic changes similar to clinical-dose protamine reversal of heparin (Group I). This effect suggests that the presence of heparin in the circulation lowers the threshold for protamine-mediated hemodynamic responses. Infusion of heparin (3 mg/kg) into pigs 15 minutes after treatment with high (25 mg/kg) (Group III) but not clinical (3 mg/kg) (Group II) doses of protamine produced hemodynamic effects similar to clinical-dose protamine reversal of heparin (Group I), suggesting that a protamine-heparin interaction may be responsible. These results also suggest a rapid inactivation in vivo of clinical doses (3 mg/kg) (Group II) of infused protamine. Protamine-heparin complex formed in vitro (Group IV) also produced hemodynamic changes similar to clinical-dose protamine reversal of heparin (Group I), suggesting that formation of this complex in vivo may be the protamine-heparin interaction responsible. Protamine-heparin complex may well be a useful tool in further elucidating the full effects of protamine reversal of heparin.     

Effects of pneumonectomy on pulmonary input impedance

The long-term effects of pneumonectomy on the pulmonary circulation quantifiable through pulmonary input impedance analysis were studied. Excision of the left lung was performed in purebred beagle dogs aged 6 to 10 weeks (n = 6 group I) or 1 year (n = 8 group II). Unoperated beagles served as controls (n = 8 group III). When the dogs were 5 years of age, pulmonary pressure and flow were measured and the impedance spectra calculated. Characteristic impedance (Zo) (indicative of changes in proximal vessel physical properties) and pulmonary vascular resistance (PVR) (indicative of the distal response) were estimated. In group III the cardiac output (CO) was 1.7 +/- 0.4 L/min, mean pressure 16 +/- 5 mm Hg, PVR 605 +/- 448 dyne-sec/cm, and Zo 204 +/- 76 dyne-sec/cm. Group I results exhibited bimodal distributions that were not statistically different from results of groups II or III; four dogs had spectra comparable to those of group III, while two dogs had developed moderate hypertension and high PVR and Zo. Group II results were more normally distributed, and comparison with group III indicated statistically significant differences (P less than 0.05) in CO (1.1 +/- 2 L/min), PVR (1396 +/- 573 dynes-sec/cm), and Zo (543 +/- 273 dynes-sec/cm). Doubling of PVR and Zo in group II indicated that proximal vessel compliance and peripheral perfusion radius had not increased following pneumonectomy in adult beagles. Group I results indicate that marked facilitory adaptation can occur when pneumonectomy is performed in puppies; however, the adaptation may not be based on true lung growth and, therefore, may not be sustained indefinitely.     

hDAF porcine cardiac xenograft maintains cardiac output after orthotopic transplantation into baboon--a perioperative study

BACKGROUND: Only limited data are available on the physiological functional compatibility of cardiac xenografts after orthotopic pig to baboon transplantation (oXHTx). Thus we investigated hemodynamic parameters including cardiac output (CO) before and after oXHTx. METHODS: Orthotopic xenogeneic heart transplantation from nine hDAF transgeneic piglets to baboons was performed. We used femoral arterial thermodilution for the invasive assessment of CO and stroke volume. RESULTS: Baseline CO of the baboons after induction of anesthesia was 1.36 (1.0-1.9) l/min. 30 to 60 min after termination of the cardiopulmonary bypass, CO of the cardiac xenograft was significantly increased to 1.72 (1.3-2.1) l/min (P < 0.01). The stroke volumes of the baboon heart before transplantation and the cardiac xenograft was comparable [14.9 (11-26) vs. 11.8 (10-23) ml]. Thus the higher CO was achieved by an increase in heart rate after oXHTx [75.0 (69-110) vs. 140.0 (77-180)/min; P < 0.01]. Despite the increased CO, oxygen delivery was reduced [256 (251-354) vs. 227 (172-477) ml/min; P < 0.01] due to the inevitable hemodilution during the cardiopulmonary bypass and the blood loss caused by the surgical procedures. CONCLUSION: Our results demonstrate that in the early phase after orthotopic transplantation of hDAF pig hearts to baboons, cardiac function of the donor heart is maintained and exceeds baseline CO. However, in the early intraoperative phase this was only possible by using inotropic substances and vasopressors due to the inevitable blood loss and dilution by the priming of the bypass circuit.     

