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Surgery_Schwartz_2602	Surgery_Schwartz	transplant in a pediatric recipient, liver segments 2 and 3 are implanted in standard fashion (the donor’s left hepatic vein to the recipient’s vena cava, the donor’s left hepatic artery to the recipient’s proper or common hepatic artery, the donor’s left portal vein branch to the recipient’s portal vein trunk). The donor’s ileocolic artery and vein are anastomosed to the recipient’s infra-renal aorta and cava. In the recipient, a duodenum-to-donor ileum anastomosis and a distal Bishop-Coop ileostomy are constructed to reestablish bowel continuity. A very short Roux-en-Y loop (10 to 20 cm) is anastomosed to the donor’s bile duct(s). (Reproduced with permission from Gruessner RWG, Benedetti E: Living Donor Organ Transplantation. New York, NY: McGraw-Hill Education; 2008.)Similarly, the recipient operation also varies by the organs transplanted. Generally, the recipient’s infrarenal aorta is used to achieve the arterial inflow to the graft. For an isolated intestine transplant, venous	Surgery_Schwartz. transplant in a pediatric recipient, liver segments 2 and 3 are implanted in standard fashion (the donor’s left hepatic vein to the recipient’s vena cava, the donor’s left hepatic artery to the recipient’s proper or common hepatic artery, the donor’s left portal vein branch to the recipient’s portal vein trunk). The donor’s ileocolic artery and vein are anastomosed to the recipient’s infra-renal aorta and cava. In the recipient, a duodenum-to-donor ileum anastomosis and a distal Bishop-Coop ileostomy are constructed to reestablish bowel continuity. A very short Roux-en-Y loop (10 to 20 cm) is anastomosed to the donor’s bile duct(s). (Reproduced with permission from Gruessner RWG, Benedetti E: Living Donor Organ Transplantation. New York, NY: McGraw-Hill Education; 2008.)Similarly, the recipient operation also varies by the organs transplanted. Generally, the recipient’s infrarenal aorta is used to achieve the arterial inflow to the graft. For an isolated intestine transplant, venous
Surgery_Schwartz_2603	Surgery_Schwartz	operation also varies by the organs transplanted. Generally, the recipient’s infrarenal aorta is used to achieve the arterial inflow to the graft. For an isolated intestine transplant, venous drainage is achieved via systemic or portomesenteric drainage; for a combined liver-intestine trans-plant or a multivisceral transplant, venous drainage is achieved via the hepatic veins. Systemic venous drainage, given its lesser technical difficulty, is preferred over portomesenteric drainage. The diversion of splanchnic flow into the systemic venous cir-culation can cause several metabolic abnormalities, but no hard evidence shows any negative impact clinically on the recipient.After the organs are perfused, the continuity of the recipi-ent’s GI tract is restored, which includes the placement of a gastrostomy or jejunostomy feeding tube and an ileostomy. In the early postoperative period, the ileostomy enables regular endoscopic surveillance and biopsy of the intestinal mucosa. Once the	Surgery_Schwartz. operation also varies by the organs transplanted. Generally, the recipient’s infrarenal aorta is used to achieve the arterial inflow to the graft. For an isolated intestine transplant, venous drainage is achieved via systemic or portomesenteric drainage; for a combined liver-intestine trans-plant or a multivisceral transplant, venous drainage is achieved via the hepatic veins. Systemic venous drainage, given its lesser technical difficulty, is preferred over portomesenteric drainage. The diversion of splanchnic flow into the systemic venous cir-culation can cause several metabolic abnormalities, but no hard evidence shows any negative impact clinically on the recipient.After the organs are perfused, the continuity of the recipi-ent’s GI tract is restored, which includes the placement of a gastrostomy or jejunostomy feeding tube and an ileostomy. In the early postoperative period, the ileostomy enables regular endoscopic surveillance and biopsy of the intestinal mucosa. Once the
Surgery_Schwartz_2604	Surgery_Schwartz	of a gastrostomy or jejunostomy feeding tube and an ileostomy. In the early postoperative period, the ileostomy enables regular endoscopic surveillance and biopsy of the intestinal mucosa. Once the recipient recovers, the ileostomy can be taken down.The last, but often the most difficult, part of the recipi-ent operation is abdominal wall closure. It is especially challenging in intestine transplant recipients because they have usually undergone multiple previous procedures, resulting in many scars, ostomies, feeding tubes, and the loss of abdomi-nal domain. To provide sufficient coverage of the transplanted organs, the use of prosthetic mesh often is necessary.Postoperative CareInitial postoperative care for intestine transplant recipients does not significantly differ from that for other organ transplant recipients. In the intensive care unit, each recipient’s cardio-vascular, pulmonary, and renal function is closely monitored; aggressive resuscitation with fluid, electrolytes, and	Surgery_Schwartz. of a gastrostomy or jejunostomy feeding tube and an ileostomy. In the early postoperative period, the ileostomy enables regular endoscopic surveillance and biopsy of the intestinal mucosa. Once the recipient recovers, the ileostomy can be taken down.The last, but often the most difficult, part of the recipi-ent operation is abdominal wall closure. It is especially challenging in intestine transplant recipients because they have usually undergone multiple previous procedures, resulting in many scars, ostomies, feeding tubes, and the loss of abdomi-nal domain. To provide sufficient coverage of the transplanted organs, the use of prosthetic mesh often is necessary.Postoperative CareInitial postoperative care for intestine transplant recipients does not significantly differ from that for other organ transplant recipients. In the intensive care unit, each recipient’s cardio-vascular, pulmonary, and renal function is closely monitored; aggressive resuscitation with fluid, electrolytes, and
Surgery_Schwartz_2605	Surgery_Schwartz	organ transplant recipients. In the intensive care unit, each recipient’s cardio-vascular, pulmonary, and renal function is closely monitored; aggressive resuscitation with fluid, electrolytes, and blood prod-ucts is performed. Broad-spectrum antibiotics are an integral component of care.Of all solid organ transplants, intestine transplants have the highest rate of rejection. With intestine transplants, no sero-logic marker of rejection is available, so frequent biopsies and histologic evaluation of the intestinal mucosa are of utmost importance. Rejection leads to structural damage of the intes-tinal mucosa. Translocation of endoluminal pathogens into the circulation can cause systemic infections.Thanks to the introduction of new immunosuppressive protocols, the rejection rates and the overall patient and graft survival rates have improved significantly. Variations between the protocols exist, but the general concept is to induce immu-nosuppression with polyclonal T-cell antibody and	Surgery_Schwartz. organ transplant recipients. In the intensive care unit, each recipient’s cardio-vascular, pulmonary, and renal function is closely monitored; aggressive resuscitation with fluid, electrolytes, and blood prod-ucts is performed. Broad-spectrum antibiotics are an integral component of care.Of all solid organ transplants, intestine transplants have the highest rate of rejection. With intestine transplants, no sero-logic marker of rejection is available, so frequent biopsies and histologic evaluation of the intestinal mucosa are of utmost importance. Rejection leads to structural damage of the intes-tinal mucosa. Translocation of endoluminal pathogens into the circulation can cause systemic infections.Thanks to the introduction of new immunosuppressive protocols, the rejection rates and the overall patient and graft survival rates have improved significantly. Variations between the protocols exist, but the general concept is to induce immu-nosuppression with polyclonal T-cell antibody and
Surgery_Schwartz_2606	Surgery_Schwartz	patient and graft survival rates have improved significantly. Variations between the protocols exist, but the general concept is to induce immu-nosuppression with polyclonal T-cell antibody and high doses of a corticosteroid, followed by maintenance doses of cortico-steroids and the calcineurin inhibitor tacrolimus.Immediately, posttransplant, recipients are maintained on TPN. Enteral nutrition is initiated as early as possible, but it is advanced very cautiously. It can take several weeks for the transplanted intestine to achieve structural integrity and func-tionality and for the recipient to tolerate the full strength of tube feeds.Despite all the recent advances, the complication rate posttransplant remains high. The most common complica-tions include intra-abdominal abscesses, enteric leaks, intra-abdominal sepsis, the need for a reoperation, graft thrombosis, life-threatening bleeding, and central line problems. Immuno-suppression-specific complications include rejection, PTLD,	Surgery_Schwartz. patient and graft survival rates have improved significantly. Variations between the protocols exist, but the general concept is to induce immu-nosuppression with polyclonal T-cell antibody and high doses of a corticosteroid, followed by maintenance doses of cortico-steroids and the calcineurin inhibitor tacrolimus.Immediately, posttransplant, recipients are maintained on TPN. Enteral nutrition is initiated as early as possible, but it is advanced very cautiously. It can take several weeks for the transplanted intestine to achieve structural integrity and func-tionality and for the recipient to tolerate the full strength of tube feeds.Despite all the recent advances, the complication rate posttransplant remains high. The most common complica-tions include intra-abdominal abscesses, enteric leaks, intra-abdominal sepsis, the need for a reoperation, graft thrombosis, life-threatening bleeding, and central line problems. Immuno-suppression-specific complications include rejection, PTLD,
