Biopolymers and polymers in the search of alternative treatments for meniscal regeneration: State of the art and future trends

Caroline A. Murphy; João B. Costa; Joana Silva-Correia; J. Miguel Oliveira; Rui L. Reis; Maurice N. Collins

doi:10.1016/j.apmt.2018.04.002

Biopolymers and polymers in the search of alternative treatments for meniscal regeneration: State of the art and future trends

Caroline A. Murphy, João B. Costa, Joana Silva-Correia, J. Miguel Oliveira, Rui L. Reis, Maurice N. Collins

School of Engineering

Research output: Contribution to journal › Review article › peer-review

Abstract

This review focuses on the meniscus and the biomaterials involved in meniscal repair and regeneration. Clinical issues associated with the meniscus are introduced and treatment strategies are discussed in terms of biomaterial choice: extracellular matrix materials (ECM), natural materials (ECM-like), synthetic or hybrids of these. These material choices lead to a myriad of options ranging from permanent implants to biodegradable scaffolds (with and without cells, binding ligands and growth factors). The latest chemistries behind emerging candidate materials are discussed in terms of functional modifications, crosslinking agents and techniques. Finally, we review the latest and promising advances associated with bioprinted meniscal implants and the drive toward more functional bioinks with the overall goal of achieving a patient-specific meniscal implant.

Original language	English
Pages (from-to)	51-71
Number of pages	21
Journal	Applied Materials Today
Volume	12
DOIs	https://doi.org/10.1016/j.apmt.2018.04.002
Publication status	Published - Sep 2018

Keywords

Bioprinting
Meniscus
Regenerative Medicine
Tissue Engineering

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10.1016/j.apmt.2018.04.002

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title = "Biopolymers and polymers in the search of alternative treatments for meniscal regeneration: State of the art and future trends",

abstract = "This review focuses on the meniscus and the biomaterials involved in meniscal repair and regeneration. Clinical issues associated with the meniscus are introduced and treatment strategies are discussed in terms of biomaterial choice: extracellular matrix materials (ECM), natural materials (ECM-like), synthetic or hybrids of these. These material choices lead to a myriad of options ranging from permanent implants to biodegradable scaffolds (with and without cells, binding ligands and growth factors). The latest chemistries behind emerging candidate materials are discussed in terms of functional modifications, crosslinking agents and techniques. Finally, we review the latest and promising advances associated with bioprinted meniscal implants and the drive toward more functional bioinks with the overall goal of achieving a patient-specific meniscal implant.",

keywords = "Bioprinting, Meniscus, Regenerative Medicine, Tissue Engineering",

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doi = "10.1016/j.apmt.2018.04.002",

language = "English",

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T2 - State of the art and future trends

AU - Murphy, Caroline A.

AU - Costa, João B.

AU - Silva-Correia, Joana

AU - Oliveira, J. Miguel

AU - Reis, Rui L.

AU - Collins, Maurice N.

PY - 2018/9

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AB - This review focuses on the meniscus and the biomaterials involved in meniscal repair and regeneration. Clinical issues associated with the meniscus are introduced and treatment strategies are discussed in terms of biomaterial choice: extracellular matrix materials (ECM), natural materials (ECM-like), synthetic or hybrids of these. These material choices lead to a myriad of options ranging from permanent implants to biodegradable scaffolds (with and without cells, binding ligands and growth factors). The latest chemistries behind emerging candidate materials are discussed in terms of functional modifications, crosslinking agents and techniques. Finally, we review the latest and promising advances associated with bioprinted meniscal implants and the drive toward more functional bioinks with the overall goal of achieving a patient-specific meniscal implant.

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KW - Regenerative Medicine

KW - Tissue Engineering

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DO - 10.1016/j.apmt.2018.04.002

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EP - 71

JO - Applied Materials Today

JF - Applied Materials Today

ER -

Biopolymers and polymers in the search of alternative treatments for meniscal regeneration: State of the art and future trends

Abstract

Keywords

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