Pulmonary edema: reversal by ultrafiltration

Ultrafiltration, the process by which plasma water is removed from the blood was utilized to determine its effect on lowering lung water in pulmonary edema produced by fluid overload, steam inhalation, and endotoxin. Lung water was measured by the thermal-dye indicator dilution technique which correlated well with lung water measured gravimetrically over a wide range (r = 0.95). Edema was produced by fluid overload in five mongrel dogs (Group I), by steam inhalation (Group II), and by endotoxin (Group III). Extravascular lung water (EVLW) rose significantly (P = less than 0.05) from control levels with the production of the edematous states (Group I: 8.0 ml/kg (mean) +/- 1.9 (SD) to 13.1 +/- 1.9); (Group II: 8.1 +/- 1.0 to 10.7 +/- 0.7); (Group III: 7.4 +/- 0.9 to 10.3 +/- 1.2). EVLW then fell significantly (P = less than 0.05) after ultrafiltration in all three groups (Group I: 8.9 +/- 2.4; Group II: 7.8 +/- 1.9; Group III: 7.7 +/- 1.4). Ultrafiltration was effective in reversing pulmonary edema and may have clinical application when excess lung water interferes with cardiac or pulmonary function.     

Non-anti-Gal alpha1-3Gal antibody mechanisms are sufficient to cause hyperacute lung dysfunction in pulmonary xenotransplantation

BACKGROUND: Hyperacute lung dysfunction, which is always associated with pulmonary pig-to-primate xenotransplantation is not well understood. The mechanisms associated with its occurrence seem to differ from mechanisms involved in hyperacute xenograft rejection seen in porcine hearts or kidneys transplanted into primates. To determine the contribution of anti-Gal alpha1-3Gal antibodies (alphaGAb) in such a process, we performed a set of orthotopic pig lung transplants into baboons depleted of alphaGAb and compared graft function and survival with those receiving only immunosuppression. STUDY DESIGN: Pigs expressing human membrane cofactor protein served as donors. All baboons received triple immunosuppressive therapy. Depletion of alphaGAb in the experimental group (n = 4) was done by way of immunoadsorption using immunoaffinity membranes. Controls (n = 4) did not undergo immunoadsorption. Orthotopic lung transplants were performed through a left thoracotomy. Main pulmonary artery blood flow and pressure, left pulmonary artery blood flow, and left atrial pressure were recorded. RESULTS: At 1 hour after reperfusion, pulmonary artery graft flows and pulmonary vascular resistances (PVR) were better in animals depleted of alphaGAb than in controls (605 +/- 325.2 mL/min versus 230 +/- 21 mL/min; 27.1 +/- 41.3 mmHg/L/min versus 63 +/- 1 mmHg/L/min). But at 3 hours after reperfusion average graft flows in baboons depleted of alphaGAb had decreased to 277.6 +/- 302.2 mL/min and PVRs had increased 58.3 +/- 42.0 mmHg/L/min. On the other hand, controls maintained stable flows and PVRs (223 +/- 23 mL/min; 61 +/- 3 mmHg/L/min). Survival was ultimately better in control baboons when compared with alphaGAb depleted ones (12.2 +/- 3.3 h versus 4.4 +/- 3.2 h). CONCLUSION: Unlike heart and kidney xenograft transplants, hyperacute lung xenograft dysfunction seems to be mediated by factors other than alphaGAb.     

Immunopathology of an hDAF transgenic pig model liver xenotransplant into a primate

BACKGROUND: hDAF transgenic pigs do not display the inherent hyperacute rejection reactions of pig-to-primate xenotransplants. The purpose of this study was to determine the immunopathologic phenomena following an hDAF transgenic pig hepatic orthotopic xenotransplant into a baboon. METHODS: Donor animals were unmodified pigs (n=4) and hDAF transgenic pigs (n=2). Recipient animals were baboons (Papio anubis). Liver biopsies were immunostained using monoclonal antibodies to C3, C5b-9, IgG, IgM, CD2, CD4, CD8, CD68, CD20, Bric 216, CD31, and fibrin, and polyclonal antibody to C4. RESULTS: hDAF transgenic grafts showed IgG, IgM, and C4 endothelial deposits. However, no fibrin, C3, or C5b9 deposits were observed after reperfusion. hDAF xenografts displayed CD31 staining in the portal spaces, perilobular areas, and at hepatic sinuisoidal levels. The baboon that lived for 4 days displayed either CD4 or CD8 T-cells periportal infiltrate. CONCLUSIONS: Future studies will seek to determine the physiologic role of CD31 hepatic sinusoidal expression in transgenic xenotransplants, and will also study the role of T-cell infiltrates in xenograft rejection.     