Surgery_Schwartz_2607	Surgery_Schwartz	leaks, intra-abdominal sepsis, the need for a reoperation, graft thrombosis, life-threatening bleeding, and central line problems. Immuno-suppression-specific complications include rejection, PTLD, graft-versus-host disease (GVHD), infections, and malignan-cies. Tailoring the recipient’s immunosuppression plays a critical role in preventing these complications: a low level of immunosuppression leads to graft rejection, but too much con-fers a high risk of infectious complications, PTLD, and, less commonly, GVHD—all of which are associated with a signifi-cantly increased risk of graft failure and mortality.The long-term results of intestine transplants have improved significantly, even though they still remain inferior to the results of other abdominal organ transplants.159,160HEART AND LUNG TRANSPLANTATIONHistoryThe first successful heterotopic heart transplant, in an animal model, was performed by Carrel and Guthrie in 1905.161 Subse-quent progress with cardiopulmonary bypass and	Surgery_Schwartz. leaks, intra-abdominal sepsis, the need for a reoperation, graft thrombosis, life-threatening bleeding, and central line problems. Immuno-suppression-specific complications include rejection, PTLD, graft-versus-host disease (GVHD), infections, and malignan-cies. Tailoring the recipient’s immunosuppression plays a critical role in preventing these complications: a low level of immunosuppression leads to graft rejection, but too much con-fers a high risk of infectious complications, PTLD, and, less commonly, GVHD—all of which are associated with a signifi-cantly increased risk of graft failure and mortality.The long-term results of intestine transplants have improved significantly, even though they still remain inferior to the results of other abdominal organ transplants.159,160HEART AND LUNG TRANSPLANTATIONHistoryThe first successful heterotopic heart transplant, in an animal model, was performed by Carrel and Guthrie in 1905.161 Subse-quent progress with cardiopulmonary bypass and
Surgery_Schwartz_2608	Surgery_Schwartz	LUNG TRANSPLANTATIONHistoryThe first successful heterotopic heart transplant, in an animal model, was performed by Carrel and Guthrie in 1905.161 Subse-quent progress with cardiopulmonary bypass and immunologic modulation facilitated the first successful adult human heart transplant, performed by Christiaan Barnard in 1967 in Cape Town, South Africa.162 However, it was Norman Shumway at Stanford who persisted with heart transplants, in the face of disappointing patient outcomes at a number of early centers. Brunicardi_Ch11_p0355-p0396.indd 38801/03/19 6:55 PM 389TRANSPLANTATIONCHAPTER 11Thanks to the diligence of Shumway and colleagues in perfect-ing heart transplant techniques, along with the development, by Caves, of endomyocardial biopsy as a method of allograft rejection surveillance, human heart transplants began to reap-pear in the 1980s as a viable solution to end-stage heart failure. By 1981, the introduction of cyclosporin A finally created the necessary clinical	Surgery_Schwartz. LUNG TRANSPLANTATIONHistoryThe first successful heterotopic heart transplant, in an animal model, was performed by Carrel and Guthrie in 1905.161 Subse-quent progress with cardiopulmonary bypass and immunologic modulation facilitated the first successful adult human heart transplant, performed by Christiaan Barnard in 1967 in Cape Town, South Africa.162 However, it was Norman Shumway at Stanford who persisted with heart transplants, in the face of disappointing patient outcomes at a number of early centers. Brunicardi_Ch11_p0355-p0396.indd 38801/03/19 6:55 PM 389TRANSPLANTATIONCHAPTER 11Thanks to the diligence of Shumway and colleagues in perfect-ing heart transplant techniques, along with the development, by Caves, of endomyocardial biopsy as a method of allograft rejection surveillance, human heart transplants began to reap-pear in the 1980s as a viable solution to end-stage heart failure. By 1981, the introduction of cyclosporin A finally created the necessary clinical
Surgery_Schwartz_2609	Surgery_Schwartz	human heart transplants began to reap-pear in the 1980s as a viable solution to end-stage heart failure. By 1981, the introduction of cyclosporin A finally created the necessary clinical immunologic modulation necessary to make long-term survival of heart recipients a reality.161Lung transplants have a similar history. In the 1950s, Metras in France and Hardin and Kittle in the United States performed canine lung transplants, demonstrating that meticu-lous anastomotic technique could produce normal pulmonary pressures. Hardy performed the first human lung transplant in 1963, although the patient lived only 18 days. The first suc-cessful long-term lung transplant was performed in 1983 in Toronto. These early lung recipients, however, were plagued by infection, rejection, and, most significantly, bronchial anas-tomotic dehiscence. Cooper and colleagues soon determined that the high-dose corticosteroids used for immunosuppression were responsible for the frequent occurrence of	Surgery_Schwartz. human heart transplants began to reap-pear in the 1980s as a viable solution to end-stage heart failure. By 1981, the introduction of cyclosporin A finally created the necessary clinical immunologic modulation necessary to make long-term survival of heart recipients a reality.161Lung transplants have a similar history. In the 1950s, Metras in France and Hardin and Kittle in the United States performed canine lung transplants, demonstrating that meticu-lous anastomotic technique could produce normal pulmonary pressures. Hardy performed the first human lung transplant in 1963, although the patient lived only 18 days. The first suc-cessful long-term lung transplant was performed in 1983 in Toronto. These early lung recipients, however, were plagued by infection, rejection, and, most significantly, bronchial anas-tomotic dehiscence. Cooper and colleagues soon determined that the high-dose corticosteroids used for immunosuppression were responsible for the frequent occurrence of
Surgery_Schwartz_2610	Surgery_Schwartz	significantly, bronchial anas-tomotic dehiscence. Cooper and colleagues soon determined that the high-dose corticosteroids used for immunosuppression were responsible for the frequent occurrence of dehiscence. The combination of high-dose corticosteroids and ischemic donor bronchi was deadly to lung recipients. Cooper, Morgan, and colleagues showed that the bronchial anastomosis could be pro-tected by wrapping it with a vascular omental pedicle, which not only provided neovascularity but also offered a buttress against any partial dehiscence.163Once cyclosporine became available for lung recipients, corticosteroid doses could be quickly tapered and stopped; cyclosporine poses no danger to the integrity of the bronchial anastomosis. In fact, the introduction of cyclosporine allowed the success of the first combined heart-lung transplant at Stanford in 1981 (after unsuccessful attempts by Cooley in 1969, Lillehei in 1970, and Barnard in 1981, all of whom used only high-dose	Surgery_Schwartz. significantly, bronchial anas-tomotic dehiscence. Cooper and colleagues soon determined that the high-dose corticosteroids used for immunosuppression were responsible for the frequent occurrence of dehiscence. The combination of high-dose corticosteroids and ischemic donor bronchi was deadly to lung recipients. Cooper, Morgan, and colleagues showed that the bronchial anastomosis could be pro-tected by wrapping it with a vascular omental pedicle, which not only provided neovascularity but also offered a buttress against any partial dehiscence.163Once cyclosporine became available for lung recipients, corticosteroid doses could be quickly tapered and stopped; cyclosporine poses no danger to the integrity of the bronchial anastomosis. In fact, the introduction of cyclosporine allowed the success of the first combined heart-lung transplant at Stanford in 1981 (after unsuccessful attempts by Cooley in 1969, Lillehei in 1970, and Barnard in 1981, all of whom used only high-dose
Surgery_Schwartz_2611	Surgery_Schwartz	the success of the first combined heart-lung transplant at Stanford in 1981 (after unsuccessful attempts by Cooley in 1969, Lillehei in 1970, and Barnard in 1981, all of whom used only high-dose corticosteroids for immunosuppression). The 1980s marked the start of the modern age of thoracic transplants.Heart TransplantsIndications. The most common diagnosis leading to a heart transplant is ischemic dilated cardiomyopathy, which stems from coronary artery disease, followed by idiopathic dilated myopathy and congenital heart disease. About 3000 patients are added to the waiting list each year.Evaluation. Pretransplant, both candidates and potential donors are evaluated to ensure their suitability for the procedure. Transplant candidates undergo echocardiography, right and left heart catheterization, evaluation for any undiagnosed malignan-cies, laboratory testing to assess the function of other organs (such as the liver, kidneys, and endocrine system), a dental examination, psychosocial	Surgery_Schwartz. the success of the first combined heart-lung transplant at Stanford in 1981 (after unsuccessful attempts by Cooley in 1969, Lillehei in 1970, and Barnard in 1981, all of whom used only high-dose corticosteroids for immunosuppression). The 1980s marked the start of the modern age of thoracic transplants.Heart TransplantsIndications. The most common diagnosis leading to a heart transplant is ischemic dilated cardiomyopathy, which stems from coronary artery disease, followed by idiopathic dilated myopathy and congenital heart disease. About 3000 patients are added to the waiting list each year.Evaluation. Pretransplant, both candidates and potential donors are evaluated to ensure their suitability for the procedure. Transplant candidates undergo echocardiography, right and left heart catheterization, evaluation for any undiagnosed malignan-cies, laboratory testing to assess the function of other organs (such as the liver, kidneys, and endocrine system), a dental examination, psychosocial
Surgery_Schwartz_2612	Surgery_Schwartz	evaluation for any undiagnosed malignan-cies, laboratory testing to assess the function of other organs (such as the liver, kidneys, and endocrine system), a dental examination, psychosocial evaluation, and appropriate screen-ing (such as mammography, colonoscopy, and prostate-specific antigen testing). Once the evaluation is complete, the selec-tion committee determines, at a multidisciplinary conference, whether or not a heart transplant is needed and is likely to be successful. Transplant candidates who meet all of the center’s criteria are added to the waiting list, according to the UNOS criteria, which are based on health status.Once a potential deceased donor is identified, the surgeon reviews the status report and screening examination results. The donor is initially matched to the recipient per the recipient’s status on the UNOS waiting list, the size match, and the blood type. Results of the donor’s serologic testing, echocardiography, chest X-ray, hemodynamic testing, and	Surgery_Schwartz. evaluation for any undiagnosed malignan-cies, laboratory testing to assess the function of other organs (such as the liver, kidneys, and endocrine system), a dental examination, psychosocial evaluation, and appropriate screen-ing (such as mammography, colonoscopy, and prostate-specific antigen testing). Once the evaluation is complete, the selec-tion committee determines, at a multidisciplinary conference, whether or not a heart transplant is needed and is likely to be successful. Transplant candidates who meet all of the center’s criteria are added to the waiting list, according to the UNOS criteria, which are based on health status.Once a potential deceased donor is identified, the surgeon reviews the status report and screening examination results. The donor is initially matched to the recipient per the recipient’s status on the UNOS waiting list, the size match, and the blood type. Results of the donor’s serologic testing, echocardiography, chest X-ray, hemodynamic testing, and
