American Society of Hirudotherapy

Dialdehyde pectin-crosslinked and hirudin-loaded decellularized porcine pericardium with improved matrix stability, enhanced anti-calcification and anticoagulant for bioprosthetic heart valves

Research article published in Biomaterials science (2021)

Last Updated: June 18, 2026Reviewed by: ASH Editorial Board
Research article — evidence reviewArticle reference
Evidence: Preclinical (animal)Clinical TrialsHu et al. · Biomaterials science, 2021

Abstract

To conveniently and effectively cure heart valve diseases or defects, combined with transcatheter valve technology, bioprosthetic heart valves (BHVs) originated from the decellularized porcine pericardium (D-PP) have been broadly used in clinics. Unfortunately, most clinically available BHVs crosslinked with glutaraldehyde (GA) were challenged in their long-term tolerance, degenerative structural changes, and even failure, owing to the synergistic impact of multitudinous elements (cytotoxicity, calcification, immune responses, etc.). In this work, dialdehyde pectin (AP) was prepared by oxidizing the o-dihydroxy of pectin with sodium periodate. Hereafter, the AP-fixed PP model was obtained by crosslinking D-PP with AP with high aldehyde content (6.85 mmol g-1), for acquiring excellent mechanical properties and outstanding biocompatibility. To further improve the hemocompatibility of the AP-fixed PP, a natural and specific inhibitor of thrombin (hirudin) was introduced to achieve surface modification of the AP-fixed PP. The feasibility of crosslinking and functionalizing AP-fixed PP, which was a potential leaflet material of BHVs, was exhaustively and systematically evaluated. In vitro studies found that hirudin-loaded and AP-fixed PP (AP + Hirudin-PP) had synchronously achieved effective fixation of collagen, highly effective anticoagulation, and good HUVECs-cytocompatibility. In vivo results revealed that the AP + Hirudin-PP specimens recruited the minimum immune cells in the implantation experiment, and also presented an excellent anti-calcification effect. Overall, AP + Hirudin-PP was endowed with competitive collagen stability (compared with GA-fixed PP), excellent hemocompatibility, good HUVECs-cytocompatibility, low immunogenicity and outstanding anti-calcification, suggesting that AP + Hirudin-PP might be a promising alternative to GA-fixed PP and exhibited a bright prospect in the clinical applications of BHVs.

Abstract sourced from PubMed (NCBI) for the cited record. See the original publication for the authoritative version.

Publication typeJournal Article
Indexed MeSH termsAnimalsAnticoagulantsBioprosthesisGlutaralHeart Valve ProsthesisHeart ValvesHirudinsPectinsPericardiumSwine

Summary

Peer-reviewed clinical and outcomes research relevant to medicinal leech therapy and its biology. Indexed in PubMed and verified against the NCBI record.

Why This Matters for Hirudotherapy

This study engineered a decellularized porcine pericardium for bioprosthetic heart valves, crosslinking it with dialdehyde pectin and loading the leech-derived thrombin inhibitor hirudin onto its surface; in vitro the hirudin-modified material achieved effective anticoagulation and good cell compatibility, and in vivo (animal implantation) it recruited minimal immune cells and showed strong anti-calcification. It is a concrete example of the medicinal-leech secretome drug-discovery story, demonstrating that hirudin, the prototypical leech anticoagulant, can be repurposed as a surface coating to confer hemocompatibility on an implantable device. Caveat: this is preclinical work (laboratory assays plus an animal model), not a human clinical trial, and it uses isolated/recombinant hirudin as a biomaterial functionalization rather than live leech therapy; the durability and clinical performance of the coated valve in patients are not established here.

Citation

Dialdehyde pectin-crosslinked and hirudin-loaded decellularized porcine pericardium with improved matrix stability, enhanced anti-calcification and anticoagulant for bioprosthetic heart valves.

Hu et al. · Biomaterials science, 2021

Added to ASH library: May 28, 2026 · Site last updated: June 18, 2026

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