TY - JOUR
T1 - Assembly of Interfacial Polyelectrolyte Complexation Fibers with Mineralization Gradient for Physiologically-Inspired Ligament Regeneration
AU - Liu, Yu Chung
AU - Chen, Shih Heng
AU - Kuan, Chen Hsiang
AU - Chen, Shih Hsien
AU - Huang, Wei Yuan
AU - Chen, Hao Xuan
AU - Wang, Tzu Wei
N1 - © 2024 Wiley‐VCH GmbH.
PY - 2024/6/20
Y1 - 2024/6/20
N2 - Current synthetic grafts for ligament rupture repair often fail to integrate well with the surrounding biological tissue, leading to complications such as graft wear, fatigue, and subsequent re-rupture. To address this medical challenge, this study aims at advancing the development of a biological ligament through the integration of physiologically-inspired principles and tissue engineering strategies. In this study, interfacial polyelectrolyte complexation (IPC) spinning technique, along with a custom-designed collection system, to fabricate a hierarchical scaffold mimicking native ligament structure, is utilized. To emulate the bone-ligament interface and alleviate stress concentration, a hydroxyapatite (HAp) mineral gradient is strategically introduced near both ends of the scaffold to enhance interface integration and diminish the risk of avulsion rupture. Biomimetic viscoelasticity is successfully displayed to provide similar mechanical support to native ligamentous tissue under physiological conditions. By introducing the connective tissue growth factor (CTGF) and conducting mesenchymal stem cells transplantation, the regenerative potential of the synthetic ligament is significantly amplified. This pioneering study offers a multifaceted solution combining biomimetic materials, regenerative therapies, and advanced techniques to potentially transform ligament rupture treatment.
AB - Current synthetic grafts for ligament rupture repair often fail to integrate well with the surrounding biological tissue, leading to complications such as graft wear, fatigue, and subsequent re-rupture. To address this medical challenge, this study aims at advancing the development of a biological ligament through the integration of physiologically-inspired principles and tissue engineering strategies. In this study, interfacial polyelectrolyte complexation (IPC) spinning technique, along with a custom-designed collection system, to fabricate a hierarchical scaffold mimicking native ligament structure, is utilized. To emulate the bone-ligament interface and alleviate stress concentration, a hydroxyapatite (HAp) mineral gradient is strategically introduced near both ends of the scaffold to enhance interface integration and diminish the risk of avulsion rupture. Biomimetic viscoelasticity is successfully displayed to provide similar mechanical support to native ligamentous tissue under physiological conditions. By introducing the connective tissue growth factor (CTGF) and conducting mesenchymal stem cells transplantation, the regenerative potential of the synthetic ligament is significantly amplified. This pioneering study offers a multifaceted solution combining biomimetic materials, regenerative therapies, and advanced techniques to potentially transform ligament rupture treatment.
KW - bone-ligament interface
KW - hierarchical structure
KW - interfacial polyelectrolyte complexation
KW - ligament tissue engineering
KW - mineralization gradient
KW - Tissue Engineering/methods
KW - Humans
KW - Ligaments/chemistry
KW - Mesenchymal Stem Cells/cytology
KW - Regeneration
KW - Biomimetic Materials/chemistry
KW - Animals
KW - Durapatite/chemistry
KW - Tissue Scaffolds/chemistry
KW - Polyelectrolytes/chemistry
UR - http://www.scopus.com/inward/record.url?scp=85189965789&partnerID=8YFLogxK
U2 - 10.1002/adma.202314294
DO - 10.1002/adma.202314294
M3 - 文章
C2 - 38572797
AN - SCOPUS:85189965789
SN - 0935-9648
VL - 36
SP - e2314294
JO - Advanced Materials
JF - Advanced Materials
IS - 25
M1 - 2314294
ER -