Surgery_Schwartz_2613	Surgery_Schwartz	recipient per the recipient’s status on the UNOS waiting list, the size match, and the blood type. Results of the donor’s serologic testing, echocardiography, chest X-ray, hemodynamic testing, and possibly coronary artery evaluation are assessed, in order to determine whether or not the donor’s heart can withstand up to 4 hours of cold ischemic time during procurement, transport, and surgery.Procedure. Heart transplants are most often performed ortho-topically (Fig. 11-25). The recipient’s native heart is removed, leaving the superior vena cava, the IVC, the left atrial cuff, the aorta, and the pulmonary artery in situ, in order to allow for anastomosis of the donor’s heart. Usually the left atrial cuff is anastomosed first, providing left heart inflow. Right heart inflow is achieved using a bicaval technique, by directly sew-ing the donor’s superior vena cava and IVC to the recipient’s venae cavae or by creating an anastomosis of the right atrium to a right atrial cuff. The donor’s	Surgery_Schwartz. recipient per the recipient’s status on the UNOS waiting list, the size match, and the blood type. Results of the donor’s serologic testing, echocardiography, chest X-ray, hemodynamic testing, and possibly coronary artery evaluation are assessed, in order to determine whether or not the donor’s heart can withstand up to 4 hours of cold ischemic time during procurement, transport, and surgery.Procedure. Heart transplants are most often performed ortho-topically (Fig. 11-25). The recipient’s native heart is removed, leaving the superior vena cava, the IVC, the left atrial cuff, the aorta, and the pulmonary artery in situ, in order to allow for anastomosis of the donor’s heart. Usually the left atrial cuff is anastomosed first, providing left heart inflow. Right heart inflow is achieved using a bicaval technique, by directly sew-ing the donor’s superior vena cava and IVC to the recipient’s venae cavae or by creating an anastomosis of the right atrium to a right atrial cuff. The donor’s
Surgery_Schwartz_2614	Surgery_Schwartz	a bicaval technique, by directly sew-ing the donor’s superior vena cava and IVC to the recipient’s venae cavae or by creating an anastomosis of the right atrium to a right atrial cuff. The donor’s main pulmonary artery is con-nected to the recipient’s pulmonary artery, and finally, the aortic anastomosis is completed (Fig. 11-26).Once the cross-clamp is removed, the heart is allowed to receive circulation from the recipient and begins to function normally. Inotropic support with isoproterenol, dobutamine, or epinephrine is often required for 3 to 5 days, in order to support recovery from the cold ischemia.164On rare occasions, a heterotopic or “piggyback” heart can be transplanted, leaving the native heart in place. But this sce-nario is becoming very uncommon with the increasing use of mechanical circulatory support for single-ventricle failure.Posttransplant Care. Patient survival rates for heart recipients differ slightly after primary transplants vs. retransplants. In 2016, 3209	Surgery_Schwartz. a bicaval technique, by directly sew-ing the donor’s superior vena cava and IVC to the recipient’s venae cavae or by creating an anastomosis of the right atrium to a right atrial cuff. The donor’s main pulmonary artery is con-nected to the recipient’s pulmonary artery, and finally, the aortic anastomosis is completed (Fig. 11-26).Once the cross-clamp is removed, the heart is allowed to receive circulation from the recipient and begins to function normally. Inotropic support with isoproterenol, dobutamine, or epinephrine is often required for 3 to 5 days, in order to support recovery from the cold ischemia.164On rare occasions, a heterotopic or “piggyback” heart can be transplanted, leaving the native heart in place. But this sce-nario is becoming very uncommon with the increasing use of mechanical circulatory support for single-ventricle failure.Posttransplant Care. Patient survival rates for heart recipients differ slightly after primary transplants vs. retransplants. In 2016, 3209
Surgery_Schwartz_2615	Surgery_Schwartz	mechanical circulatory support for single-ventricle failure.Posttransplant Care. Patient survival rates for heart recipients differ slightly after primary transplants vs. retransplants. In 2016, 3209 heart transplants were performed in the United States. New, active listings increased 57% since 2005. Overall 1-year survival for patients who underwent heart transplant in 2009 to 2011 was 90.1%, 3-year survival was 83.5%, and 5-year Figure 11-25. A donor’s heart brought forward for anastomosis.Brunicardi_Ch11_p0355-p0396.indd 38901/03/19 6:55 PM 390BASIC CONSIDERATIONSPART IFigure 11-26. Suture lines for bicaval anastomosis (a), biatrial anastomosis (b), aortic anastomosis (c), and pulmonary artery anas-tomosis (d).aacbdsurvival was 78.3%, and the most common cause of death within the first year after transplant was infection.165 An increasing number of heart recipients have now survived more than 15 to 20 years with their first graft, especially those with no significant history of	Surgery_Schwartz. mechanical circulatory support for single-ventricle failure.Posttransplant Care. Patient survival rates for heart recipients differ slightly after primary transplants vs. retransplants. In 2016, 3209 heart transplants were performed in the United States. New, active listings increased 57% since 2005. Overall 1-year survival for patients who underwent heart transplant in 2009 to 2011 was 90.1%, 3-year survival was 83.5%, and 5-year Figure 11-25. A donor’s heart brought forward for anastomosis.Brunicardi_Ch11_p0355-p0396.indd 38901/03/19 6:55 PM 390BASIC CONSIDERATIONSPART IFigure 11-26. Suture lines for bicaval anastomosis (a), biatrial anastomosis (b), aortic anastomosis (c), and pulmonary artery anas-tomosis (d).aacbdsurvival was 78.3%, and the most common cause of death within the first year after transplant was infection.165 An increasing number of heart recipients have now survived more than 15 to 20 years with their first graft, especially those with no significant history of
Surgery_Schwartz_2616	Surgery_Schwartz	year after transplant was infection.165 An increasing number of heart recipients have now survived more than 15 to 20 years with their first graft, especially those with no significant history of either cellular or antibody-mediated rejection.Heart recipients must be monitored for both early and late complications. Early complications include primary graft dys-function, acute cellular or antibody-mediated rejection, right heart failure secondary to pulmonary hypertension, and infec-tion. Hemodynamic values are monitored to assess early graft function; pharmacologic and sometimes mechanical support is instituted if needed.The goal of immunosuppression is to prevent rejection, which is assessed by immunosuppressive levels and, early on, by endomyocardial biopsy. Both T-cell–mediated (cellular) and B-cell–mediated (antibody-mediated) rejection are moni-tored. Most of the immunosuppression used is aimed at T cells; however, if the recipient has many preformed antibodies or develops	Surgery_Schwartz. year after transplant was infection.165 An increasing number of heart recipients have now survived more than 15 to 20 years with their first graft, especially those with no significant history of either cellular or antibody-mediated rejection.Heart recipients must be monitored for both early and late complications. Early complications include primary graft dys-function, acute cellular or antibody-mediated rejection, right heart failure secondary to pulmonary hypertension, and infec-tion. Hemodynamic values are monitored to assess early graft function; pharmacologic and sometimes mechanical support is instituted if needed.The goal of immunosuppression is to prevent rejection, which is assessed by immunosuppressive levels and, early on, by endomyocardial biopsy. Both T-cell–mediated (cellular) and B-cell–mediated (antibody-mediated) rejection are moni-tored. Most of the immunosuppression used is aimed at T cells; however, if the recipient has many preformed antibodies or develops
Surgery_Schwartz_2617	Surgery_Schwartz	and B-cell–mediated (antibody-mediated) rejection are moni-tored. Most of the immunosuppression used is aimed at T cells; however, if the recipient has many preformed antibodies or develops donor-specific antibodies, other strategies (such as plasmapheresis or rituximab) are used to reduce the antibody load. Immunosuppressive regimens can vary by center, but most often consist of three categories of medications: a calcineurin inhibitor (usually tacrolimus or cyclosporine), an antiprolifera-tive agent (MMF or AZA), and a corticosteroid (prednisone). Other immunosuppressive agents can be used, depending on the needs of individual recipients.Recipients are also assessed for any infections, with visual inspection of wound healing and with monitoring of the com-plete blood count and cultures as needed. Other common early sequelae include drug-induced nephrotoxicity, glucose intoler-ance, hypertension, hyperlipidemia, osteoporosis, malignancies, and biliary disease.Late complications	Surgery_Schwartz. and B-cell–mediated (antibody-mediated) rejection are moni-tored. Most of the immunosuppression used is aimed at T cells; however, if the recipient has many preformed antibodies or develops donor-specific antibodies, other strategies (such as plasmapheresis or rituximab) are used to reduce the antibody load. Immunosuppressive regimens can vary by center, but most often consist of three categories of medications: a calcineurin inhibitor (usually tacrolimus or cyclosporine), an antiprolifera-tive agent (MMF or AZA), and a corticosteroid (prednisone). Other immunosuppressive agents can be used, depending on the needs of individual recipients.Recipients are also assessed for any infections, with visual inspection of wound healing and with monitoring of the com-plete blood count and cultures as needed. Other common early sequelae include drug-induced nephrotoxicity, glucose intoler-ance, hypertension, hyperlipidemia, osteoporosis, malignancies, and biliary disease.Late complications
