Primary hyperoxaluria: simultaneous combined liver and kidney transplantation from a living related donor

Extreme living donation: A single center simultaneous and sequential living liver-kidney donor experience with long-term outcomes under literature review

OBJECTIVES

Living liver and kidney donor surgeries are major surgical procedures applied to healthy people with mortality and morbidity risks not providing any direct therapeutic advantage to the donor. In this study, we aimed to share our simultaneous and sequential living liver-kidney donor experience under literature review in this worldwide rare practice.

MATERIAL AND METHODS

Between January 2007 and February 2018, a total of 1109 living donor nephrectomies and 867 living liver donor hepatectomies were performed with no mortality to living-related donors. Eight donors who were simultaneous or sequential living liver-kidney donors in this time period were retrospectively reviewed and presented with their minimum 2- year follow-up.

RESULTS

Of the 8 donors, 3 of them were simultaneous and 5 of them were sequential liver-kidney donation. All of them were close relatives. Mean age was 39 (26-61) years and mean BMI was 25.7 (17.7-40). In 3 donors, right lobe, in 4 donors, left lateral sector, and in 1 donor, left lobe hepatectomy were performed. Median hospital stay was 9 (7-13) days. Two donors experienced early and late postoperative complications (Grade 3b and Grade 1). No mortality and no other long-term complication occurred.

CONCLUSION

Expansion of the donor pool by utilizing grafts from living donors is a globally-accepted proposition since it provides safety and successful outcomes. Simultaneous or sequential liver and kidney donation from the same donor seems to be a reasonable option for combined liver-kidney transplant recipients in special circumstances with acceptable outcomes.

Simultaneous laparoscopic left lateral sectionectomy and nephrectomy in the same living donor: The first case report

With the presence of organ shortage, living donors remain important sources of grafts, especially for pediatric recipients. Laparoscopic nephrectomy has become the gold standard for living donors. Additionally, laparoscopic partial liver procurement in living donors has proven its safety and feasibility in the latest studies. We have combined both approaches to perform a simultaneous liver-kidney transplantation in a pediatric patient from the same living donor. Our experience of laparoscopic left lateral sectionectomy and laparoscopic nephrectomy in living donors was the basis for adapting to this procedure. A 29-year-old mother was an ABO-incompatible (ABOi) donor for the left lateral section (LLS) of the liver and left kidney for her 2-year-old son. The postoperative period was uneventful. Two sessions of plasmapheresis and rituximab induction were necessary to prepare for ABOi transplantation. The donor and recipient were discharged on postoperative days 5 and 28, respectively. Simultaneous laparoscopic left lateral sectionectomy and nephrectomy in the same living donor is feasible for transplantation from the parent to the child with advanced laparoscopic expertise.

Landscape of Living Multiorgan Donation in the United States: A Registry-Based Cohort Study

BACKGROUND

The donation of multiple allografts from a single living donor is a rare practice, and the patient characteristics and outcomes associated with these procedures are not well described.

METHODS

Using the Scientific Registry of Transplant Recipients, we identified 101 living multiorgan donors and their 133 recipients.

RESULTS

The 49 sequential (donations during separate procedures) multiorgan donors provided grafts to 81 recipients: 21 kidney-then-liver, 15 liver-then-kidney, 5 lung-then-kidney, 3 liver-then-intestine, 3 kidney-then-pancreas, 1 lung-then-liver, and 1 pancreas-then-kidney. Of these donors, 38% donated 2 grafts to the same recipient and 15% donated 2 grafts as non-directed donors. Compared to recipients from first-time, single organ living donors, recipients from second-time living donors had similar graft and patient survival. The 52 simultaneous (multiple donations during one procedure) multiorgan donors provided 2 grafts to 1 recipient each: 48 kidney-pancreas and 4 liver-intestine. Donors had median of 13.4 years (interquartile range, 8.3-18.5 years) of follow-up. There was one reported death of a sequential donor (2.5 years after second donation). Few postdonation complications were reported over a median of 116 days (interquartile range, 0-295 days) of follow-up; however, routine living donor follow-up data were sparse. Recipients of kidneys from second-time living donors had similar graft (P = 0.2) and patient survival (P = 0.4) when compared with recipients from first-time living donors. Similarly, recipients of livers from second-time living donors had similar graft survival (P = 0.9) and patient survival (P = 0.7) when compared with recipients from first-time living donors.

