Panel reactive antibody

The PRA is an immunologic test routinely performed to determine a recipient’s antibody response to human leukocyte antigens, a protein that coats human cells and is unique to each individual. Exposure to nonself human proteins results in production of antihuman leukocyte antigen (anti-HLA) antibodies, a phenomenon known as sensitization. Sensitization to HLA can occur with administration of blood products, implantation of nonself human tissue into the body, use of a ventricular assist device, or pregnancy. The former two often occur in children undergoing palliative or corrective surgery for congenital heart disease. Anti-HLA antibodies may also develop spontaneously.

HLAs are divided into two classes, class I and class II, and are specified by a letter (A, B, C, DR, DQ) and number code (e.g., A2, B8, C6) based on the molecular structure. The PRA test is performed by exposing a potential recipient’s serum to the lymphocytes of a panel of about 100 blood donors. Results are reported in percentage of positive reactions within the panel from 0% to 100%. Thus, if a recipient reacts to 50 of 100 samples, the PRA is 50%. This test is reported for class I and class II antigens separately. Current testing is predominately performed with Luminex beads, which allows for HLA specificities to be reported. In other words, a list of antigen codes producing a positive antibody reaction can be generated. These would be the undesirable antigens in a donor that could stimulate production of undesirable donor-specific antibodies (DSAs) and give a positive crossmatch. Knowing these antigens allows a virtual crossmatch to be performed comparing the donor HLAs with the list of anti-HLA antibodies of the recipient. A positive virtual crossmatch is likely to give a positive retrospective crossmatch if that heart were to be implanted.

The presence of DSAs is associated with antibody-mediated rejection and can reduce the longevity of the cardiac allograft. A PRA of more than 10% has historically been associated with decreased posttransplant 1-year graft survival. Strategies exist to reduce anti-HLA antibodies pretransplant, although variable in success, as well as strategies posttransplant to reduce the impact of DSAs, predominately with plasmapheresis. PRA in patients with repaired or palliated congenital heart disease can often be over 80%.

Anticoagulation

All patients with severe myocardial dysfunction are at risk for complications of systemic and pulmonary emboli. While there are no established guidelines for thrombosis prophylaxis in pediatric patients, most centers consider antiplatelet therapy with aspirin and/or anticoagulation with heparin or warfarin. Low-molecular-weight heparin is generally not used, as it cannot be easily reversed in a patient who must go to the operating room urgently once a donor heart has been identified.

ABO-incompatible listing and transplantation

At present, it is possible to perform an ABO-incompatible (ABOi) heart transplantation without risk of hyperacute rejection if performed prior to maturation of the immune system and development of isohemagglutinins, generally under 12 months of age and possibly under 24 months. ABOi posttransplant outcomes have been shown not to be statistically different from ABO-compatible transplantation outcomes, and there has also been some improvement in wait list outcomes. The UNOS allows listing of patients 1 to 2 years of age as eligible for ABOi transplantation with an A or B isohemagglutinin titer less than 1:16 and no limit on titer for those younger than 1 year. Most centers now have protocols regarding pre- and posttransplant care for individuals listed as eligible for and undergoing an ABOi transplantation. Predominately, the management centers on avoiding sensitization events related to administration of blood products and strict adherence to blood-typing protocol when blood products are needed.

Intraoperative considerations

Posttransplant cardiac function is affected by multiple factors, such as recipient pretransplant characteristics, donor characteristics and management, preservation techniques, and total ischemic time of the donor heart. Total ischemic time is defined as the total time starting from placement of the cross-clamp on the donor aorta to release of the recipient cross-clamp and is a major factor in early posttransplant cardiac function and transplant outcomes. Total ischemic times of less than 4 hours typically are associated with better graft function and posttransplant outcomes. Because of this, a great deal of planning goes into keeping ischemic time as low as possible. This includes planning for repeat sternotomies or performing any reconstruction that needs to be done prior to donor heart implantation, considering the logistics and travel times to donor site, and using implant techniques that reduce ischemic time.

