A Bilayer Engineered Skin Substitute for Wound Repair in an Irradiation-Impeded Healing Model on Rat

Hilmi, Abu Bakar Mohd; Hassan, Asma; Halim, Ahmad Sukari

doi:10.1089/wound.2014.0551

Cited by 12 publications

(6 citation statements)

References 35 publications

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“…The challenge is seeding two cell lines to create a bilayer skin substitute as there needs to be a clear division between epidermal and dermal layers. After culturing scaffolds with adhered dermal cells, it is possible to seed epidermal cells dropwise on to one surface of the scaffold[214] or by placing the cellularized scaffold on to a surface previously adhered with keratinocytes[206]. Both of these techniques may create a bilayer scaffold, but one significant component is missing, the basement membrane.…”

Section: Creating Skin Substitutesmentioning

confidence: 99%

Methodologies in creating skin substitutes

Nicholas

Jeschke

Amini-Nik

2016

Cell. Mol. Life Sci.

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The creation of skin substitutes has significantly decreased morbidity and mortality of skin wounds. Although there are still a number of disadvantages of currently available skin substitutes, there has been a significant decline in research advances over the past several years in improving these skin substitutes. Clinically most skin substitutes used are acellular and do not use growth factors to assist wound healing, key areas of potential in this field of research. This article discusses the five necessary attributes of an ideal skin substitute. It comprehensively discusses the three major basic components of currently available skin substitutes: scaffold materials, growth factors, and cells, comparing and contrasting what has been used so far. It then examines a variety of techniques in how to incorporate these basic components together to act as a guide for further research in the field to create cellular skin substitutes with clinically better results.

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Section: Creating Skin Substitutesmentioning

confidence: 99%

Methodologies in creating skin substitutes

Nicholas

Jeschke

Amini-Nik

2016

Cell. Mol. Life Sci.

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“…This supports previous findings that chitosan reduces the inflammatory response, therefore improving the inflammation stage. As a result, the greater proliferation and excellent collagen deposition during remodeling accelerate the wound healing process [ 50 ]. This biopolymer improves the wound tensile strength by speeding up the fibroblastic synthesis of collagen in the first few days of wound healing [ 51 ].…”

Section: Discussionmentioning

confidence: 99%

“…The antimicrobial activity of chitosan also promotes the repair of damaged tissue, preventing infection of the wound [ 7 , 50 , 51 ]. This biopolymer increases the permeability of the inner and outer membranes and ultimately disrupts the bacterial cell membranes, releasing their contents.…”

Section: Discussionmentioning

confidence: 99%

The Effects of Chitosan on the Healing Process of Oral Mucosa: An Observational Cohort Feasibility Split-Mouth Study

et al. 2023

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The healing process is a dynamic process accompanied by some classical symptoms of inflammation such as redness, swelling, pain, and loss of function. Chitosan is a natural polymer with properties that contribute to tissue healing, with properties that could be applied in periodontal therapy, such as the wound healing of oral mucosa. This experimental split-mouth study aims to assess the possibilities of chitosan influencing the healing process of oral mucosa in eight patients, where the studied group was subjected to two oral surgeries: one with chitosan hydrogel into the socket and other without the biomaterial. A semi-quantitative analysis of the data was performed. Some classic signs of inflammation in a short period of time were observed where chitosan acted, compared to the control. An absence of bleeding was observed in the chitosan cases. According to the literature, chitosan recruits and activates neutrophils and macrophages and stimulates angiogenesis. Hemostatic and antimicrobial activity of chitosan also play an important role in wound healing. Chitosan seems to improve the postoperative quality of patients, allowing rapid wound healing with less complications.

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“…Apart from FSCs being used in combination with DPSCs, where a correct stratification, differentiation and well-ordered epithelia was observed 130 , Mohd Hilmi et al 132 reported that a chitosan-TESS composed of fibroblasts and FSCs serving as the epidermal component, was capable of restoring rat skin after radiation exposure by an increasing collagen bundle deposition.…”

Section: Human Stem Cells (Hsscs) In Tesssmentioning

confidence: 99%

“…Many different biomaterials have been investigated for the development of TESSs; from xenogeneic scaffolds such as porcine acellular matrix 130 , natural polymers like silk fibroin 159 , agarose 32 , 156 or chitosan 29 , 129 , 132 to substances that resemble in better way the native dermal components of skin: collagen 56 , 60 – 65 , 86 – 93 , 95 , 101 , 104 , 106 , plasma/fibrin 49 , 51 , 94 , 96 , 98 , 102 , 103 , hyaluronic acid 60 – 65 , 97 , elastin 56 , amniotic membrane 68 , 178 or extracellular matrix derived from fibroblasts 39 , 99 , 100 , 105 .…”

Section: Main Biomaterials For Clinical Tesssmentioning

confidence: 99%

Cellular human tissue-engineered skin substitutes investigated for deep and difficult to heal injuries

et al. 2021

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Wound healing is an important function of skin; however, after significant skin injury (burns) or in certain dermatological pathologies (chronic wounds), this important process can be deregulated or lost, resulting in severe complications. To avoid these, studies have focused on developing tissue-engineered skin substitutes (TESSs), which attempt to replace and regenerate the damaged skin. Autologous cultured epithelial substitutes (CESs) constituted of keratinocytes, allogeneic cultured dermal substitutes (CDSs) composed of biomaterials and fibroblasts and autologous composite skin substitutes (CSSs) comprised of biomaterials, keratinocytes and fibroblasts, have been the most studied clinical TESSs, reporting positive results for different pathological conditions. However, researchers’ purpose is to develop TESSs that resemble in a better way the human skin and its wound healing process. For this reason, they have also evaluated at preclinical level the incorporation of other human cell types such as melanocytes, Merkel and Langerhans cells, skin stem cells (SSCs), induced pluripotent stem cells (iPSCs) or mesenchymal stem cells (MSCs). Among these, MSCs have been also reported in clinical studies with hopeful results. Future perspectives in the field of human-TESSs are focused on improving in vivo animal models, incorporating immune cells, designing specific niches inside the biomaterials to increase stem cell potential and developing three-dimensional bioprinting strategies, with the final purpose of increasing patient’s health care. In this review we summarize the use of different human cell populations for preclinical and clinical TESSs under research, remarking their strengths and limitations and discuss the future perspectives, which could be useful for wound healing purposes.

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A Bilayer Engineered Skin Substitute for Wound Repair in an Irradiation-Impeded Healing Model on Rat

Cited by 12 publications

References 35 publications

Methodologies in creating skin substitutes

Methodologies in creating skin substitutes

The Effects of Chitosan on the Healing Process of Oral Mucosa: An Observational Cohort Feasibility Split-Mouth Study

Cellular human tissue-engineered skin substitutes investigated for deep and difficult to heal injuries

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