CONCLUSIONS

Careful documentation of outcomes is needed to ensure ethical practices in selection, informed consent, and postdonation care of this unique donor community.

Left Lateral Sectionectomy of the Native Liver and Combined Living-Related Liver-Kidney Transplantation for Primary Hyperoxaluria Type 1

Primary hyperoxaluria type I (PH1), the most severe form of primary hyperoxalurias, is a liver disease of the metabolic defect in glyoxylate detoxification that can be corrected by liver transplantation. A 21-year-old man presented to our center after 4 months of regular hemodialysis for kidney failure caused by nephrolithiasis. A diagnosis of PH1 was confirmed by mutations of the AGXT gene. Left lateral sectionectomy of the native liver was performed; and auxiliary partial orthotopic liver transplantation (APOLT) and kidney transplantation were carried out synchronously using a living donor. After transplantation, the patient's plasma oxalate and creatinine levels substantially decreased and the patient recovered well with good dual grafts function. APOLT and kidney transplantation can compensate the liver deficient in liver enzyme production and aid the renal elimination of oxalate, thus serving as an effective treatment option for patients with PH1. In conclusion, left lateral sectionectomy of the native liver and combined living-related liver-kidney transplantation can be a surgical option for PH1.

Liver transplantation using grafts with rare metabolic disorders

Metabolic diseases that involve the liver represent a heterogeneous group of disorders. Apart from the metabolic defect, the subject's liver functions may be normal. With the increasing need for organs, livers from donors with metabolic diseases other than familial amyloid polyneuropathy might be possibly used for transplantation. However, whether such livers qualify as grafts and how they might impact recipient outcome are still unanswered questions. This review of the literature summarizes current experience in the use of such grafts in the context of cadaveric, domino, and living-related liver transplantation.

Two-step transplantation for primary hyperoxaluria: a winning strategy to prevent progression of systemic oxalosis in early onset renal insufficiency cases

Several transplant strategies for PH1 have been proposed, and LT is performed to correct the metabolic defects. The patients with PH1 often suffer from ESRD and require simultaneous LKT, which leads to a long wait due to the shortage of suitable organ donors. Five patients with PH1 underwent LDLT at our institute. Three of the five patients were under dialysis before LDLT, while the other two patients were categorized as CKD stage 3. An isolated LDLT was successfully performed in all but our first case, who had complicated postoperative courses and consequently died due to sepsis after retransplantation. The renal function of the patients with CKD stage 3 was preserved after LDLT. On the other hand, our second case with ESRD underwent successful LDKT six months after LDLT, and our infant case is waiting for the subsequent KT without any post-LDLT complications after the early establishment of PD. In conclusion, a two-step transplant strategy may be needed as a life-saving option for patients with PH1 and may be possible even in small infants with systemic oxalosis. While waiting for a subsequent KT, an early resumption of PD should be considered from the perspective of the long-term requirement of RRT.

Hepatocyte Transplantation Ameliorates the Metabolic Abnormality in a Mouse Model of Acute Intermittent Porphyria