Surgery_Schwartz_2618	Surgery_Schwartz	as needed. Other common early sequelae include drug-induced nephrotoxicity, glucose intoler-ance, hypertension, hyperlipidemia, osteoporosis, malignancies, and biliary disease.Late complications include acquired transplant vasculopa-thy, progressive renal failure, and, most commonly, malignan-cies, especially skin cancer and PTLD. Accelerated coronary artery disease is the third most common cause of death posttrans-plant (after infections and acute rejection) and the most common cause after the first year. Coronary artery disease can begin to develop as early as 1 year posttransplant. Its pathogenesis is unknown, but it is believed to be immunologic. Because of these late complications, most transplant centers continue to perform screening tests and recipient examinations at least annually after the first year.Lung TransplantsIndications. The indications for a lung transplant include congenital disease, emphysema, COPD, cystic fibrosis, idio-pathic pulmonary fibrosis, primary	Surgery_Schwartz. as needed. Other common early sequelae include drug-induced nephrotoxicity, glucose intoler-ance, hypertension, hyperlipidemia, osteoporosis, malignancies, and biliary disease.Late complications include acquired transplant vasculopa-thy, progressive renal failure, and, most commonly, malignan-cies, especially skin cancer and PTLD. Accelerated coronary artery disease is the third most common cause of death posttrans-plant (after infections and acute rejection) and the most common cause after the first year. Coronary artery disease can begin to develop as early as 1 year posttransplant. Its pathogenesis is unknown, but it is believed to be immunologic. Because of these late complications, most transplant centers continue to perform screening tests and recipient examinations at least annually after the first year.Lung TransplantsIndications. The indications for a lung transplant include congenital disease, emphysema, COPD, cystic fibrosis, idio-pathic pulmonary fibrosis, primary
Surgery_Schwartz_2619	Surgery_Schwartz	annually after the first year.Lung TransplantsIndications. The indications for a lung transplant include congenital disease, emphysema, COPD, cystic fibrosis, idio-pathic pulmonary fibrosis, primary pulmonary hypertension, α1-antitrypsin deficiency, and the need for a retransplant after primary graft failure. Each year in the United States, about 1600 patients are added to the waiting list; nearly a third of them have COPD and/or emphysema. The next most common diagnosis among patients on the waiting list is cystic fibrosis. A lung allo-cation score (LAS) was instituted in 2005. The average lung transplant candidate requires oxygen (often 4 L/min or more at rest) and has an extensively compromised quality of life, as documented by the results of pulmonary function and 6-minute walk tests.Evaluation. Evaluation for a lung transplant is very similar to evaluation for a heart transplant, except that lung transplant candidates undergo more extensive pulmonary function testing, a 6-minute	Surgery_Schwartz. annually after the first year.Lung TransplantsIndications. The indications for a lung transplant include congenital disease, emphysema, COPD, cystic fibrosis, idio-pathic pulmonary fibrosis, primary pulmonary hypertension, α1-antitrypsin deficiency, and the need for a retransplant after primary graft failure. Each year in the United States, about 1600 patients are added to the waiting list; nearly a third of them have COPD and/or emphysema. The next most common diagnosis among patients on the waiting list is cystic fibrosis. A lung allo-cation score (LAS) was instituted in 2005. The average lung transplant candidate requires oxygen (often 4 L/min or more at rest) and has an extensively compromised quality of life, as documented by the results of pulmonary function and 6-minute walk tests.Evaluation. Evaluation for a lung transplant is very similar to evaluation for a heart transplant, except that lung transplant candidates undergo more extensive pulmonary function testing, a 6-minute
Surgery_Schwartz_2620	Surgery_Schwartz	for a lung transplant is very similar to evaluation for a heart transplant, except that lung transplant candidates undergo more extensive pulmonary function testing, a 6-minute walk test, chest computed tomography, ventilation-perfusion (V-Q) scanning, and arterial blood gas assessment. In addition, all lung transplant candidates must have adequate cardiac function and must meet psychosocial requirements.Potential lung donors are also screened for blood type and size match. Larger lungs are accepted for COPD patients; smaller lungs are chosen for the restricted chest cavity of fibrotic patients. Donors should have a partial pressure of oxygen in arterial blood (Pao2) value >300 mmHg on a fraction of inspired oxygen (Fio2) of 100% and a positive end-expiratory pressure (PEEP) value of 5. Ideally, donors will have normal chest X-ray results, but exceptions for isolated abnormalities that will not affect subsequent graft function can be made. Living donors can donate a single lobe to a	Surgery_Schwartz. for a lung transplant is very similar to evaluation for a heart transplant, except that lung transplant candidates undergo more extensive pulmonary function testing, a 6-minute walk test, chest computed tomography, ventilation-perfusion (V-Q) scanning, and arterial blood gas assessment. In addition, all lung transplant candidates must have adequate cardiac function and must meet psychosocial requirements.Potential lung donors are also screened for blood type and size match. Larger lungs are accepted for COPD patients; smaller lungs are chosen for the restricted chest cavity of fibrotic patients. Donors should have a partial pressure of oxygen in arterial blood (Pao2) value >300 mmHg on a fraction of inspired oxygen (Fio2) of 100% and a positive end-expiratory pressure (PEEP) value of 5. Ideally, donors will have normal chest X-ray results, but exceptions for isolated abnormalities that will not affect subsequent graft function can be made. Living donors can donate a single lobe to a
Surgery_Schwartz_2621	Surgery_Schwartz	Ideally, donors will have normal chest X-ray results, but exceptions for isolated abnormalities that will not affect subsequent graft function can be made. Living donors can donate a single lobe to a smaller recipient, such as a child. Single-lung transplants are common in many centers and can serve to increase the availability of lungs for multiple recipients. Newer concepts, such as “lung in the box” extracorporeal lung perfusion and stem cell technologies, may further improve the availability of donor lungs by optimizing the use of otherwise marginal grafts.Procedure. Lung transplants can be done either as (a) single-lung transplants (to either side via thoracotomy) or as (b) sequential bilateral-lung transplants (via bilateral thoracotomies or via a single clamshell incision that divides the sternum; Fig. 11-27). They can be done absent extracorporeal mechanical cardiopul-monary perfusion (bypass), with the lung with the worst func-tion (as predicted by preoperative ventilation	Surgery_Schwartz. Ideally, donors will have normal chest X-ray results, but exceptions for isolated abnormalities that will not affect subsequent graft function can be made. Living donors can donate a single lobe to a smaller recipient, such as a child. Single-lung transplants are common in many centers and can serve to increase the availability of lungs for multiple recipients. Newer concepts, such as “lung in the box” extracorporeal lung perfusion and stem cell technologies, may further improve the availability of donor lungs by optimizing the use of otherwise marginal grafts.Procedure. Lung transplants can be done either as (a) single-lung transplants (to either side via thoracotomy) or as (b) sequential bilateral-lung transplants (via bilateral thoracotomies or via a single clamshell incision that divides the sternum; Fig. 11-27). They can be done absent extracorporeal mechanical cardiopul-monary perfusion (bypass), with the lung with the worst func-tion (as predicted by preoperative ventilation
Surgery_Schwartz_2622	Surgery_Schwartz	the sternum; Fig. 11-27). They can be done absent extracorporeal mechanical cardiopul-monary perfusion (bypass), with the lung with the worst func-tion (as predicted by preoperative ventilation and perfusion scanning) transplanted first. Despite careful surgical technique and excellent anesthesia, the poor pulmonary reserve of some lung recipients may require the institution of cardiopulmonary bypass to complete the transplant. Bypass is initiated through the chest by direct cardiac cannulation or peripherally via the femoral vessels.Once the thoracotomy is made, a recipient pneumonec-tomy is performed with care, in order to avoid injury to the phrenic or recurrent laryngeal nerves. The pulmonary veins and main pulmonary artery are encircled outside the peri-cardium. At this point, once the main pulmonary vessels are occluded, the need for cardiopulmonary bypass can be assessed. Brunicardi_Ch11_p0355-p0396.indd 39001/03/19 6:55 PM 391TRANSPLANTATIONCHAPTER 11Figure	Surgery_Schwartz. the sternum; Fig. 11-27). They can be done absent extracorporeal mechanical cardiopul-monary perfusion (bypass), with the lung with the worst func-tion (as predicted by preoperative ventilation and perfusion scanning) transplanted first. Despite careful surgical technique and excellent anesthesia, the poor pulmonary reserve of some lung recipients may require the institution of cardiopulmonary bypass to complete the transplant. Bypass is initiated through the chest by direct cardiac cannulation or peripherally via the femoral vessels.Once the thoracotomy is made, a recipient pneumonec-tomy is performed with care, in order to avoid injury to the phrenic or recurrent laryngeal nerves. The pulmonary veins and main pulmonary artery are encircled outside the peri-cardium. At this point, once the main pulmonary vessels are occluded, the need for cardiopulmonary bypass can be assessed. Brunicardi_Ch11_p0355-p0396.indd 39001/03/19 6:55 PM 391TRANSPLANTATIONCHAPTER 11Figure
