Renal dysfunction in liver transplant recipients: evaluation of the critical issues.

Major progress has been made in the field of liver transplantation since the first procedure was performed nearly 50 years ago. Despite these improvements, renal dysfunction before and after liver transplantation remains a major complicating factor associated with increased health care costs, morbidity, and mortality. Creatinine-based estimates of renal function are inaccurate in the setting of end-stage liver disease and often lead to underdiagnosis and late intervention. This issue is critical in that it is important to understand both the etiology and chronicity of renal dysfunction before liver transplantation because the treatment clearly varies, especially with respect to simultaneous liver-kidney (SLK) transplantation. Because of the scarcity of available grafts, identifying appropriate candidates for SLK transplantation is crucial. Hepatorenal syndrome is common in liver transplant candidates; however, other etiologies of renal dysfunction need to be considered. Renal dysfunction after liver transplantation is common and may have an acute or chronic presentation. Although calcineurin inhibitors (CNIs) have been associated with post-liver transplant nephrotoxicity, their role may be overestimated, and other contributing etiologies should remain in a clinician's differential diagnosis. Alternatives to CNIs have been evaluated; however, a safe immunosuppressive regimen that achieves the preservation of renal function in liver transplant recipients remains to be established. In this review of the literature, renal dysfunction in the setting of liver transplantation is evaluated, and the critical issues that are barriers to improved outcomes are highlighted.

Weight loss: a neglected intervention in the management of chronic kidney disease.

PURPOSE OF REVIEW: Obesity is being increasingly implicated as an independent risk factor for the development of chronic kidney disease (CKD), raising the question whether reversing obesity can be utilized as a mainstay or an adjunct therapy for CKD and possibly for its prevention. The purpose of this review is to examine the impact of treatment of obesity on renal outcomes. RECENT FINDINGS: Many observations have pointed to improvement in renal parameters following weight loss. In fact, both surgical and nonsurgical approaches appear to be effective at reducing blood pressure and proteinuria. Weight loss has also been shown to lower glomerular filtration rate (GFR) in obese patients, not an insignificant benefit considering that intra-glomerular hypertension and the subsequent hyperfiltration in the setting of obesity might be a main driver for the development of CKD. SUMMARY: Urinary protein excretion, blood pressure, and GFR improve with surgical and nonsurgical weight loss interventions. Whether improvements in these surrogate outcomes after weight loss actually translate into a reduction in the risk of CKD or amelioration in the rate of progression of established CKD is yet to be determined.

Opioids induce renal abnormalities in tumor-bearing mice.

BACKGROUND/AIMS: The etiology of renal dysfunction in cancer patients is likely to be multifactorial. A large proportion of these patients receive opioid analgesics, but whether opioids contribute to renal dysfunction remains uncertain. In a murine cancer model, we examined the effects of chronic opioid administration on renal function and pathology, and the molecular mechanisms involved. METHODS: C3H/HeJ mice implanted with 2472 tumor cells were treated with either morphine or hydromorphone in clinically relevant doses, or PBS (controls). Renal function was assessed by blood and urine chemistry as well as by measuring mean arterial pressure (MAP) and kidney perfusion. Pathological changes in the kidneys were examined by routine histology. Molecular changes were examined by assessing eNOS, iNOS, HO-1 and COX-2 expression in whole-kidney lysates by Western immunoblotting, and cellular colocalization of these enzymes was determined using immunofluorescence microscopy. RESULTS: Three weeks of opioid treatment resulted in increased kidney weight, elevated BUN and proteinuria, and decreased MAP. This was accompanied by histological abnormalities including glomerular enlargement, hypercellularity, peritubular congestion, vasodilatation and tubular casts. The vasoregulatory molecules iNOS, eNOS, HO-1 and COX-2 were upregulated in the kidneys. The NOS inhibitor L-NAME prevented the morphine-induced increase in perfusion and kidney weight. CONCLUSIONS: The chronic use of clinically relevant doses of opioidsleads to structural kidney abnormalities, upregulates NOS, COX-2 and HO-1, and results in renal dysfunction in a murine model of cancer.

