Self-Assembled Gels for Biomedical Applications

Natural and synthetic gel‐like materials have featured heavily in the development of biomaterials for wound healing and other tissue‐engineering purposes. More recently, molecular gels have been designed and tailored for the same purpose. When mixed with, or conjugated to therapeutic drugs or bioact...

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Veröffentlicht in:Chemistry, an Asian journal Jg. 6; H. 1; S. 30 - 42
Hauptverfasser: Truong, Warren Ty, Su, Yingying, Meijer, Joris T., Thordarson, Pall, Braet, Filip
Format: Journal Article
Sprache:Englisch
Veröffentlicht: Weinheim WILEY-VCH Verlag 03.01.2011
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Schlagworte:
Amino Acid Sequence
Biocompatible Materials - chemistry
biomaterials
Biomedical materials
Chemistry
Chemistry, Pharmaceutical
gels
Gels - chemistry
medicinal chemistry
Models, Biological
Molecular Sequence Data
self-assembly
sol-gel processes
Tissue Engineering
Wound Healing
ISSN:1861-4728, 1861-471X, 1861-471X
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Abstract Natural and synthetic gel‐like materials have featured heavily in the development of biomaterials for wound healing and other tissue‐engineering purposes. More recently, molecular gels have been designed and tailored for the same purpose. When mixed with, or conjugated to therapeutic drugs or bioactive molecules, these materials hold great promise for treating/curing life‐threatening and degenerative diseases, such as cancer, osteoarthritis, and neural injuries. This focus review explores the latest advances in this field and concentrates on self‐assembled gels formed under aqueous conditions (i.e., self‐assembled hydrogels), and critically compares their performance within different biomedical applications, including three‐dimensional cell‐culture studies, drug delivery, and tissue engineering. Although stability and toxicity issues still need to be addressed in more detail, it is clear from the work reviewed here that self‐assembled gels have a bright future as novel biomaterials. Self‐assembled medicine! Emerging medical applications of self‐assembled gels (see picture) based on interactions between these materials with cells and tissues, such as drug delivery, 3D cell cultures, and tissue engineering, are discussed.
AbstractList Natural and synthetic gel-like materials have featured heavily in the development of biomaterials for wound healing and other tissue-engineering purposes. More recently, molecular gels have been designed and tailored for the same purpose. When mixed with, or conjugated to therapeutic drugs or bioactive molecules, these materials hold great promise for treating/curing life-threatening and degenerative diseases, such as cancer, osteoarthritis, and neural injuries. This focus review explores the latest advances in this field and concentrates on self-assembled gels formed under aqueous conditions (i.e., self-assembled hydrogels), and critically compares their performance within different biomedical applications, including three-dimensional cell-culture studies, drug delivery, and tissue engineering. Although stability and toxicity issues still need to be addressed in more detail, it is clear from the work reviewed here that self-assembled gels have a bright future as novel biomaterials. [PUBLICATION ABSTRACT]
Natural and synthetic gel-like materials have featured heavily in the development of biomaterials for wound healing and other tissue-engineering purposes. More recently, molecular gels have been designed and tailored for the same purpose. When mixed with, or conjugated to therapeutic drugs or bioactive molecules, these materials hold great promise for treating/curing life-threatening and degenerative diseases, such as cancer, osteoarthritis, and neural injuries. This focus review explores the latest advances in this field and concentrates on self-assembled gels formed under aqueous conditions (i.e., self-assembled hydrogels), and critically compares their performance within different biomedical applications, including three-dimensional cell-culture studies, drug delivery, and tissue engineering. Although stability and toxicity issues still need to be addressed in more detail, it is clear from the work reviewed here that self-assembled gels have a bright future as novel biomaterials.Natural and synthetic gel-like materials have featured heavily in the development of biomaterials for wound healing and other tissue-engineering purposes. More recently, molecular gels have been designed and tailored for the same purpose. When mixed with, or conjugated to therapeutic drugs or bioactive molecules, these materials hold great promise for treating/curing life-threatening and degenerative diseases, such as cancer, osteoarthritis, and neural injuries. This focus review explores the latest advances in this field and concentrates on self-assembled gels formed under aqueous conditions (i.e., self-assembled hydrogels), and critically compares their performance within different biomedical applications, including three-dimensional cell-culture studies, drug delivery, and tissue engineering. Although stability and toxicity issues still need to be addressed in more detail, it is clear from the work reviewed here that self-assembled gels have a bright future as novel biomaterials.