Surgery_Schwartz_2623	Surgery_Schwartz	point, once the main pulmonary vessels are occluded, the need for cardiopulmonary bypass can be assessed. Brunicardi_Ch11_p0355-p0396.indd 39001/03/19 6:55 PM 391TRANSPLANTATIONCHAPTER 11Figure 11-27. Clamshell incision. Bronchial anastomosis with ligated pulmonary arteries and veins.Figure 11-28. Bronchial anastomosis.The vessels and bronchus are ligated; the donor’s lung is pre-pared and brought to the table wrapped in cold iced gauze, in order to extend the cold preservation time. The bronchial anas-tomosis (Fig. 11-28) is performed first and then covered with peribronchial tissue or pericardium. The pulmonary artery and, finally, the vein are anastomosed. The lung is then de-aired before the final anastomotic suture is tightened, with gentle lung insufflation. All clamps are removed, and the lung is aerated. At least two chest tubes are left in place. After the transplant is complete, a bronchoscopy is performed to clear the airway of blood and secretions.Posttransplant	Surgery_Schwartz. point, once the main pulmonary vessels are occluded, the need for cardiopulmonary bypass can be assessed. Brunicardi_Ch11_p0355-p0396.indd 39001/03/19 6:55 PM 391TRANSPLANTATIONCHAPTER 11Figure 11-27. Clamshell incision. Bronchial anastomosis with ligated pulmonary arteries and veins.Figure 11-28. Bronchial anastomosis.The vessels and bronchus are ligated; the donor’s lung is pre-pared and brought to the table wrapped in cold iced gauze, in order to extend the cold preservation time. The bronchial anas-tomosis (Fig. 11-28) is performed first and then covered with peribronchial tissue or pericardium. The pulmonary artery and, finally, the vein are anastomosed. The lung is then de-aired before the final anastomotic suture is tightened, with gentle lung insufflation. All clamps are removed, and the lung is aerated. At least two chest tubes are left in place. After the transplant is complete, a bronchoscopy is performed to clear the airway of blood and secretions.Posttransplant
Surgery_Schwartz_2624	Surgery_Schwartz	removed, and the lung is aerated. At least two chest tubes are left in place. After the transplant is complete, a bronchoscopy is performed to clear the airway of blood and secretions.Posttransplant Care. Patient survival rates for lung recipients vary significantly after primary vs. redo transplants. After pri-mary transplants, the patient survival rates at 1, 3, and 5 years are 83%, 62%, and 46%, respectively; after retransplants, the rates are 64%, 38%, and 28%.Postoperative care of lung recipients can be very labor-intensive. These patients require meticulous ventilator manage-ment, in order to maintain Fio2 at a minimum and to keep Pao2 at 70 mmHg. Most patients are extubated within the first 24 to 48 hours. Recipients can require multiple bronchoscopies for both airway management and surveillance biopsies. Diuretics are used generously to counteract any positive fluid balance from the operation and to help with pulmonary recovery.Early complications include technical	Surgery_Schwartz. removed, and the lung is aerated. At least two chest tubes are left in place. After the transplant is complete, a bronchoscopy is performed to clear the airway of blood and secretions.Posttransplant Care. Patient survival rates for lung recipients vary significantly after primary vs. redo transplants. After pri-mary transplants, the patient survival rates at 1, 3, and 5 years are 83%, 62%, and 46%, respectively; after retransplants, the rates are 64%, 38%, and 28%.Postoperative care of lung recipients can be very labor-intensive. These patients require meticulous ventilator manage-ment, in order to maintain Fio2 at a minimum and to keep Pao2 at 70 mmHg. Most patients are extubated within the first 24 to 48 hours. Recipients can require multiple bronchoscopies for both airway management and surveillance biopsies. Diuretics are used generously to counteract any positive fluid balance from the operation and to help with pulmonary recovery.Early complications include technical
Surgery_Schwartz_2625	Surgery_Schwartz	and surveillance biopsies. Diuretics are used generously to counteract any positive fluid balance from the operation and to help with pulmonary recovery.Early complications include technical complications, graft dysfunction, infections, and rejection. Technical complications often involve stenosis of one or more anastomoses leading to graft dysfunction. Bronchoscopy, V-Q scanning, echocardiogra-phy, and radiologic imaging are useful in identifying the causes of graft dysfunction. In up to 20% of recipients, primary early graft dysfunction can occur with no obvious cause. Such dys-function may be due to some pathology from the donor, perhaps an unknown aspiration, infection, or contusion; or it could result from poor graft preservation at the time of organ procurement. In the intensive care unit, aggressive ventilator and pharmaco-logic management can help, but recipients can nonetheless prog-ress to the need for mechanical support in the form of ECMO. Infections are treated with	Surgery_Schwartz. and surveillance biopsies. Diuretics are used generously to counteract any positive fluid balance from the operation and to help with pulmonary recovery.Early complications include technical complications, graft dysfunction, infections, and rejection. Technical complications often involve stenosis of one or more anastomoses leading to graft dysfunction. Bronchoscopy, V-Q scanning, echocardiogra-phy, and radiologic imaging are useful in identifying the causes of graft dysfunction. In up to 20% of recipients, primary early graft dysfunction can occur with no obvious cause. Such dys-function may be due to some pathology from the donor, perhaps an unknown aspiration, infection, or contusion; or it could result from poor graft preservation at the time of organ procurement. In the intensive care unit, aggressive ventilator and pharmaco-logic management can help, but recipients can nonetheless prog-ress to the need for mechanical support in the form of ECMO. Infections are treated with
Surgery_Schwartz_2626	Surgery_Schwartz	care unit, aggressive ventilator and pharmaco-logic management can help, but recipients can nonetheless prog-ress to the need for mechanical support in the form of ECMO. Infections are treated with appropriate antibiotics, which can be challenging in patients with cystic fibrosis and a history of multidrug-resistant organisms. Rejection is monitored by biop-sies and treated as needed.Late complications include airway complications, such as strictures and, rarely, dehiscence, bronchiolitis obliterans, and malignancies. Strictures are treated with bronchoscopic dilation and intervention. Bronchiolitis obliterans often is a sequela of chronic rejection, but can be due to aspiration, chronic infec-tions, or various other causes. In recipients with a progressive fall in their forced expiratory volume in 1 second (FEV1), bron-chiolitis obliterans is suspected. All recipients should be taught to perform microspirometry at home as a screening tool post-transplant. Biopsies are performed to	Surgery_Schwartz. care unit, aggressive ventilator and pharmaco-logic management can help, but recipients can nonetheless prog-ress to the need for mechanical support in the form of ECMO. Infections are treated with appropriate antibiotics, which can be challenging in patients with cystic fibrosis and a history of multidrug-resistant organisms. Rejection is monitored by biop-sies and treated as needed.Late complications include airway complications, such as strictures and, rarely, dehiscence, bronchiolitis obliterans, and malignancies. Strictures are treated with bronchoscopic dilation and intervention. Bronchiolitis obliterans often is a sequela of chronic rejection, but can be due to aspiration, chronic infec-tions, or various other causes. In recipients with a progressive fall in their forced expiratory volume in 1 second (FEV1), bron-chiolitis obliterans is suspected. All recipients should be taught to perform microspirometry at home as a screening tool post-transplant. Biopsies are performed to
Surgery_Schwartz_2627	Surgery_Schwartz	volume in 1 second (FEV1), bron-chiolitis obliterans is suspected. All recipients should be taught to perform microspirometry at home as a screening tool post-transplant. Biopsies are performed to confirm the diagnosis of any complication and, if possible, the cause. Despite aggres-sive screening and treatment, more than 50% of recipients will develop graft dysfunction. Most if not all of the sequelae of chronic immunosuppression that occur in lung transplant recipi-ents are similar to those occurring in other groups of solid organ transplants.Heart-Lung TransplantsEvery year in the United States, 30 to 50 patients are added to the list of patients waiting to receive a simultaneous heart-lung transplant. The most common diagnosis is idiopathic pulmo-nary fibrosis, followed by primary pulmonary hypertension. Heart-lung candidates are often younger than their single-organ counterparts. The patient survival rates at 1, 3, and 5 years are 66%, 48%, and 39%, respectively. Often, lung	Surgery_Schwartz. volume in 1 second (FEV1), bron-chiolitis obliterans is suspected. All recipients should be taught to perform microspirometry at home as a screening tool post-transplant. Biopsies are performed to confirm the diagnosis of any complication and, if possible, the cause. Despite aggres-sive screening and treatment, more than 50% of recipients will develop graft dysfunction. Most if not all of the sequelae of chronic immunosuppression that occur in lung transplant recipi-ents are similar to those occurring in other groups of solid organ transplants.Heart-Lung TransplantsEvery year in the United States, 30 to 50 patients are added to the list of patients waiting to receive a simultaneous heart-lung transplant. The most common diagnosis is idiopathic pulmo-nary fibrosis, followed by primary pulmonary hypertension. Heart-lung candidates are often younger than their single-organ counterparts. The patient survival rates at 1, 3, and 5 years are 66%, 48%, and 39%, respectively. Often, lung
Surgery_Schwartz_2628	Surgery_Schwartz	pulmonary hypertension. Heart-lung candidates are often younger than their single-organ counterparts. The patient survival rates at 1, 3, and 5 years are 66%, 48%, and 39%, respectively. Often, lung complications ultimately lead to graft failure. The immunosuppression is the same as that for single thoracic organ recipients, with emphasis on weaning the patient off corticosteroids as early as possible.XENOTRANSPLANTSXenotransplants (i.e., cross-species transplants of organs, tis-sues, or cells) have immense, yet untapped, potential to solve the critical shortage of available grafts. A primary hurdle is the formidable immunologic barrier between species, especially Brunicardi_Ch11_p0355-p0396.indd 39101/03/19 6:55 PM 392BASIC CONSIDERATIONSPART Iwith vascularized whole organs.161-170 Other problems include the potential risk of transmitting infections (known as zoono-ses or xenoses) and the ethical problems of using animals for widespread human transplants, even though great	Surgery_Schwartz. pulmonary hypertension. Heart-lung candidates are often younger than their single-organ counterparts. The patient survival rates at 1, 3, and 5 years are 66%, 48%, and 39%, respectively. Often, lung complications ultimately lead to graft failure. The immunosuppression is the same as that for single thoracic organ recipients, with emphasis on weaning the patient off corticosteroids as early as possible.XENOTRANSPLANTSXenotransplants (i.e., cross-species transplants of organs, tis-sues, or cells) have immense, yet untapped, potential to solve the critical shortage of available grafts. A primary hurdle is the formidable immunologic barrier between species, especially Brunicardi_Ch11_p0355-p0396.indd 39101/03/19 6:55 PM 392BASIC CONSIDERATIONSPART Iwith vascularized whole organs.161-170 Other problems include the potential risk of transmitting infections (known as zoono-ses or xenoses) and the ethical problems of using animals for widespread human transplants, even though great
