Renal Embolization-Induced Uremic Swine Model for Assessment of Next-Generation Implantable Hemodialyzers

Moyer, Jarrett; Wilson, Mark W.; Sorrentino, Thomas A.; Santandreu, Ana; Chen, Caressa; Hu, Dean; Kerdok, Amy; Porock, Edward; Wright, Nathan; Ly, Jimmy; Blaha, Charles; Frassetto, Lynda A.; Fissell, William H.; Vartanian, Shant M.; Roy, Shuvo

doi:10.3390/toxins15090547

Toxins

2023

DOI: 10.3390/toxins15090547

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Renal Embolization-Induced Uremic Swine Model for Assessment of Next-Generation Implantable Hemodialyzers

Jarrett Moyer,

Mark W. Wilson,

Thomas A. Sorrentino

et al.

Abstract: Reliable models of renal failure in large animals are critical to the successful translation of the next generation of renal replacement therapies (RRT) into humans. While models exist for the induction of renal failure, none are optimized for the implantation of devices to the retroperitoneal vasculature. We successfully piloted an embolization-to-implantation protocol enabling the first implant of a silicon nanopore membrane hemodialyzer (SNMHD) in a swine renal failure model. Renal arterial embolization is … Show more

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2024

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Cited by 2 publications

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Transportable, portable, wearable and (partially) implantable haemodialysis systems: comparison of technologies and readiness levels

Wieringa,

Bolhuis,

Søndergaard

et al. 2024

Clinical Kidney Journal

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Background Dialysis modalities and their various treatment schedules result from complex compromises (‘trade-offs’) between medical, financial, technological, ergonomic, and ecological factors. This study targets summarizing the mutual influence of these trade-offs on (trans)portable, wearable, or even (partially) implantable haemodialysis (HD) systems, identify what systems are in development, and how they might improve quality of life (QoL) for patients with kidney failure. Methods HD as defined by international standard IEC 60601–2-16 was applied on a PUBMED database query regarding (trans)portable, wearable, and (partly) implantable HD systems. Out of 159 search results, 24 were included and scanned for specific HD devices and/or HD systems in development. Additional information about weight, size, and development status was collected by the internet and/or contacting manufacturers. International airplane hand baggage criteria formed the boundary between transportable and portable. Technology readiness levels (TRLs) were assigned by combining TRL scales from the European Union and NATO medical staff. Results The query revealed 13 devices/projects: seven transportable (six TRL9, one TRL5); two portable (one TRL6–7, one TRL4); two wearable (one TRL6, one frozen); and two partly implantable (one TRL4–5, one TRL2–3). Discussion Three main categories of technical approaches were distinguished: single-pass, dialysate regenerating, and implantable HD filter with extracorporeal dialysate regeneration (in climbing order of mobility). Conclusions Kidneys facilitate mobility by excreting strongly concentrated waste solutes with minimal water loss. Mimicking this kidney function can increase HD system mobility. Dialysate-regenerating HD systems are enablers for portability/wearability and, combined with durable implantable HD filters (once available), they may enable HD without needles or intravascular catheters. However, lack of funding severely hampers progress.

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Transportable, portable, wearable and (partially) implantable haemodialysis systems: comparison of technologies and readiness levels

Wieringa,

Bolhuis,

Søndergaard

et al. 2024

Clinical Kidney Journal

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Future of Uremic Toxin Management

Vanholder,

Snauwaert,

Verbeke

et al. 2024

Toxins

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During the progression of chronic kidney disease (CKD), the retention of uremic toxins plays a key role in the development of uremic syndrome. Knowledge about the nature and biological impact of uremic toxins has grown exponentially over the past decades. However, the science on reducing the concentration and effects of uremic toxins has not advanced in parallel. Additionally, the focus has remained for too long on dialysis strategies, which only benefit the small fraction of people with CKD who suffer from advanced kidney disease, whereas uremic toxicity effects are only partially prevented. This article reviews recent research on alternative methods to counteract uremic toxicity, emphasizing options that are also beneficial in the earlier stages of CKD, with a focus on both established methods and approaches which are still under investigation or at the experimental stage. We will consequently discuss the preservation of kidney function, the prevention of cardiovascular damage, gastro-intestinal interventions, including diet and biotics, and pharmacologic interventions. In the final part, we also review alternative options for extracorporeal uremic toxin removal. The future will reveal which of these options are valid for further development and evidence-based assessment, hopefully leading to a more sustainable treatment model for CKD than the current one.

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Renal Embolization-Induced Uremic Swine Model for Assessment of Next-Generation Implantable Hemodialyzers

Cited by 2 publications

References 46 publications

Transportable, portable, wearable and (partially) implantable haemodialysis systems: comparison of technologies and readiness levels

Transportable, portable, wearable and (partially) implantable haemodialysis systems: comparison of technologies and readiness levels

Future of Uremic Toxin Management

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