Techniques of implantation have not changed significantly since the original description. ^, Although modifications may be necessary in transplantation for complex congenital heart disease patients, heart transplantation can be accomplished in virtually any congenital heart anomaly because the anatomic position of the aorta, pulmonary arteries, and left atrium are in a relatively constant position near the midline. Regardless of malposition or positional relationships of the great arteries, the aorta of the recipient can be mobilized to make anastomosis with the donor aorta possible. The left atrium is a midline structure; even when anomalies of pulmonary venous return exist, pulmonary veins usually approach the midline and can be incorporated into the repair. However, aortic root size mismatch can cause technical difficulty. Implantation of recipients with complex congenital heart disease can usually be accomplished by harvesting additional donor pulmonary artery, aorta, and caval tissue to replace deficient recipient tissue or to correct malposition of the vena cava or great arteries. ^,

There are generally two standard implantation techniques, classified by use of either a biatrial or bicaval anastomosis. In both techniques, left atrial tissue surrounding the recipient pulmonary veins is anastomosed to the donor left atrium. This is done to reduce implantation time and to avoid individual pulmonary vein anastomoses and subsequent stenosis. The traditional biatrial technique uses a relatively large cuff of recipient right and left atrial tissue anastomosed to a portion of both donor atria. This results in the presence of large atrial suture lines that can be a source for arrhythmia; possible injury to the sinus node, causing bradycardia; and atrial dilation resulting in alterations of atrial contractility, tricuspid valve function, and flow dynamics. This technique is primarily now used for infants and small children to avoid end-to-end anastomoses with small venae cavae or for patients with venous anomalies in which using the recipient atria is beneficial to the transplant. The newer bicaval technique removes the recipient right atrium and a large portion of the left atrium with preservation of the superior and inferior venae cavae and a cuff of tissue around the pulmonary veins. ^, End-to-end anastomoses of recipient and donor venae cavae are then used. This technique has the advantage of preserving sinus node function and atrial geometry.

Besides the issues discussed earlier, other intraoperative considerations include the administration of immunosuppressants during or immediately after implantation, delivery of inhaled nitric oxide (iNO) to support the donor right ventricle following implantation, and intraoperative plasmapheresis for any HLA antibody concerns. In the event of acute graft dysfunction and inability to separate from bypass, or for any other concerns about graft function, the use of temporary mechanical circulatory support should be considered.

Early perioperative management

The early perioperative management of the recipient is not significantly different from the management of any postcardiac surgical patient. The physiologic responses of the newly transplanted heart are altered because of denervation. The major changes related to autonomic denervation include diastolic dysfunction and exaggerated response to exogenously administered catecholamines. The transplanted heart must also adapt to a new environment related to recipient lung function and elevated PVR.

Autonomic system denervation results in a relatively fixed heart rate without respiratory variation. Heart rates are between 90 and 110 beats per minute but can be faster because of exogenous catecholamine administration. Heart rates can also be slower if the recipient has been exposed to amiodarone before transplantation or if there was injury to the donor sinus node due to cold preservation or to disruption of blood supply. Temporary pacing or isoproterenol infusion may be needed to support heart rate and cardiac output during the postoperative period. Permanent pacing is rarely necessary.

Early blood pressure instability is common because of loss of baroreceptor regulation and dependence of the transplanted heart on endogenous or exogenous catecholamines. Hypotension can have multiple causes, most related to the usual postcardiac bypass surgery issues. In addition, hypotension can be seen with primary graft dysfunction (discussed more later) and with vasoplegia in patients with a history of prolonged milrinone or amiodarone use.

Hypertension in the perioperative period has multiple causes. An increased stroke volume from the healthier transplanted heart into a systemic vascular bed that is abnormal because of a long-standing increase in SVR secondary to chronic heart failure is one such cause. Donor hearts are also often oversized, resulting in a larger stroke volume. This larger stroke volume can contribute to hypertension and to hyperperfusion syndrome, a condition in which an acute increase in cardiac output increases cerebral blood flow, resulting in cerebral vasoconstriction, symptomatic seizures, headache, or changes in mental status in a patient with a previously low cardiac output. The oversized donor heart eventually undergoes remodeling with regression of hypertrophy. The use of steroids for immunosuppression is an additional cause of posttransplant hypertension. Any symptomatic hypertension should be treated aggressively early in the perioperative period, but hypotension should be avoided in order to reduce the risk of renal dysfunction.

Systolic and/or diastolic dysfunction of the transplanted heart are often seen in the early postoperative period. The right ventricle is especially at risk owing to its susceptibility to preservation injury with thinner myocardium and increased myocardial stress from elevated PVR. Infusions of β-adrenergic agents for several days are often necessary to maintain optimal heart allograft function, as early myocardial function of the transplanted heart is dependent on catecholamine support. Milrinone, as well as other agents that improve contractility or decrease afterload, may be advantageous to support right ventricular function.