Surgery_Schwartz_2629	Surgery_Schwartz	Other problems include the potential risk of transmitting infections (known as zoono-ses or xenoses) and the ethical problems of using animals for widespread human transplants, even though great progress has been made in the past few years in efforts to overcome these problems.166-172Pigs are generally accepted as the most likely donor spe-cies for xenotransplants into human beings.173 Pigs would also be easier to raise on a large-scale basis. Guidelines for raising pigs in specialized facilities designated as pathogen-free have been established; in anticipation of clinical trials, such facilities have already been created and populated.171,172The immunologic barrier in pig-to-human xenotrans-plants is highly complex, but generally involves four subtypes of rejection.166 The first is hyperacute rejection (HAR), which is mediated by the presence of natural (preformed) xenoantibod-ies in humans. These antibodies bind to antigens found mainly on the vascular endothelial cells of porcine	Surgery_Schwartz. Other problems include the potential risk of transmitting infections (known as zoono-ses or xenoses) and the ethical problems of using animals for widespread human transplants, even though great progress has been made in the past few years in efforts to overcome these problems.166-172Pigs are generally accepted as the most likely donor spe-cies for xenotransplants into human beings.173 Pigs would also be easier to raise on a large-scale basis. Guidelines for raising pigs in specialized facilities designated as pathogen-free have been established; in anticipation of clinical trials, such facilities have already been created and populated.171,172The immunologic barrier in pig-to-human xenotrans-plants is highly complex, but generally involves four subtypes of rejection.166 The first is hyperacute rejection (HAR), which is mediated by the presence of natural (preformed) xenoantibod-ies in humans. These antibodies bind to antigens found mainly on the vascular endothelial cells of porcine
Surgery_Schwartz_2630	Surgery_Schwartz	rejection (HAR), which is mediated by the presence of natural (preformed) xenoantibod-ies in humans. These antibodies bind to antigens found mainly on the vascular endothelial cells of porcine donor organs, lead-ing to complement activation, intravascular coagulation, and rapid graft ischemia soon after the transplant. The second sub-type is acute humoral xenograft rejection (AHXR), a delayed form of antibody-mediated rejection seen in pig-to-nonhuman-primate transplants after steps to prevent HAR—steps such as depletion of antipig antibodies or complement from nonhu-man primates’ serum. Alternative names for AHXR include acute vascular rejection or delayed xenograft rejection. The third subtype is an acute cellular rejection process (similar to the classic T-cell–mediated acute rejection seen in allograft recipients). The fourth subtype is chronic rejection in grafts that survive for more than a few weeks (similar to the chronic rejection seen in long-surviving allograft recipients,	Surgery_Schwartz. rejection (HAR), which is mediated by the presence of natural (preformed) xenoantibod-ies in humans. These antibodies bind to antigens found mainly on the vascular endothelial cells of porcine donor organs, lead-ing to complement activation, intravascular coagulation, and rapid graft ischemia soon after the transplant. The second sub-type is acute humoral xenograft rejection (AHXR), a delayed form of antibody-mediated rejection seen in pig-to-nonhuman-primate transplants after steps to prevent HAR—steps such as depletion of antipig antibodies or complement from nonhu-man primates’ serum. Alternative names for AHXR include acute vascular rejection or delayed xenograft rejection. The third subtype is an acute cellular rejection process (similar to the classic T-cell–mediated acute rejection seen in allograft recipients). The fourth subtype is chronic rejection in grafts that survive for more than a few weeks (similar to the chronic rejection seen in long-surviving allograft recipients,
Surgery_Schwartz_2631	Surgery_Schwartz	seen in allograft recipients). The fourth subtype is chronic rejection in grafts that survive for more than a few weeks (similar to the chronic rejection seen in long-surviving allograft recipients, with fea-tures of chronic vasculopathy).Many different options are being tested to overcome this immunologic barrier, including the genetic engineering of pigs, the use of agents to inhibit platelet aggregation and complement activation, and the administration of powerful immunosuppres-sive drugs.166-173During the first decade of the 21st century, the field of whole-organ xenotransplantation progressed significantly, thanks to the increasing availability of genetically engineered pigs and new immunosuppressive protocols. At a recent sympo-sium organized by the International Xenotransplantation Asso-ciation, data presented demonstrated extended survival time of porcine solid organs in nonhuman primates: from about 30 days to an average of 60 days and even up to 250 days (depending on the	Surgery_Schwartz. seen in allograft recipients). The fourth subtype is chronic rejection in grafts that survive for more than a few weeks (similar to the chronic rejection seen in long-surviving allograft recipients, with fea-tures of chronic vasculopathy).Many different options are being tested to overcome this immunologic barrier, including the genetic engineering of pigs, the use of agents to inhibit platelet aggregation and complement activation, and the administration of powerful immunosuppres-sive drugs.166-173During the first decade of the 21st century, the field of whole-organ xenotransplantation progressed significantly, thanks to the increasing availability of genetically engineered pigs and new immunosuppressive protocols. At a recent sympo-sium organized by the International Xenotransplantation Asso-ciation, data presented demonstrated extended survival time of porcine solid organs in nonhuman primates: from about 30 days to an average of 60 days and even up to 250 days (depending on the
Surgery_Schwartz_2632	Surgery_Schwartz	Asso-ciation, data presented demonstrated extended survival time of porcine solid organs in nonhuman primates: from about 30 days to an average of 60 days and even up to 250 days (depending on the model).166,169,174,175 However, clinical application is still limited by thrombotic microangiopathy and consumptive coagu-lopathy; novel methods to prevent those complications will be required for further progress.Cellular xenotransplants have made great strides and are currently in the early stages of clinical trials. Porcine islet xenotransplants are the most advanced form; five independent groups have now demonstrated survival and function of porcine islets in nonhuman primates for more than 100 days.166,175-181 For the clinical trials, cost-benefit models have been developed, and the regulatory framework has been established.170-172,178 One trial of particular interest involves transplanting encapsulated porcine islets without immunosuppression.179 Early results are encouraging. But the	Surgery_Schwartz. Asso-ciation, data presented demonstrated extended survival time of porcine solid organs in nonhuman primates: from about 30 days to an average of 60 days and even up to 250 days (depending on the model).166,169,174,175 However, clinical application is still limited by thrombotic microangiopathy and consumptive coagu-lopathy; novel methods to prevent those complications will be required for further progress.Cellular xenotransplants have made great strides and are currently in the early stages of clinical trials. Porcine islet xenotransplants are the most advanced form; five independent groups have now demonstrated survival and function of porcine islets in nonhuman primates for more than 100 days.166,175-181 For the clinical trials, cost-benefit models have been developed, and the regulatory framework has been established.170-172,178 One trial of particular interest involves transplanting encapsulated porcine islets without immunosuppression.179 Early results are encouraging. But the
Surgery_Schwartz_2633	Surgery_Schwartz	framework has been established.170-172,178 One trial of particular interest involves transplanting encapsulated porcine islets without immunosuppression.179 Early results are encouraging. But the efficacy of that approach may be limited until further genetic engineering enables proper oxygenation and nourishment of islet grafts, thereby supporting their viabil-ity and function.The future of xenotransplantation is exciting. Continued active research will focus on further genetic engineering of pigs, newer immunosuppressive drugs, and tissue engineering approaches that will minimize or eliminate the need for immu-nosuppression. Given recent progress, routine clinical applica-tion of cellular xenotransplants is likely within the next decade.REFERENCESEntries highlighted in bright blue are key references. 1. Carrel A. The surgery of blood vessels, etc. B Johns Hopkins Hosp. 1907;18:18-28. 2. Hamilton D, Reid, WA. Yu Yu Voronoy and the first human kidney allograft. Surg Gynecol Obstet.	Surgery_Schwartz. framework has been established.170-172,178 One trial of particular interest involves transplanting encapsulated porcine islets without immunosuppression.179 Early results are encouraging. But the efficacy of that approach may be limited until further genetic engineering enables proper oxygenation and nourishment of islet grafts, thereby supporting their viabil-ity and function.The future of xenotransplantation is exciting. Continued active research will focus on further genetic engineering of pigs, newer immunosuppressive drugs, and tissue engineering approaches that will minimize or eliminate the need for immu-nosuppression. Given recent progress, routine clinical applica-tion of cellular xenotransplants is likely within the next decade.REFERENCESEntries highlighted in bright blue are key references. 1. Carrel A. The surgery of blood vessels, etc. B Johns Hopkins Hosp. 1907;18:18-28. 2. Hamilton D, Reid, WA. Yu Yu Voronoy and the first human kidney allograft. Surg Gynecol Obstet.
