Bioartificial Kidney Ameliorates Gram-Negative Bacteria-Induced Septic Shock in Uremic Animals

Fissell, William H.; Lou, Liandi; Abrishami, Simin; Buffington, Deborah A.; Humes, H. David

doi:10.1097/01.asn.0000045046.94575.96

Cited by 94 publications

(67 citation statements)

References 47 publications

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“…In vitro and ex vivo tests of renal assist devices have been conducted of animals and critically ill patients, with promising results that include better cardiovascular and hemodynamic parameters and improved survival (18 -20). Of particular interest is the potential differential beneficial effect in patients with acute kidney injury associated with sepsis (21)(22)(23)(24)(25).…”

Section: Living Membranes and Bioartificial Kidneymentioning

confidence: 99%

Technological Advances in Renal Replacement Therapy

Rastogi

Nissenson²

2009

Clinical Journal of the American Society of Nephrology

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The worldwide epidemic of chronic kidney disease shows no signs of abating in the near future. Current dialysis forms of renal replacement therapy (RRT), even though successful in sustaining life and improving quality of life somewhat for patients with ESRD, have many limitations that result in still unacceptably high morbidity and mortality. Transplantation is an excellent option but is limited by the scarcity of organs. An ideal form of RRT would mimic the functions of natural kidneys and be transparent to the patient, as well as affordable to society. Recent advances in technology, although generally in early stages of development, might achieve these goals. The application of nanotechnology, microfluidics, bioreactors with kidney cells, and miniaturized sorbent systems to regenerate dialysate makes clinical reality seem closer than ever before. Finally, stem cells hold much promise, both for kidney disease and as a source of tissues and organs. In summary, nephrology is at an exciting crossroad with the application of innovative and novel technologies to RRT that hold considerable promise for the near future.Clin J Am Soc Nephrol 4: S132-S136, 2009. doi: 10.2215/CJN.02860409 T he ongoing worldwide epidemic of chronic kidney disease (CKD) includes ESRD. According to recent US Renal Data System estimates, more than 900,000 patients worldwide have ESRD and are on renal replacement therapy (RRT) (1). The majority of these patients are on intermittent, diffusion-based hemodialysis (HD), with only a relatively small fraction able to receive kidney transplants because of the scarcity of available donor organs.Even though dialysis is touted as the only currently available successful therapy that replaces the functions of an organ ex vivo, it has several limitations. The advent of clinical dialysis in the 1950s has had a huge impact on the way in which ESRD and acute kidney failure are managed, but several decades later, the morbidity and mortality in patients with ESRD remain unacceptably high (1). One possible reason is that the equivalent clearance provided by three-times-a-week conventional HD or typical continuous ambulatory peritoneal dialysis (PD) is barely 15 to 20 ml/min, and the treatment by any criterion is unphysiologic (2). At the same time, the quality of life of patients who are on dialysis has remained suboptimal, and the cost of these procedures has remained high.Several attempts have been made to prove intramuscularly the efficiency of dialysis and outcomes in patients. In HD, these attempts include more biocompatible membranes, high-flux and high-efficiency membranes, more frequent and longer duration of dialysis, use of convective forms of therapy, and use of more user-friendly delivery systems. In PD, introduction of automated cyclers has improved convenience of the technique for some patients, increased the practical volume of dialysate, and, therefore, increased solute clearance and ultrafiltration capacity; however, none of these advances has had a substantial impact on patient outcomes.An ide...

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Section: Living Membranes and Bioartificial Kidneymentioning

confidence: 99%

Technological Advances in Renal Replacement Therapy

Rastogi

Nissenson²

2009

Clinical Journal of the American Society of Nephrology

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“…A series of additional animal experiments investigated the impact of treatment with this device on the high mortality of sepsis complicated by AKI. Studies in both dogs and pigs have demonstrated that RAD treatment in a bioartificial kidney circuit improves cardiovascular performance associated with changes in cytokine profiles and confers a significant survival advantage in septic or endotoxin animal models [13,14,15]. …”

Section: Preclinical Studies Of Bioartificial Kidneymentioning

confidence: 99%

The Bioartificial Kidney and Bioengineered Membranes in Acute Kidney Injury

Ding¹,

Humes²

2008

Nephron Exp Nephrol

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The treatment of severe acute kidney injury (AKI) with dialysis or hemofiltration remains suboptimal with high levels of morbidity and mortality. Current renal replacement therapies substitute for the small solute clearance function of the kidney but do not replace the lost reclamation, metabolic and endocrine functions of this organ. Cell therapy and tissue engineering offer hope of fuller replacement of kidney function in renal failure patients. A renal tubule assist device (RAD) that includes a conventional hemodialysis filter and a bioreactor containing living renal proximal tubule cells has been successfully engineered. Differentiated activity of these cells and survival advantages have been demonstrated in large-animal models of sepsis and AKI. Data from phase I/II and phase II clinical studies have shown that the addition of renal tubule cell therapy to conventional continuous renal replacement therapy (CRRT) treatment resulted in a significant clinical impact on survival, and that RAD treatment demonstrated an acceptable safety profile. Another substantive advance for the treatment of AKI will be the development of nanofabrication technology to further improve the clearance function of the kidney to replicate glomerular permselectivity while retaining high rates of hydraulic permeability. New developments in this translational research area will improve the unmet medical needs of patients with renal failure.

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“…In terms of augmentation of traditional hemodialysis, a "renal assist device," which is composed of a membrane coated with cultured porcine proximal tubule cells, has been developed (14,15). These cells support unidirectional transport, and when added in series to a traditional hemofiltration circuit, the resultant bioartificial kidney appears to significantly improve outcomes of acutely uremic dogs in models of endotoxin-mediated sepsis (10). Human trials are in progress.…”

Section: Cell-based Strategiesmentioning

confidence: 99%

Developmental approaches to kidney tissue engineering

Steer

Nigám

2004

American Journal of Physiology-Renal Physiology

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Recent advances in our understanding of the developmental biology of the kidney, as well as the establishment of novel in vitro model systems, have potential implications for kidney tissue engineering. These advances include delineation of the roles of a number of growth factors in the developmental programs of branching morphogenesis and mesenchymal differentiation, a new understanding of the roles of the extracellular matrix, identification of potential “renal” stem cells, the ex vivo propagation and subsequent recombination of isolated components of the kidney, and successful transplantation of renal primordia into adult hosts. This review will examine these advances in the context of approaches to tissue engineering. Finally, novel approaches that synthesize advances in both cell-based and organ-based approaches are proposed.

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Bioartificial Kidney Ameliorates Gram-Negative Bacteria-Induced Septic Shock in Uremic Animals

Cited by 94 publications

References 47 publications

Technological Advances in Renal Replacement Therapy

Technological Advances in Renal Replacement Therapy

The Bioartificial Kidney and Bioengineered Membranes in Acute Kidney Injury

Developmental approaches to kidney tissue engineering

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