联合药物预处理对非协调性异种心脏移植物的影响

目的　观察联合应用环孢素A(CsA)和来氟米特 (Lef)预处理对豚鼠 大鼠非协调性异种心脏移植物的影响并探讨其作用机制。方法　移植大鼠分为 4组 :A组 (CVF ,n =10 ) ;B组(CVF CsA ,n =8) ;C组 (CVF Lef,n =5 ) ;D组 (CVF CsA Lef ,n =11) ;记录移植物存活时间 ,检测移植物病理组织学 ,用免疫组织化学检测移植物CD68、CD5 7表达情况 ,TUNEL法检测移植物细胞凋亡。结果　移植物的平均存活时间 :A组为 41h、B组为 68h、C组为 5 5h、D组为 82h。各组移植物病理表现均为急性血管性排斥反应 (AVR)改变。B、C、D组移植物炎症细胞浸润数减少 ,CD68和CD5 7表达下调 ,凋亡指数较低 ,半定量测定与A组比较差异有显著性 (P <0 .0 5 ) ;D组凋亡指数最低而CD68和CD5 7表达最弱 ,与其他各组比较差异有显著性 (P <0 .0 5 )。结论　联合应用CsA和Lef预处理可明显延长非协调性异种移植物存活时间 ,减少炎症细胞浸润 ,抑制心肌细胞凋亡 ,减轻异种AVR损害。     

Increased prostacyclin and adverse hemodynamic responses to protamine sulfate in an experimental canine model

Prostanoid activity was correlated with the hemodynamic effects of protamine sulfate reversal of heparin in 24 dogs undergoing three different pretreatment regimens: Group I (n = 8) received saline, Group II (n = 8) received the thromboxane synthetase inhibitor U63,557A (30 mg/kg), and Group III (n = 8) received indomethacin (10 mg/kg). Pretreatment substances were administered as 5-min intravenous infusions 20 min before anticoagulation with intravenous heparin (150 IU/kg). Protamine sulfate (1.5 mg/kg) was subsequently given as a 10-sec intravenous infusion 30 min after heparin had been administered. Hemodynamic data, as well as prostacyclin (PGI2) and thromboxane (TxA2) activity in aortic, venous, and pulmonary artery blood samples, were assessed over a 30-min time period following protamine administration. Group III indomethacin pretreatment provided the most protection from declines in blood pressure, heart rate, cardiac output, venous oxygen saturation, oxygen consumption, and elevations in pulmonary pressures and was accompanied with actual declines in PGI2. Group II U63,557A pretreatment was associated with the most severe hemodynamic changes and the greatest increase in PGI2 (+576%). Elevated PGI2 correlated with hypotension at 1 and 3 min (P less than 0.01), as well as pulmonary artery pressure declines at all times following protamine reversal. TxA2 changes did not correlate with hemodynamic changes. Protamine's adverse hemodynamic responses were attenuated with cyclooxygenase blockade by indomethacin, but were worsened with selective TxA2 blockade with U63,557A. Excess arachadonic acid precursors in the latter setting may increase PGI2 production. This study, for the first time, raises the possibility that PGI2 contributes to the adverse effects accompanying protamine reversal of heparin anticoagulation.     

Experimental studies on reimplantation response after lung transplantation

The reimplantation response after lung transplantation may critically impair the function of transplanted lungs in the early postoperative period. The purpose of this study is to evaluate the factors which cause this reimplantation response. Using canine left lungs, four groups were studied. Group I underwent complete hilar stripping (n = 6). Group II underwent complete hilar stripping and kept in warm ischemia for 60 min. by clamping left pulmonary artery and veins (n = 6). Group III underwent the same surgery as Group II and administered superoxide dismutase (SOD) (12000 U/kg/h) during reperfusion (n = 7). Group IV underwent autotransplantation of left lung (n = 6). To evaluate the function of left lung, arterial blood gas, pulmonary arterial pressure, aortic pressure, cardiac output and left extravascular lung water (liter EVLW) were measured in a transient contralateral pulmonary arterial occlusion before operation and 60 min. after reventilation and reperfusion. The measurement of EVLW was performed by thermal-green dye double indicator dilution method. The results obtained were as follows. 1) The values of liter EVLW measured in rt. pulmonary arterial occlusion were extremely well correlated with those of both lung EVLW. (r = 0.943 p less than 0.001). 2) The ratios of postoperative-liter EVLW: preoperative-liter EVLW and postoperative-total pulmonary resistance (TPR): preoperative-TPR were as follows: Group I; 1.29 +/- 0.19 and 1.23 +/- 0.36, Group II; 1.85 +/- 0.49 and 1.69 +/- 0.36, Group III; 1.28 +/- 0.17 and 1.50 +/- 0.36 Group IV; 2.28 +/- 0.40 and 1.70 +/- 0.34. These data indicate that the most important factor of reimplantation response at the time of this acute phase is the oxygen free radical-induced reperfusion injury. Hilar stripping, ischemic injury and surgical trauma are also important factors of reimplantation response. Vascular anastomosis is not so important when it is done well technically. 3) Administration of SOD provides protection against lung edema after lung transplantation.     