The hemodynamics of the transplanted heart reflect a significant shift to the left of the pressure/volume curve such that small increases in preload can result in significant elevations in ventricular end-diastolic and atrial pressures. Diastolic dysfunction is a significant impediment to early allograft function, limiting cardiac output. Some degree of diastolic dysfunction can persist well into the recovery phase and even several months after transplantation, with biopsy specimens often displaying evidence of persistent preservation injury.

Management of early heart allograft dysfunction

Early allograft dysfunction may be related to unsuspected injury prior to organ procurement or because of preservation injury. The other major cause of primary allograft failure is elevated PVR in the recipient. Allograft failure rarely is caused by acute antibody-mediated injury.

Donor risk factors for allograft dysfunction include “down time of the donor” (length of initial resuscitation), evidence of myocardial injury with elevation of troponin or ventricular dysfunction on echocardiogram, and use of high-dose inotropic support (dopamine/dobutamine >20 μg/kg per minute or epinephrine/norepinephrine >0.1 μg/kg per minute) in the donor. Abnormal heart function seen in the midst of the catecholamine storm of brain death can recover. Repeating the echocardiogram remote from the initial resuscitation period or after the reduction or discontinuation of inotropic support can increase confidence in accepting the donor heart.

The other major reason for primary donor heart dysfunction is right heart failure from high PVR. We have known since the early days of heart transplantation that the donor right ventricle will not function well when exposed to an abnormal pulmonary circulation. High PVR in the recipient increases perioperative morbidity and mortality and can affect late survival. Potential heart recipients generally undergo cardiac catheterization before heart transplantation to document the anatomy of systemic and pulmonary venous connections, determine pulmonary artery size and distribution, and calculate PVR. The upper limit of PVR associated with successful orthotopic heart transplantation is not known. Criteria developed from the adult heart transplant experience indicate that a PVR greater than 6 Wood units or a transpulmonary gradient (pulmonary artery mean pressure minus left atrial mean pressure) greater than 15 mm Hg is associated with increased perioperative mortality. The transpulmonary gradient is the most useful surrogate for PVR because estimation of cardiac output in the catheterization laboratory can be flawed if using the Fick equation. In children, the PVR index (PVRI), determined by dividing the transpulmonary gradient by the cardiac index, is more useful, because children come in all sizes. A PVRI less than 6 index units is associated with low perioperative mortality. Orthotopic heart transplants have been successful with a PVRI greater than 6 and as high as 10 index units but with increased morbidity and mortality rates. The diagnosis of high PVR is evident as the recipient is weaned from cardiopulmonary bypass. Intraoperative transesophageal echocardiography demonstrates dilation of the right ventricle and a small, underfilled left heart. Acute management of high PVR and right heart dysfunction includes ventilation with a high fraction of inspired oxygen and administration of iNO at 20 to 40 ppm. The need for continuous pulmonary vasodilator medications in the immediate perioperative period is unusual, but prostacyclin and sildenafil have both proved effective in this situation.

Immunosuppression and heart allograft rejection

It is imperative that immunosuppression be initiated early after heart transplantation. Solid-organ transplants transfer antigen-presenting cells (APCs) that are recognized as foreign by the recipient’s HLA immune system, which sets up a cascade of lymphocyte stimulation and proliferation. These lymphocytes then migrate to the heart allograft, where they can adhere to myocytes and endothelial receptors and cause tissue destruction. T-cell activation is the prime promoter of allograft rejection. The initial signal is T-cell receptor binding of antigen on the surface of an APC. The APC is derived from the donor in the form of a monocyte, or a tissue macrophage. Interaction of the APC and T-cell receptor causes release of interleukin (IL)-1 from the APC, which activates the T cell. Activated T cells secrete IL-2 and other lymphokines that induce proliferation of activated T cells, which migrate to the allograft and cause tissue damage.

Immunosuppression protocols are similar from center to center with generally only small variations. Initial immunosuppression protocols typically include high-dose corticosteroids, induction with IL-2 receptor blockade (e.g., basiliximab) or antithymocyte globulin (ATG), followed within approximately 48 hours by introduction of a calcineurin inhibitor (CNI), such as cyclosporine or tacrolimus ( Table 37.1 ).

TABLE 37.1

Only gold members can continue reading. Log In or Register to continue

Share this:

• Click to share on Twitter (Opens in new window)
• Click to share on Facebook (Opens in new window)

Related

Related posts:

Evolution of critical care nursing Pediatric vascular access and centeses Structure and function of the heart Echocardiographic imaging Structure and development of the upper respiratory system Neonatal pulmonary disease

Stay updated, free articles. Join our Telegram channel

Join