Acute intermittent porphyria (AIP) is an autosomal dominant disorder characterized by insufficient porphobilinogen deaminase (PBGD) activity. When hepatic heme synthesis is induced, porphobilinogen (PBG) and 5-aminolevulinic acid (ALA) accumulate, which causes clinical symptoms such as abdominal pain, neuropathy, and psychiatric disturbances. Our aim was to investigate if hepatocyte transplantation can prevent or minimize the metabolic alterations in an AIP mouse model. We transplanted wild-type hepatocytes into PBGD-deficient mice and induced heme synthesis with phenobarbital. ALA and PBG concentrations in plasma were monitored, and the gene transcriptions of hepatic enzymes ALAS1, PBGD, and CYP2A5 were analyzed. Results were compared with controls and correlated to the percentage of engrafted hepatocytes. The accumulation of ALA and PBG was reduced by approximately 50% after the second hepatocyte transplantation. We detected no difference in mRNA levels of PBGD, ALAS1, or CYP2A5. Engraftment corresponding to 2.7% of the total hepatocyte mass was achieved following two hepatocyte transplantations. A lack of precursor production in less than 3% of the hepatocytes resulted in a 50% reduction in plasma precursor concentrations. This disproportional finding suggests that ALA and PBG produced in PBGD-deficient hepatocytes crossed cellular membranes and was metabolized by transplanted cells. The lack of effect on enzyme mRNA levels suggests that no significant efflux of heme from normal to PBGD-deficient hepatocytes takes place. Further studies are needed to establish the minimal number of engrafted hepatocytes needed to completely correct the metabolic abnormality in AIP and whether amelioration of the metabolic defect by partial restoration of PBGD enzyme activity translates into a clinical effect in human AIP.

Feasible isolated liver transplantation for a cirrhotic patient on chronic hemodialysis

End-stage liver and kidney disease (ELKD) is an indication for deceased donor simultaneous liver-kidney transplantation. Although a few cases of living donor liver-kidney transplantation have been reported, the invasiveness remains to be discussed. Living donor liver transplantation (LDLT) is an alternative choice for ELKD, but has never been reported. Here, we report a case of successful LDLT for a patient with ELKD on hemodialysis. The patient was a 63-year-old male and had decompensated hepatitis C cirrhosis with seronegativity for hepatitis C virus. He had non-diabetic end-stage renal failure and had been on hemodialysis for 3 years. He was in good general condition except for hepatic and renal failure. The living donor was his 58-year-old healthy wife. A right lobe graft was transplanted to the recipient under continuous hemodiafiltration (CHDF) and extracorporeal veno-venous bypass. CHDF was continued until postoperative day 4, at which point CHDF was converted to hemodialysis. His posttransplant course was good and he was discharged on postoperative day 36. To the best of our knowledge, this is the first report of LDLT for a patient on chronic hemodialysis. Therefore, being on hemodialysis is not a contraindication for LDLT. LDLT is feasible for a patient with ELKD on hemodialysis.

Sequential liver-kidney transplantation in a boy with congenital hepatic fibrosis and nephronophthisis from a living donor

A five-yr-old boy developed chronic liver failure and ESKD because of CHF and juvenile NPHP. He underwent sequential liver and kidney transplantation with a compatible blood type from his father, at five yr, seven months and five yr, 11 months old, respectively. Because the patient was not in ESKD, we initially performed LDLT because of significant portal hypertension. Even after LDLT, his ascites was not ameliorated, and he needed continuous drainage of ascites and daily albumin and gamma globulin infusion. Thereafter, he progressed to ESKD and needed hemodialysis for one month before LDKT. CDC crossmatch for donor B cells in the warm test, FCXM for B cell IgG, and flow PRA for donor class II were positive before LDKT. After pretreatment of three courses of plasma exchange and intravenous gamma globulin, LDKT was performed. Two weeks after LDKT, AIHA concomitant with autoimmune thrombocytopenia, also called Evans syndrome, occurred because of passenger lymphocytes from the donor; however, the patient was successfully treated with intravenous methylprednisolone. Eighteen months have passed since LDKT, and liver and kidney function in both the recipient and donor are normal.