Surgery_Schwartz_2634	Surgery_Schwartz	key references. 1. Carrel A. The surgery of blood vessels, etc. B Johns Hopkins Hosp. 1907;18:18-28. 2. Hamilton D, Reid, WA. Yu Yu Voronoy and the first human kidney allograft. Surg Gynecol Obstet. 1984;159(3):289-294. 3. Medawar PB. Immunity to homologous grafted skin; the suppression of cell division in grafts transplanted to immu-nized animals. Br J Exp Pathol. 1946;27:9-14. 4. Merrill JP, Murray J, Harrison JH. Successful homotransplan-tation of the human kidney between identical twins. JAMA. 1956;160(4):277-282. 5. Murray JE, Merrill J, Harrison JH, et al. Prolonged sur-vival of human-kidney homografts by immunosuppressive drug therapy. N Engl J Med. 1963;268:1315-1323. 6. Starzl TE, Waddell WR, Marchioro TL. Reversal of rejection in human renal homografts with subsequent development of homograft tolerance. Surg Gynecol Obstet. 1963;117(4):385. 7. Calne RY, Rolles K, Thiru S, et al. Cyclosporin A initially as the only immunosuppressant in 34 recipients of cadav-eric organs: 32	Surgery_Schwartz. key references. 1. Carrel A. The surgery of blood vessels, etc. B Johns Hopkins Hosp. 1907;18:18-28. 2. Hamilton D, Reid, WA. Yu Yu Voronoy and the first human kidney allograft. Surg Gynecol Obstet. 1984;159(3):289-294. 3. Medawar PB. Immunity to homologous grafted skin; the suppression of cell division in grafts transplanted to immu-nized animals. Br J Exp Pathol. 1946;27:9-14. 4. Merrill JP, Murray J, Harrison JH. Successful homotransplan-tation of the human kidney between identical twins. JAMA. 1956;160(4):277-282. 5. Murray JE, Merrill J, Harrison JH, et al. Prolonged sur-vival of human-kidney homografts by immunosuppressive drug therapy. N Engl J Med. 1963;268:1315-1323. 6. Starzl TE, Waddell WR, Marchioro TL. Reversal of rejection in human renal homografts with subsequent development of homograft tolerance. Surg Gynecol Obstet. 1963;117(4):385. 7. Calne RY, Rolles K, Thiru S, et al. Cyclosporin A initially as the only immunosuppressant in 34 recipients of cadav-eric organs: 32
Surgery_Schwartz_2635	Surgery_Schwartz	of homograft tolerance. Surg Gynecol Obstet. 1963;117(4):385. 7. Calne RY, Rolles K, Thiru S, et al. Cyclosporin A initially as the only immunosuppressant in 34 recipients of cadav-eric organs: 32 kidneys, 2 pancreases, and 2 livers. Lancet. 1979;2(8151):1033-1036. 8. Hall BM, Dorsch S, Roser B. Cellular basis of allograft-rejection in vivo. 1. Cellular requirements for 1st set rejection of heart grafts. J Exp Med. 1978;148(4):878-889. 9. Hall BM, Dorsch S, Roser B. Cellular basis of allograft-rejection in vivo. 2. Nature of memory cells mediating second set heart graft rejection. J Exp Med. 1978;148(4):890-902. 10. Hariharan S, Johnson CP, Bresnahan BA, et al. Improved graft survival after renal transplantation in the United States, 1988 to 1996. N Engl J Med. 2000;342(9):605-612. 11. Cicciarelli J. Cyclosporine and trends in kidney transplanta-tion. Clin Transpl. 1986;6;223-320. 12. Meier-Kriesche HU, Li S, Gruessner RW, et al. Immuno-suppression: evolution in practice and trends,	Surgery_Schwartz. of homograft tolerance. Surg Gynecol Obstet. 1963;117(4):385. 7. Calne RY, Rolles K, Thiru S, et al. Cyclosporin A initially as the only immunosuppressant in 34 recipients of cadav-eric organs: 32 kidneys, 2 pancreases, and 2 livers. Lancet. 1979;2(8151):1033-1036. 8. Hall BM, Dorsch S, Roser B. Cellular basis of allograft-rejection in vivo. 1. Cellular requirements for 1st set rejection of heart grafts. J Exp Med. 1978;148(4):878-889. 9. Hall BM, Dorsch S, Roser B. Cellular basis of allograft-rejection in vivo. 2. Nature of memory cells mediating second set heart graft rejection. J Exp Med. 1978;148(4):890-902. 10. Hariharan S, Johnson CP, Bresnahan BA, et al. Improved graft survival after renal transplantation in the United States, 1988 to 1996. N Engl J Med. 2000;342(9):605-612. 11. Cicciarelli J. Cyclosporine and trends in kidney transplanta-tion. Clin Transpl. 1986;6;223-320. 12. Meier-Kriesche HU, Li S, Gruessner RW, et al. Immuno-suppression: evolution in practice and trends,
Surgery_Schwartz_2636	Surgery_Schwartz	J. Cyclosporine and trends in kidney transplanta-tion. Clin Transpl. 1986;6;223-320. 12. Meier-Kriesche HU, Li S, Gruessner RW, et al. Immuno-suppression: evolution in practice and trends, 1994-2004. Am J Transplant. 2006;6(5 Pt 2):1111-1131. 13. Halloran PF. Immunosuppressive drugs for kidney transplanta-tion. N Engl J Med. 2004;351(26):2715-2729. 14. Zand MS, Vo T, Huggins J, et al. Polyclonal rabbit antithy-mocyte globulin triggers B-cell and plasma cell apoptosis by multiple pathways. Transplantation. 2005;79(11):1507-1515. 15. Brennan DC, Daller JA, Lake KD, Cibrik D, Del Castillo D. Rabbit antithymocyte globulin versus basiliximab in renal transplantation. N Engl J Med. 2006;355(19):1967-1977. 16. Vega O, Cardenas G, Correa-Rotter R, Alberu J, Morales-Buenrostro LE. Basilizimab vs. limited dose daclizumab (2 mg/kg) administered in single or two separated doses in kidney transplantation. Rev Invest Clin. 2008;60(2):82-86. 17. Kirk AD, Hale DA, Mann RB, et al. Results from a	Surgery_Schwartz. J. Cyclosporine and trends in kidney transplanta-tion. Clin Transpl. 1986;6;223-320. 12. Meier-Kriesche HU, Li S, Gruessner RW, et al. Immuno-suppression: evolution in practice and trends, 1994-2004. Am J Transplant. 2006;6(5 Pt 2):1111-1131. 13. Halloran PF. Immunosuppressive drugs for kidney transplanta-tion. N Engl J Med. 2004;351(26):2715-2729. 14. Zand MS, Vo T, Huggins J, et al. Polyclonal rabbit antithy-mocyte globulin triggers B-cell and plasma cell apoptosis by multiple pathways. Transplantation. 2005;79(11):1507-1515. 15. Brennan DC, Daller JA, Lake KD, Cibrik D, Del Castillo D. Rabbit antithymocyte globulin versus basiliximab in renal transplantation. N Engl J Med. 2006;355(19):1967-1977. 16. Vega O, Cardenas G, Correa-Rotter R, Alberu J, Morales-Buenrostro LE. Basilizimab vs. limited dose daclizumab (2 mg/kg) administered in single or two separated doses in kidney transplantation. Rev Invest Clin. 2008;60(2):82-86. 17. Kirk AD, Hale DA, Mann RB, et al. Results from a
Surgery_Schwartz_2637	Surgery_Schwartz	vs. limited dose daclizumab (2 mg/kg) administered in single or two separated doses in kidney transplantation. Rev Invest Clin. 2008;60(2):82-86. 17. Kirk AD, Hale DA, Mann RB, et al. Results from a human renal allograft tolerance trial evaluating the humanized CD52-specific monoclonal antibody alemtuzumab (CAMPAH-1H). Transplantation. 2003;76(1):120-129. 18. Agarwal A, Shen LY, Kirk AD. The role of alemtuzumab in facilitating maintenance immunosuppression minimiza-tion following solid organ transplantation. Transpl Immunol. 2008;20(1-2):6-11. 19. Fryer JP, Granger DK, Leventhal JR, et al. Steroid-related complications in the cyclosporine era. Clin Transplant. 1994; 8:224.Brunicardi_Ch11_p0355-p0396.indd 39201/03/19 6:55 PM 393TRANSPLANTATIONCHAPTER 11 20. Humar A, Crotteau S, Gruessner A, et al. Steroid minimization in liver transplant recipients: impact on hepatitis C recurrence and posttransplant diabetes. Clin Transplant. 2007;21:526. 21. Matas AJ, Kandaswamy R, Gillingham	Surgery_Schwartz. vs. limited dose daclizumab (2 mg/kg) administered in single or two separated doses in kidney transplantation. Rev Invest Clin. 2008;60(2):82-86. 17. Kirk AD, Hale DA, Mann RB, et al. Results from a human renal allograft tolerance trial evaluating the humanized CD52-specific monoclonal antibody alemtuzumab (CAMPAH-1H). Transplantation. 2003;76(1):120-129. 18. Agarwal A, Shen LY, Kirk AD. The role of alemtuzumab in facilitating maintenance immunosuppression minimiza-tion following solid organ transplantation. Transpl Immunol. 2008;20(1-2):6-11. 19. Fryer JP, Granger DK, Leventhal JR, et al. Steroid-related complications in the cyclosporine era. Clin Transplant. 1994; 8:224.Brunicardi_Ch11_p0355-p0396.indd 39201/03/19 6:55 PM 393TRANSPLANTATIONCHAPTER 11 20. Humar A, Crotteau S, Gruessner A, et al. Steroid minimization in liver transplant recipients: impact on hepatitis C recurrence and posttransplant diabetes. Clin Transplant. 2007;21:526. 21. Matas AJ, Kandaswamy R, Gillingham