Complement activation during cardiopulmonary bypass. Comparison of bubble and membrane oxygenators

A prospective randomized trial involving 91 patients undergoing cardiopulmonary bypass compared the effects of bubble oxygenators (with and without methylprednisolone sodium succinate) and membrane oxygenators on complement activation and transpulmonary sequestration of leukocytes. Patients were divided as follows: Group I, 30 patients, bubble oxygenator; Group II, 31 patients, bubble oxygenator and methylprednisolone sodium succinate (30 mg/kg); Group III, 30 patients, membrane oxygenator. In Group I, C3a increased from 323 +/- 171 ng/ml during cardiopulmonary bypass to 1,564 +/- 785 ng/ml at 25 minutes after bypass (p less than 0.0001). A significant decrease in C3a was found in Groups II and III compared to Group I (p less than 0.0001). C5a did not change significantly during cardiopulmonary bypass in any group. Reestablishment of pulmonary circulation at the end of bypass produced significant transpulmonary leukocyte sequestration in Group I; the median cell difference was 1,700/microliter. Transpulmonary sequestration was significantly (p less than 0.0001) less in Group II (median cell difference = 200/microliter) and in Group III (median cell difference = 400/microliter) than in Group I. We conclude that cardiopulmonary bypass with a bubble oxygenator alone initiates significantly (p less than 0.0001) more C3a activation and leukocyte sequestration than when methylprednisolone sodium succinate (30 mg/kg) is given 20 minutes before the start of cardiopulmonary bypass with a bubble oxygenator or when a silicone membrane oxygenator is used.     

Preparation of the left ventricle for anatomical correction in patients with simple transposition of the great arteries. Surgical guidelines

Pulmonary artery banding in combination with an aortopulmonary shunt was performed on 16 patients with simple transposition of the great arteries to prepare the left ventricle for anatomical correction. Three groups were identified after operation: Group I (four patients) had increased pulmonary blood flow and tight pulmonary artery banding; Group II (four patients) had increased pulmonary blood flow and moderate pulmonary artery banding; Group III (eight patients) had normal pulmonary blood flow and moderate pulmonary artery banding. Postoperative low cardiac output was present in all patients in Group I, whereas mild heart failure was present in two patients in Group II and in two in Group III. There was one hospital death (6%). The follow-up period was 125 patient-months. Left ventricular systolic pressure rose from 63 +/- 11 torr before the operation to 101 +/- 35 torr after the procedure in Group I (p less than 0.05), from 59 +/- 10 to 93 +/- 33 torr in Group II (p less than 0.05), and from 55 +/- 10 to 84 +/- 16 torr in Group III (p less than 0.005). The increase in left ventricular muscle mass was from 44 +/- 2 gm/m2 preoperatively to 108 +/- 12 gm/m2 after operation in Group I (p less than 0.01), from 43 +/- 3 to 93 +/- 8 gm/m2 in Group II (p less than 0.02), and from 46 +/- 3 to 55 +/- 14 gm/m2 in Group III (p = no statistically significant difference). The postoperative change in left ventricular end-diastolic volume was from 100% +/- 17% to 133% +/- 23% of normal in Groups I and II (p less than 0.05) and from 123% +/- 29% to 107% +/- 36% of normal in Group III (p = no statistically significant difference). In preparing the left ventricle for anatomical correction, avoidance of severe pulmonary artery banding decreases the incidence of postoperative myocardial dysfunction, a moderate degree of volume overload and pulmonary artery banding provides the most effective stimulus for ventricular growth, and a small to moderate atrial septal defect is advantageous because it ensures the volume preload necessary for the development of the left ventricle.