Morphine promotes renal pathology in sickle mice.

Patients with sickle cell disease (SCD) are often treated with opioids for severe pain. Although opioids are known to have renal-specific effects, their role in nephropathy in SCD remains unknown. Because a subset of patients receives opioids for long periods of time, we examined the influence of chronic morphine treatment on mice with pre-existing renal disease expressing varying amounts of sickle hemoglobin. Morphine treatment for 3-6 weeks resulted in a variety of defects in renal morphology observed using light and electron microscopy. Notably, morphine induced glomerular pathology, resulting in increased glomerular volume, mesangial expansion, mesangial cell proliferation, parietal cell metaplasia, podocyte effacement, and microvillus transformation. Cystic tubulopathy and hemeoxygenase-1 expression and activity were also increased in morphine-treated mice. Naloxone, a non-selective opioid receptor (OR) antagonist, ameliorated these effects. Functionally, the urine albumin to creatinine ratio was increased following acute as well as chronic morphine treatment. These results suggest that clinically relevant doses of morphine induce renal pathology and that OR antagonists may be effective for ameliorating morphine-induced renal disease.

Morphine induces mesangial cell proliferation and glomerulopathy via kappa-opioid receptors.

Morphine sulfate (MS) stimulates mesangial cell (MC) proliferation, a process central to development of glomerular disease. The purpose of this study was to examine whether specific opioid receptors (OR) and signal transducer and activators of transcription 3 (STAT3) signaling are associated with MS-induced MC proliferation. C57Bl/6J and OR-specific knockout (KO) mice were treated for up to 6 wk with PBS, MS (0.7-2.14 mg/kg), naloxone (equimolar to MS), or MS+naloxone (n = 6 per group). Glomerular volume and expression of PCNA, Thy1, and ED1/CD68 were analyzed in kidney sections. Cell proliferation and STAT3 phosphorylation were analyzed by bromodeoxyuridine (BrdU) ELISA and Western blot, respectively, in MCs in vitro. MS treatment led to enlarged kidneys and glomerulopathy and naloxone reversed these effects. MS treatment increased glomerular volume in both mu-OR (MOR) KO and delta-OR (DOR) KO mice, but not in kappa-OR (KOR) KO mice. To ascertain that MS-induced glomerulopathy in vivo was due to MC proliferation, we further examined the OR-specific effects of MS in MCs in vitro. MS-induced MC proliferation in vitro was inhibited by KOR-specific nor-BNI, but not by DOR or MOR-specific antagonists naltrindol or CTOP, respectively. KOR-specific agonist U50488H stimulated proliferation of MCs, but DOR-specific agonist DPDPE and MOR-specific agonist DAMGO did not. MS failed to stimulate proliferation of MCs from KOR KO mice. MS and KOR agonists induced STAT3 phosphorylation, and STAT3 inhibitor blocked KOR agonist-induced MC proliferation. We show that MS stimulates glomerulopathy and MC proliferation via KOR and STAT3 signaling.

Renal effects of opioid exposure: considerations for therapeutic use.

In recent years, the discovery of peripheral opioid receptors has challenged the dogma of opioids interacting exclusively with the central nervous system. In this article, we describe the current understanding of the roles of opioids and opioid receptors in renal physiology and pathophysiology. The renal response to opioid exposure varies depending upon the specific opioid agonist, dose, and duration of exposure. The known acute effects of opioids on the kidney impact salt and water balance. The chronic effects of opioid exposure on kidney function are largely unknown, but collapsing glomerulopathy has been associated with chronic heroin abuse. Opioid exposure can lead to both physiological and architectural renal changes, and this may have important clinical implications. Since opioids are often used for pain management in patients with existing kidney disease, their role in kidney function warrants attention.