A single center experience of combined liver kidney transplantation

With advancements in the operative techniques, patient survival following liver transplantation (LTx) has increased substantially. This has led to the acceleration of pre-existing kidney disease because of immunosuppressive nephrotoxicity making additional kidney transplantation (KTx) inevitable. On the other hand, in a growing number of patients on the waiting list to receive liver, long waiting time has resulted in adverse effect of decompensated liver on the kidney function. During the last two decades, the transplant community has considered combined liver kidney transplantation (CLKTx) to overcome this problem. The aim of our study is to present an overview of our experience as well as a review of the literature in CLKTx and to discuss the controversy in this regard. All performed CLKTx (n = 22) at our institution as well as all available reported case series focusing on CLKTx are extracted. The references of the manuscripts were cross-checked to implement further articles into the review. The analyzed parameters include demographic data, indication for LTx and KTx, duration on the waiting list, Model for End-Stage Liver Disease (MELD) score, Child-Turcotte-Pugh (CTP) score, immunosuppressive regimen, post-transplant complications, graft and patient survival, and cause of death. From 1988 to 2009, a total of 22 CLKTx were performed at our institution. The median age of the patients at the time of CLKTx was 44.8 (range: 4.5-58.3 yr). The indications for LTx were liver cirrhosis, hyperoxaluria type 1, polycystic liver disease, primary or secondary sclerosing cholangitis, malignant hepatic epithelioid hemangioendothelioma, cystinosis, and congenital biliary fibrosis. The KTx indications were end-stage renal disease of various causes, hyperoxaluria type 1, polycystic kidney disease, and cystinosis. The mean follow-up duration for CLKTx patients were 4.6 +/- 3.5 yr (range: 0.5-12 yr). Overall, the most important encountered complications were sepsis (n = 8), liver failure leading to retransplantation (n = 4), liver rejection (n = 3), and kidney rejection (n = 1). The overall patient survival rate was 80%. Review of the literature showed that from 1984 to 2008, 3536 CLKTx cases were reported. The main indications for CLKTx were oxalosis of both organs, liver cirrhosis and chronic renal failure, polycystic liver and kidney disease, and liver cirrhosis along with hepatorenal syndrome (HRS). The most common encountered complications following CLKTx were infection, bleeding, biliary complications, retransplantation of the liver, acute hepatic artery thrombosis, and retransplantation of the kidney. From the available data regarding the need for post-operative dialysis (n = 673), a total of 175 recipients (26%) required hemodialysis. During the follow-up period, 154 episodes of liver rejection (4.3%) and 113 episodes of kidney rejection (3.2%) occurred. The cumulative 1, 2, 3, and 5 yr survival of both organs were 78.2%, 74.4%, 62.4%, and 60.9%, respectively. Additionally, the cumulative 1, 2, 3, and 5 yr patient survival were 84.9%, 52.8%, 45.4%, and 42.6%, respectively. The total number of reported deaths was 181 of 2808 cases (6.4%), from them the cause of death in 99 (55%) cases was sepsis. It can be concluded that there is still no definitive evidence of better graft and patient survival in CLKTx recipients when compared with LTx alone because of the complexity of the exact definition of irreversible kidney function in LTx candidates. Additionally, CLKTx is better to be performed earlier than isolated LTx and KTx leading to the avoidance of deterioration of clinical status, high rate of graft loss, and mortality. Shorter graft ischemia time and more effective immunosuppressive regimens can reduce the incidence of graft malfunctioning in CLKTx patients. Providing a model to reliably determine the need for CLKTx seems necessary. Such a model can be shaped based upon new and precise markers of renal function, and modification of MELD system.

The primary hyperoxalurias

The primary hyperoxalurias (PHs) are rare autosomal-recessive inborn errors of metabolism. In the most severe form (type 1), recurrent kidney stones and progressive nephrocalcinosis lead to the loss of kidney function, accompanied by systemic oxalosis, and often requires dialysis and/or transplantation. The variety of genetic mutations leading to PH increasingly are being defined, resulting in the ability to diagnose most patients accurately via minimally invasive means. During and after definitive diagnosis, supportive therapies with pyridoxine supplementation, urinary crystallization inhibitors, and hydration should be used, but have varying success. Emerging information about the renal tubular and intestinal transport of oxalate is leading to increasing evidence to support the use of oxalate-degrading bacteria (probiotics) and enzymes in the treatment of PH. Organ transplantation historically has offered the only potential cure for PH, and may include kidney-alone, combined liver-kidney, or pre-emptive liver-alone transplantation. Exciting new approaches in the treatment of type 1 PH, however, are under investigation. These include the restoration of defective enzymatic activity through the use of chemical chaperones, hepatocyte cell transplantation, or enzyme replacement by recombinant gene therapy. These novel approaches illustrate the goal for the ideal treatment of PH: correcting the genetic defect without exposing patients to the life-long risks associated with organ transplantation.

