Ethanol pretreatment of glutaraldehyde cross-linked porcine aortic valve bioprostheses represents a highly efficacious and mechanistically based approach and may prevent calcific bioprosthetic heart valve failure.
The release profile of chlorhexidine from the PerioChip (Chip), a biodegradable local delivery system that contains 2.5 mg of chlorhexidine gluconate (CHX) in a cross-linked hydrolyzed gelatin matrix, into the gingival crevice, was evaluated in an in vivo, open label, single-center, 10-day pharmacokinetic study conducted on 19 volunteers with chronic adult periodontitis. Each volunteer had a single chip inserted into each of 4 selected pockets, with probing pocket depths of between 5-8 mm, at time 0. Gingival crevicular fluid (GCF) samples were collected using filter paper strips prior to Chip placement and at 2 h, 4 h, 24 h and 2, 3, 4, 5, 6, 8, and 9 days post-Chip placement. The GCF volume was measured using a calibrated Periotron 6000. Blood samples were collected at times 0, 1, 4, 8, 12 h and 5 days post-dosing. Urine was collected as a total 24-h specimen immediately post-dosing and 2 single samples at time 0, prior to dosing, and 5 days. The CHX was eluted from the paper strips and the CHX levels in GCF, blood and urine quantified using HPLC. The results indicate an initial peak concentration of CHX in the GCF at 2 h post-Chip insertion (2007 microg/ml) with slightly lower concentrations of between 1300-1900 microg/ml being maintained over the next 96 h. The CHX concentration then progressively decreased until study conclusion with significant CHX concentrations (mean=57 microg/ml) still being detectable at study termination. CHX was not detectable in any of the plasma or urine samples at any time point during the study. These results indicate that the PerioChip can maintain clinically effective levels of CHX in the GCF of periodontal pockets for over 1 week with no detectable systemic absorption.
Clinical usage of bioprosthetic heart valves (BPHVs) fabricated from glutaraldehyde-pretreated porcine aortic valves is restricted due to calcification-related failure. We previously reported a highly efficacious ethanol pretreatment of BPHVs for the prevention of cuspal calcification. The aim of the present study is to extend our understanding of the material changes brought about by ethanol and the relationship of these material effects to the ethanol pretreatment anticalcification mechanism. Glutaraldehyde-crosslinked porcine aortic valve cusps (control and ethanol-pretreated) were studied for the effects of ethanol on tissue water content and for spin-lattice relaxation times (T1) using solid state proton NMR. Cusp samples were studied for protein conformational changes due to ethanol by ATR-FTIR spectroscopy. The changes in cuspal tissue-cholesterol (in vitro) interactions also were studied. Cusp material stability was assessed in terms of residual glutaraldehyde content and collagenase degradation. Water content of the cusp samples was decreased significantly due to ethanol pretreatment. The cuspal collagen conformational changes (per infrared spectroscopy) brought about by ethanol pretreatment were persistent even after rat subdermal implantation of cusp samples for 7 days. In vitro cholesterol uptake by cusps was greatly reduced as a result of ethanol pretreatment. Ethanol pretreatment of cusps also resulted in increased resistance to collagenase digestion. Cuspal glutaraldehyde content was not changed by ethanol pretreatment. We conclude that ethanol pretreatment of bioprosthetic heart valve cusps causes multi-component effects on the tissue/material and macromolecular characteristics, which partly may explain the ethanol-pretreatment anticalcification mechanism.
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