In vitro Clearance and Hemocompatibility Assessment of Ultrathin Nanoporous Silicon Membranes for Hemodialysis Applications Using Human Whole Blood

Ahmadi, Morteza; Gorbet, Maud; Yeow, John T. W.

doi:10.1159/000350613

Cited by 9 publications

(5 citation statements)

References 60 publications

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“…These devices could be applied in the body e.g. engineered tissues or out of the body which are in contact with blood such as dialysis apparatuses, artificial cardiovascular machines and blood bags [1][2][3]. There are varieties of biomaterials to apply in medical devices with different pros and cons [4].…”

Section: Introductionmentioning

confidence: 99%

Extract of fetal membrane would inhibit thrombosis and hemolysis

2015

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Section: Introductionmentioning

confidence: 99%

Extract of fetal membrane would inhibit thrombosis and hemolysis

2015

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“…13 Here we demonstrated the mechanical robustness of SNM by showing that the membranes can consistently withstand pressures beyond 775.7 mmHg, which is well beyond any physiologic pressure encountered clinically. Of note, four out of eleven membranes failed before reaching the system maximum 1448 mmHg indicating mechanical differences at these extreme pressures.…”

Section: Discussionmentioning

confidence: 63%

“…used flat MEMS based ultrathin porous nanocrystalline silicon membranes from SiMPore (N.Y. USA) to investigate in vitro clearance of small molecules and hemocompatibility using a single parallel plate configuration. 13, 14 These flat membranes had average circular pore sizes of 5 and 20nm with a membrane thickness of 30 nm. They were able to show clearance of small solutes over a total membrane area of 3 mm 2 .…”

Section: Introductionmentioning

confidence: 99%

Preliminary Diffusive Clearance of Silicon Nanopore Membranes in a Parallel Plate Configuration for Renal Replacement Therapy

et al. 2016

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Silicon nanopore membranes (SNM) with compact geometry and uniform pore size distribution have demonstrated a remarkable capacity for hemofiltration. These advantages could potentially be used for hemodialysis. Here we present an initial evaluation of the SNM’s mechanical robustness, diffusive clearance, and hemocompatibility in a parallel plate configuration. Mechanical robustness of the SNM was demonstrated by exposing membranes to high flows (200ml/min) and pressures (1,448mmHg). Diffusive clearance was performed in an albumin solution and whole blood with blood and dialysate flow rates of 25ml/min. Hemocompatibility was evaluated using scanning electron microscopy and immunohistochemistry after 4-hours in an extra-corporeal porcine model. The pressure drop across the flow cell was 4.6mmHg at 200ml/min. Mechanical testing showed that SNM could withstand up to 775.7mmHg without fracture. Urea clearance did not show an appreciable decline in blood versus albumin solution. Extra-corporeal studies showed blood was successfully driven via the arterial-venous pressure differential without thrombus formation. Bare silicon showed increased cell adhesion with a 4.1 fold increase and 1.8 fold increase over polyethylene-glycol (PEG)-coated surfaces for tissue plasminogen factor (t-PA) and platelet adhesion (CD-41), respectively. These initial results warrant further design and development of a fully scaled SNM-based parallel plate dialyzer for renal replacement therapy.

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“…However, since the 1970’s the filtration material has remained fundamentally the same, specifically maintaining the same basic size and form. Various research groups have been working to develop miniaturized hemodialysis devices [15–18]. The small size of these devices, with lower flow rates and reduced extracorporeal volume, preclude testing with the current HD delivery systems, especially those that involve a major change in the dialyzer format.…”

Section: Introductionmentioning

confidence: 99%

Protein Separation and Hemocompatibility of Nitride Membranes in Microfluidic Filtration Systems

Salminen

Hill

Chung

et al. 2018

2018 40th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC)

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Improving the health outcomes for end-stage renal Disease (ESRD) patients on hemodialysis (HD) requires new technologies for wearable HD such as a highly efficient membrane that can achieve standard toxic clearance rates in small device footprints. Our group has developed nanoporous silicon nitride (NPN) membranes which are 100 to 1000 times thinner than conventional membranes and are orders-of-magnitude more efficient for dialysis. Counter flow dialysis separation experiments were performed to measure urea clearance while microdialysis experiments were performed in a stirred beaker to measure the separation of cytochrome-c and albumin. Hemodialysis experiments testing for platelet activation as well as protein adhesion were performed. Devices for the counter flow experiments were constructed with polydimethylsiloxane (PDMS) and a NPN membrane chip. The counter flow devices reduced the urea by as much as 20%. The microdialysis experiments showed a diffusion of ~60% for the cytochrome-c while clearing ~20% of the Albumin. Initial hemocompatibility studies show that the NPN membrane surface is less prone to both protein adhesion and platelet activation when compared to positive control (glass).

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In vitro Clearance and Hemocompatibility Assessment of Ultrathin Nanoporous Silicon Membranes for Hemodialysis Applications Using Human Whole Blood

Cited by 9 publications

References 60 publications

Extract of fetal membrane would inhibit thrombosis and hemolysis

Extract of fetal membrane would inhibit thrombosis and hemolysis

Preliminary Diffusive Clearance of Silicon Nanopore Membranes in a Parallel Plate Configuration for Renal Replacement Therapy

Protein Separation and Hemocompatibility of Nitride Membranes in Microfluidic Filtration Systems

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