Combined liver-kidney transplantation and follow-up in primary hyperoxaluria treatment: report of three cases

INTRODUCTION

Primary hyperoxaluria type-1 (PH1) is an autosomal recessive disorder caused by impaired activity of the hepatic peroxisomal alanine-glyoxilate aminotransferase, which leads to end-stage renal disease (ESRD) and requires combined liver-kidney transplantation (CLKT). Herein, we have reported 3 children diagnosed with PH1 who received CLKT. CASE 1: A 4.5-year-old boy with an elder brother diagnosed with PH1 was diagnosed during family screening when the sonography showed multiple calculi. Within 5 years he experienced flank pain, hematuria attacks, and anuric phases due to obstruction and received hemodialysis (HD) when ESRD appeared. CLKT was performed from his full-match sister at the age of 9.5. He is doing well at 5.5 years. CASE 2: A 7-year-old boy was admitted with polyuria, polydypsia, and stomach pain with renal stones on sonography. PD was instituted when serum creatinine and BUN levels were measured as high values. At the age of 10, CKLT was performed from his mother. His liver and renal function tests are well at 14 months after CKLT. CASE 3: A 2.5-year-old girl had attacks of dark urine without any pain; renal stones were imaged on sonography. She was diagnosed with PH1 and operated on several times due to obstruction. She received peritoneal dialysis and a cadaveric CLKT was performed when she was 9 years old. At the age of 16, she experienced chronic allograft nephropathy requiring HD and subsequent cadaveric donor renal transplantation at 1.5 years after initiation of HD.

CONCLUSION

Herein, we have presented the favorable clinical outcomes of patients with CKLT to indicate the validity of this treatment choice for PH1.

Hyperoxaluria and systemic oxalosis: current therapy and future directions

Excessive urinary oxalate excretion, termed hyperoxaluria, may arise from inherited or acquired diseases. The most severe forms are caused by increased endogenous production of oxalate related to one of several inborn errors of metabolism, termed primary hyperoxaluria. Recurrent kidney stones and progressive medullary nephrocalcinosis lead to the loss of kidney function, requiring dialysis or transplantation, accompanied by systemic oxalate deposition that is termed systemic oxalosis. For most primary hyperoxalurias, accurate diagnosis leads to the use of therapies that include pyridoxine supplementation, urinary crystallisation inhibitors, hydration with enteral fluids and, in the near future, probiotic supplementation or other innovative therapies. These therapies have varying degrees of success, and none represent a cure. Organ transplantation results in reduced patient and organ survival when compared with national statistics. Exciting new approaches under investigation include the restoration of defective enzymatic activity through the use of chemical chaperones and hepatocyte cell transplantation, or recombinant gene therapy for enzyme replacement. Such approaches give hope for a future therapeutic cure for primary hyperoxaluria that includes correction of the underlying genetic defect without exposure to the life-long dangers associated with organ transplantation.

One Living Donor and Two Donations: Sequential Kidney and Liver Donation With 20-Years Interval

The shortage of cadaveric donor organs remains the critical factor limiting the use of organ transplantation. In this environment of organ shortage, living donor transplantation has emerged as a reasonable therapeutic alternative. Simultaneous kidney-liver transplantation from the same donor has been described. We report a case of right liver lobe transplant from a living donor who had donated his kidney to the same recipient 20 years prior.