Surgery_Schwartz_2638	Surgery_Schwartz	A, et al. Steroid minimization in liver transplant recipients: impact on hepatitis C recurrence and posttransplant diabetes. Clin Transplant. 2007;21:526. 21. Matas AJ, Kandaswamy R, Gillingham KJ, et al. Prednisone-free maintenance immunosuppression—a 5-year experience. Am J Transplant. 2005;5:2473. 22. Elion GB. The George Hitchings and Gertrude Elion Lecture. The pharmacology of azathioprine. Ann N Y Acad Sci. 1993; 685:400-407. 23. Remuzzi G, Lesti M, Gotti E, et al. Mycophenolate mofetil versus azathioprine for prevention of acute rejection in renal transplantation (MYSS): a randomized trial. Lancet. 2004;364:503. 24. Bolin P, Tanriover B, Zibari GB, et al. Improvement in 3-month patient-reported gastrointestinal symptoms after con-version from mycophenolate mofetil to enteric-coated myco-phenolate sodium in renal transplant patients. Transplantation. 2007;84(11):1443-1451. 25. Kaplan B, Schold J, Srinivas T, et al. Effect of sirolimus with-drawal in patients with deteriorating	Surgery_Schwartz. A, et al. Steroid minimization in liver transplant recipients: impact on hepatitis C recurrence and posttransplant diabetes. Clin Transplant. 2007;21:526. 21. Matas AJ, Kandaswamy R, Gillingham KJ, et al. Prednisone-free maintenance immunosuppression—a 5-year experience. Am J Transplant. 2005;5:2473. 22. Elion GB. The George Hitchings and Gertrude Elion Lecture. The pharmacology of azathioprine. Ann N Y Acad Sci. 1993; 685:400-407. 23. Remuzzi G, Lesti M, Gotti E, et al. Mycophenolate mofetil versus azathioprine for prevention of acute rejection in renal transplantation (MYSS): a randomized trial. Lancet. 2004;364:503. 24. Bolin P, Tanriover B, Zibari GB, et al. Improvement in 3-month patient-reported gastrointestinal symptoms after con-version from mycophenolate mofetil to enteric-coated myco-phenolate sodium in renal transplant patients. Transplantation. 2007;84(11):1443-1451. 25. Kaplan B, Schold J, Srinivas T, et al. Effect of sirolimus with-drawal in patients with deteriorating
Surgery_Schwartz_2639	Surgery_Schwartz	myco-phenolate sodium in renal transplant patients. Transplantation. 2007;84(11):1443-1451. 25. Kaplan B, Schold J, Srinivas T, et al. Effect of sirolimus with-drawal in patients with deteriorating renal function. Am J Transpl. 2004;4(10):1709-1712. 26. Larson TS, Dean PG, Stegall MD, et al. Complete avoidance of calcineurin inhibitors in renal transplantation: a randomized trial comparing sirolimus and tacrolimus. Am J Transplant. 2006;6:514. 27. Burke JF, Pirsch JD, Ramos EL, et al. Long-term efficacy and safety of cyclosporine in renal transplant recipients. N Engl J Med. 1994;331:358. 28. Calne RY, Rolles K, White DJG, et al. Cyclosporin A initially as the only immunosuppressant in 34 recipients of cadaveric organs. Lancet. 1979;2:1033. 29. Sweny P, Farrington K, Younis F, et al. Sixteen months expe-rience with cyclosporin A in human kidney transplantation. Transplant Proc. 1981;13:365. 30. Mihatsch MJ, Kyo M, Morozumi K, et al. The side-effects of ciclosporine-A and tacrolimus.	Surgery_Schwartz. myco-phenolate sodium in renal transplant patients. Transplantation. 2007;84(11):1443-1451. 25. Kaplan B, Schold J, Srinivas T, et al. Effect of sirolimus with-drawal in patients with deteriorating renal function. Am J Transpl. 2004;4(10):1709-1712. 26. Larson TS, Dean PG, Stegall MD, et al. Complete avoidance of calcineurin inhibitors in renal transplantation: a randomized trial comparing sirolimus and tacrolimus. Am J Transplant. 2006;6:514. 27. Burke JF, Pirsch JD, Ramos EL, et al. Long-term efficacy and safety of cyclosporine in renal transplant recipients. N Engl J Med. 1994;331:358. 28. Calne RY, Rolles K, White DJG, et al. Cyclosporin A initially as the only immunosuppressant in 34 recipients of cadaveric organs. Lancet. 1979;2:1033. 29. Sweny P, Farrington K, Younis F, et al. Sixteen months expe-rience with cyclosporin A in human kidney transplantation. Transplant Proc. 1981;13:365. 30. Mihatsch MJ, Kyo M, Morozumi K, et al. The side-effects of ciclosporine-A and tacrolimus.
Surgery_Schwartz_2640	Surgery_Schwartz	months expe-rience with cyclosporin A in human kidney transplantation. Transplant Proc. 1981;13:365. 30. Mihatsch MJ, Kyo M, Morozumi K, et al. The side-effects of ciclosporine-A and tacrolimus. Clin Nephrol. 1998;49(6):356-363. 31. Larsen CP, Pearson TC, Adams AB, et al. Rational devel-opment of LEA29Y (belatacept), a high-affinity variant of CTLA4-Ig with potent immunosuppressive properties. Am J Transplant. 2005;5:443. 32. Vincenti F, Larsen C, Durrback A, et al. Costimulation block-ade with belatacept in renal transplantation. N Engl J Med. 2005;353;770. 33. Pescovitz MD. Rituximab, an anti-cd20 monoclonal anti-body: history and mechanism of action. Am J Transplant. 2006;6:859. 34. Blume OR, Yost SE, Kaplan B. Antibody-mediated rejection: pathogenesis, prevention, treatment, and outcomes. J Trans-plant. 2012:201754. 35. Becker YT, Becker BN, Pirsch JD, Sollinger HW. Rituximab as treatment for refractory kidney transplant rejection. Am J Transplant. 2004;4:996. 36. Perry DK, Burns	Surgery_Schwartz. months expe-rience with cyclosporin A in human kidney transplantation. Transplant Proc. 1981;13:365. 30. Mihatsch MJ, Kyo M, Morozumi K, et al. The side-effects of ciclosporine-A and tacrolimus. Clin Nephrol. 1998;49(6):356-363. 31. Larsen CP, Pearson TC, Adams AB, et al. Rational devel-opment of LEA29Y (belatacept), a high-affinity variant of CTLA4-Ig with potent immunosuppressive properties. Am J Transplant. 2005;5:443. 32. Vincenti F, Larsen C, Durrback A, et al. Costimulation block-ade with belatacept in renal transplantation. N Engl J Med. 2005;353;770. 33. Pescovitz MD. Rituximab, an anti-cd20 monoclonal anti-body: history and mechanism of action. Am J Transplant. 2006;6:859. 34. Blume OR, Yost SE, Kaplan B. Antibody-mediated rejection: pathogenesis, prevention, treatment, and outcomes. J Trans-plant. 2012:201754. 35. Becker YT, Becker BN, Pirsch JD, Sollinger HW. Rituximab as treatment for refractory kidney transplant rejection. Am J Transplant. 2004;4:996. 36. Perry DK, Burns
Surgery_Schwartz_2641	Surgery_Schwartz	J Trans-plant. 2012:201754. 35. Becker YT, Becker BN, Pirsch JD, Sollinger HW. Rituximab as treatment for refractory kidney transplant rejection. Am J Transplant. 2004;4:996. 36. Perry DK, Burns JM, Pollinger HS, et al. Proteasome inhibi-tion causes apoptosis of normal human plasma cells prevent-ing alloantibody production. Am J Transplant. 2009;9:201. 37. Everly MJ, Everly JJ, Susskind B, et al. Bortezomib provides effective therapy for antibodyand cell-mediated acute rejec-tion. Transplantation. 2008;86:1754. 38. Lock JE, Magro CM, Singer AL, et al. The use of antibody to complement protein C5 for salvage treatment of severe antibody-mediated rejection. Am J Transplant. 2011;24:e61. 39. Stegall MD, Diwan T, Raghavaiah S, et al. Terminal comple-ment inhibition decreases antibody-mediated rejection in sensitized renal transplant recipients. Am J Transplant. 2011; 11:2405. 40. Hodson EM, Jones CA, Webster AC, et al. Antiviral medica-tions to prevent cytomegalovirus disease and early	Surgery_Schwartz. J Trans-plant. 2012:201754. 35. Becker YT, Becker BN, Pirsch JD, Sollinger HW. Rituximab as treatment for refractory kidney transplant rejection. Am J Transplant. 2004;4:996. 36. Perry DK, Burns JM, Pollinger HS, et al. Proteasome inhibi-tion causes apoptosis of normal human plasma cells prevent-ing alloantibody production. Am J Transplant. 2009;9:201. 37. Everly MJ, Everly JJ, Susskind B, et al. Bortezomib provides effective therapy for antibodyand cell-mediated acute rejec-tion. Transplantation. 2008;86:1754. 38. Lock JE, Magro CM, Singer AL, et al. The use of antibody to complement protein C5 for salvage treatment of severe antibody-mediated rejection. Am J Transplant. 2011;24:e61. 39. Stegall MD, Diwan T, Raghavaiah S, et al. Terminal comple-ment inhibition decreases antibody-mediated rejection in sensitized renal transplant recipients. Am J Transplant. 2011; 11:2405. 40. Hodson EM, Jones CA, Webster AC, et al. Antiviral medica-tions to prevent cytomegalovirus disease and early