Natural and synthetic gel‐like materials have featured heavily in the development of biomaterials for wound healing and other tissue‐engineering purposes. More recently, molecular gels have been designed and tailored for the same purpose. When mixed with, or conjugated to therapeutic drugs or bioactive molecules, these materials hold great promise for treating/curing life‐threatening and degenerative diseases, such as cancer, osteoarthritis, and neural injuries. This focus review explores the latest advances in this field and concentrates on self‐assembled gels formed under aqueous conditions (i.e., self‐assembled hydrogels), and critically compares their performance within different biomedical applications, including three‐dimensional cell‐culture studies, drug delivery, and tissue engineering. Although stability and toxicity issues still need to be addressed in more detail, it is clear from the work reviewed here that self‐assembled gels have a bright future as novel biomaterials. magnified image
Natural and synthetic gel‐like materials have featured heavily in the development of biomaterials for wound healing and other tissue‐engineering purposes. More recently, molecular gels have been designed and tailored for the same purpose. When mixed with, or conjugated to therapeutic drugs or bioactive molecules, these materials hold great promise for treating/curing life‐threatening and degenerative diseases, such as cancer, osteoarthritis, and neural injuries. This focus review explores the latest advances in this field and concentrates on self‐assembled gels formed under aqueous conditions (i.e., self‐assembled hydrogels), and critically compares their performance within different biomedical applications, including three‐dimensional cell‐culture studies, drug delivery, and tissue engineering. Although stability and toxicity issues still need to be addressed in more detail, it is clear from the work reviewed here that self‐assembled gels have a bright future as novel biomaterials. Self‐assembled medicine! Emerging medical applications of self‐assembled gels (see picture) based on interactions between these materials with cells and tissues, such as drug delivery, 3D cell cultures, and tissue engineering, are discussed.
Natural and synthetic gel-like materials have featured heavily in the development of biomaterials for wound healing and other tissue-engineering purposes. More recently, molecular gels have been designed and tailored for the same purpose. When mixed with, or conjugated to therapeutic drugs or bioactive molecules, these materials hold great promise for treating/curing life-threatening and degenerative diseases, such as cancer, osteoarthritis, and neural injuries. This focus review explores the latest advances in this field and concentrates on self-assembled gels formed under aqueous conditions (i.e., self-assembled hydrogels), and critically compares their performance within different biomedical applications, including three-dimensional cell-culture studies, drug delivery, and tissue engineering. Although stability and toxicity issues still need to be addressed in more detail, it is clear from the work reviewed here that self-assembled gels have a bright future as novel biomaterials.
Author Su, Yingying
Braet, Filip
Truong, Warren Ty
Thordarson, Pall
Meijer, Joris T.
Author_xml – sequence: 1
  givenname: Warren Ty
  surname: Truong
  fullname: Truong, Warren Ty
  organization: School of Chemistry, The University of New South Wales, NSW 2052 (Australia)
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  surname: Meijer
  fullname: Meijer, Joris T.
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  surname: Thordarson
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  givenname: Filip
  surname: Braet
  fullname: Braet, Filip
  organization: Australian Key Centre for Microscopy and Microanalysis, The University to Sydney, NSW 2006 (Australia), Fax: (+61) 2-9351-7682
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2010; 10
2009; 47
2001; 101
1987; 3
2010; 15
1997; 273
2006; 39
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2004; 3
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2008; 3
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2010; 28
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1999; 99
2007; 7
1994; 35
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2008; 14
1996
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2005
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2006; 2
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2002; 69
2007; 316
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2004; 50
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2002; 20
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2002; 124
2009; 462
2010; 132
2008; 47
1997; 39
1999; 77
2009; 8
2009; 6
2008; 41
2009; 5
2007 2007; 119 46
2010; 92
2005; 16
2003; 300
1973; 7
2008 2008; 120 47
2009; 38
2005; 11
2009; 103
2003; 21
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Snippet Natural and synthetic gel‐like materials have featured heavily in the development of biomaterials for wound healing and other tissue‐engineering purposes. More...
Natural and synthetic gel-like materials have featured heavily in the development of biomaterials for wound healing and other tissue-engineering purposes. More...
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SubjectTerms Amino Acid Sequence
Biocompatible Materials - chemistry
biomaterials
Biomedical materials
Chemistry
Chemistry, Pharmaceutical
gels
Gels - chemistry
medicinal chemistry
Models, Biological
Molecular Sequence Data
self-assembly
sol-gel processes
Tissue Engineering
Wound Healing
Title Self-Assembled Gels for Biomedical Applications
URI https://api.istex.fr/ark:/67375/WNG-GVR6GPQF-1/fulltext.pdf
https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fasia.201000592
https://www.ncbi.nlm.nih.gov/pubmed/21077096
https://www.proquest.com/docview/1517127371
https://www.proquest.com/docview/821597251
Volume 6
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