Liver Transplantation for Inborn Errors of Metabolism

Liver transplantation (LT) has become an accepted treatment for various hepatic-based metabolic disorders. For diseases with hepatic origin but mainly extrahepatic manifestations, it can be regarded as a means of gene therapy. Depending on the underlying disease, optimal dietary and medicamentous treatment cannot reliably prevent periods of metabolic decompensation resulting in severe organ damage. In severe neonatal forms of urea cycle disorders, liver transplantation should be considered in early infancy. The same applies to propionic acidemia, although severe perioperative complications have been described. In methylmalonic aciduria, there is no consensus whether LT alone is prior to combined liver and kidney transplantation (LKT). Moreover, late neurologic complications can occur in some patients with propionic and methylmalonic acidemias. LT as well as LKT is discussed in primary hyperoxaluria. For patients with cystic fibrosis and biliary cirrhosis, LT has become an established treatment that may even improve pulmonary function. Careful individual decisions must be made in patients with mitochondrial disorders because of possible progressive neuromuscular involvement. In most hepatic-based metabolic disorders, restoration of only about 10% of the original enzyme activity is sufficient to warrant sufficient metabolic control.

Cadaveric orthotopic auxiliary split liver transplantation and kidney transplantation: an alternative for type 1 primary hyperoxaluria

Liver transplantation (LTX) corrects the enzymatic defect responsible for type 1 primary hyperoxaluria (PH1). It has been advocated in combination with kidney transplantation (KTX) in patients with renal failure from PH1 because KTX alone can result in early graft loss. A 58-year-old male patient with PH1 on hemodialysis underwent resection of the left lateral segment of the liver followed by orthotopic auxiliary left lateral segment liver transplantation and kidney transplantation from a deceased donor. The serum oxalate dropped from 34.8 micromol/L before transplant to 3.6-8.3 in the first months posttransplant to <1 micromol/L (normal range 0.4-3.0). One year after posttransplant, the patient has an iothalamate glomerular filtration rate of 58 ml/min. Orthotopic auxiliary LTX is an alternative to whole LTX in PH1. By using a split deceased donor liver, it does not deprive the donor pool and protects the recipient from liver failure in case of graft loss.

Combined living donor liver/small bowel transplantation

We are reporting the first known case of sequential combined living donor liver/small bowel transplantation (LDL/SBT). A 2-year-old boy born with gastroschisis and intestinal malrotation lost his entire small bowel and colon shortly after birth. He underwent a living donor small bowel transplant at 1 year of age that was lost 4 months after implantation for posttransplant lymphoproliferative disease (PTLD). He recovered from PTLD but developed total parenteral nutrition (TPN)-induced liver failure. He received a combined left lateral liver and terminal ileum transplant that we chose to perform sequentially due to the presence of preformed antibodies against his mother's tissues. The mother had no complications and a cumulative hospital stay of 7 days. At 9 months postsurgery, the patient is on full enteral nutrition and has suffered neither technical complications nor rejection. The technique described here is reproducible and makes combined living donor LDL/SBT an alternative to combined cadaveric liver-small bowel transplant.

A 20-year experience of combined liver/kidney transplantation for primary hyperoxaluria (PH1): the European PH1 transplant registry experience 1984-2004

Primary hyperoxaluria (PH1) is a condition caused by a hepatic-based enzyme defect which can lead to renal failure due to oxalate stone disease, obstructive uropathy and nephrocalcinosis. It has been shown that the underlying metabolic defect can be corrected by liver transplantation and in most cases (renal failure having already occurred) is accompanied by a kidney graft. This paper describes the current results of 127 liver transplants performed in 117 patients over a 20-year period from 1984 to 2004 in 35 European centres. The mean age at onset of symptoms was 5.6 +/- 7.8 years and the mean age at which a diagnosis was made was 8.8 +/- 9.5 years. The diagnosis was confirmed by liver biopsy proven decreased AGT activity in 68% of cases, hyperoxaluria in 74%, hyperglycolicaciduria in 37% and hyperoxalaemia in 50%. Patients were transplanted at a mean age of 16.5 +/- 11.4 years following a period of dialysis of 3.2 +/- 3.2 years (range 0-14.4 years). 1-, 5- and 10-year patient survival values were 86, 80 and 69%, respectively, and liver graft survival rates of 80, 72 and 60% at the same time intervals. There have been 27 deaths and 10 liver retransplants have been carried out. Patient outcomes are improved when prolonged periods on dialysis and the complications of systemic oxalosis have not occurred.