Genetically Modified Porcine Kidneys Have Sufficient Tissue Integrity for Use in Pig-to-Human Xenotransplantation.

OBJECTIVE: We sought to determine if genetically modified porcine kidneys used for xenotransplantation had sufficient tissue integrity to support long term function in a human recipient. BACKGROUND: Kidney transplantation remains the best available treatment for patients with end-stage kidney disease. However, a shortage of available donor human kidneys prevents many patients from achieving the benefits of transplantation. Xenotransplantation is a potential solution to this shortage. Recent pre-clinical human studies have demonstrated kidneys from genetically modified pig donors can be transplanted without hyperacute rejection and capable of providing creatinine and other solute clearance. It is unknown whether the porcine kidneys would tolerate the relatively higher resting blood pressure in an adult human recipient compared to the pig donor or non-human primate (NHP) recipients used in translational studies. Furthermore, previous experience in NHPs raised concerns about the tissue integrity of the porcine ureter and post-xenotransplant growth of the porcine kidney. METHODS: Kidneys recovered from porcine donors with 10 gene edits were transplanted into decedent brain dead recipients who were not eligible for organ donation. Decedents underwent bilateral native nephrectomy prior to transplant and were followed for 3-7 days. Standard induction and maintenance immunosuppression was used as previously reported. Vital signs including blood pressure were recorded frequently. Kidney xenografts were assessed daily, serially biopsied, and were measured at implantation and study completion. RESULTS: Three decedents underwent successful xenotransplantation. Subcapsular hematomas developed requiring incision of the xenograft capsules to prevent Page kidney. Blood pressures were maintained in a physiologic range for adult humans (median arterial pressures (MAP) 108.5mmHg (Interquartile Range (IQR): 97-114mmHg), 74mmHg (IQR: 71-78mmHg), and 95mmHg (IQR: 88-99mmHg. respectively) and no bleeding complications or aneurysm formation was observed. Serial biopsies were taken from the xenografts without apparent loss of tissue integrity, despite the lack of a capsule. Ureteroneocystotomies remained intact without evidence of urine leak. Xenograft growth was observed, but plateaued, in 1 decedent with increased volume of the left and right xenografts by 25% and 26%, respectively, and in the context of human growth hormone levels consistently less <0.1 ng/ml and insulin-like growth factor 1 levels ranging from 34-50 ng/ml. CONCLUSIONS: The findings of this study suggest kidneys from 10-gene edited porcine donors have sufficient tissue integrity to tolerate xenotransplantation into a living human recipient. There was no evidence of anastomotic complications and the xenografts tolerated needle biopsy without issue. Xenograft growth occurred but plateaued by study end; further observation and investigation will be required to confirm this finding and elucidate underlying mechanisms.

Spatiotemporal immune atlas of a clinical-grade gene-edited pig-to-human kidney xenotransplant.

Pig-to-human xenotransplantation is rapidly approaching the clinical arena; however, it is unclear which immunomodulatory regimens will effectively control human immune responses to pig xenografts. Here, we transplant a gene-edited pig kidney into a brain-dead human recipient on pharmacologic immunosuppression and study the human immune response to the xenograft using spatial transcriptomics and single-cell RNA sequencing. Human immune cells are uncommon in the porcine kidney cortex early after xenotransplantation and consist of primarily myeloid cells. Both the porcine resident macrophages and human infiltrating macrophages express genes consistent with an alternatively activated, anti-inflammatory phenotype. No significant infiltration of human B or T cells into the porcine kidney xenograft is detectable. Altogether, these findings provide proof of concept that conventional pharmacologic immunosuppression may be able to restrict infiltration of human immune cells into the xenograft early after compatible pig-to-human kidney xenotransplantation.

The Opioid Risk Tool Correlates With Increased Postsurgical Opioid Use Among Patients With Orthopedic Trauma.

The aim of this study was to determine whether the Opioid Risk Tool (ORT), which has been validated in patients with chronic pain, relates to postoperative opioid consumption. The purpose was to investigate a tool that could help identify patients with orthopedic trauma at high risk for opioid abuse. Patients 18 to 80 years old presenting between May 2018 and August 2018 to UNC Hospitals with isolated orthopedic injuries that required surgical intervention were considered for inclusion. At 2 weeks postoperatively, the ORT was administered. At 6 weeks postoperatively, total morphine milligram equivalents (MME) was determined for each patient. Each patient was also categorized as either low risk (LR) or moderate to high risk (M-HR) based on the cumulative ORT score. Finally, opioid prescriptions provided after 6 weeks postoperatively was recorded. One hundred four patients met the inclusion criteria, and 42 completed the questionnaire. Thirty patients were categorized as LR and 12 patients as M-HR. Patients who were at M-HR consumed a significantly higher MME than LR patients (LR=406 [95% CI, 287-526]; M-HR=824 [95% CI, 591-1057]; P=.001). Linear regression analysis showed that for each additional risk factor, opioid consumption increased by 61 MME, and approximately 58% of the variation in opioid consumption could be explained by the ORT (beta=61, R2=0.58, P=.02). In this study, the ORT predicted which patients would have increased opioid consumption after orthopedic trauma surgery. Each additional risk factor correlated with increased opioid use. The ORT did not predict which patients would continue to receive opioid prescriptions after 6 weeks postoperatively. [Orthopedics. 2023;46(4):e219-e222.].

Spatiotemporal immune atlas of the first clinical-grade, gene-edited pig-to-human kidney xenotransplant.

Pig-to-human xenotransplantation is rapidly approaching the clinical arena; however, it is unclear which immunomodulatory regimens will effectively control human immune responses to pig xenografts. We transplanted a gene-edited pig kidney into a brain-dead human recipient on pharmacologic immunosuppression and studied the human immune response to the xenograft using spatial transcriptomics and single-cell RNA sequencing. Human immune cells were uncommon in the porcine kidney cortex early after xenotransplantation and consisted of primarily myeloid cells. Both the porcine resident macrophages and human infiltrating macrophages expressed genes consistent with an alternatively activated, anti-inflammatory phenotype. No significant infiltration of human B or T cells into the porcine kidney xenograft was detected. Altogether, these findings provide proof of concept that conventional pharmacologic immunosuppression is sufficient to restrict infiltration of human immune cells into the xenograft early after compatible pig-to-human kidney xenotransplantation.

First clinical-grade porcine kidney xenotransplant using a human decedent model.

A radical solution is needed for the organ supply crisis, and the domestic pig is a promising organ source. In preparation for a clinical trial of xenotransplantation, we developed an in vivo pre-clinical human model to test safety and feasibility tenets established in animal models. After performance of a novel, prospective compatible crossmatch, we performed bilateral native nephrectomies in a human brain-dead decedent and subsequently transplanted two kidneys from a pig genetically engineered for human xenotransplantation. The decedent was hemodynamically stable through reperfusion, and vascular integrity was maintained despite the exposure of the xenografts to human blood pressure. No hyperacute rejection was observed, and the kidneys remained viable until termination 74 h later. No chimerism or transmission of porcine retroviruses was detected. Longitudinal biopsies revealed thrombotic microangiopathy that did not progress in severity, without evidence of cellular rejection or deposition of antibody or complement proteins. Although the xenografts produced variable amounts of urine, creatinine clearance did not recover. Whether renal recovery was impacted by the milieu of brain death and/or microvascular injury remains unknown. In summary, our study suggests that major barriers to human xenotransplantation have been surmounted and identifies where new knowledge is needed to optimize xenotransplantation outcomes in humans.