Antibacterial Activity within Degradation Products of Biological Scaffolds Composed of Extracellular Matrix

Brennan, Ellen P.; Reing, Janet E.; Chew, Douglas W.; Myers-Irvin, Julie M.; Young, Emma; Badylak, Stephen F.

doi:10.1089/ten.2006.12.2949

Cited by 209 publications

(140 citation statements)

References 50 publications

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“…Similar type of activity has been demonstrated by the ECM scaffold components derived from small intestinal submucosa (SIS) and urinary bladder sub-mucosa (UBS), which exhibit antibacterial activity against both Gram-negative and Gram-positive bacteria [76]. The antibacterial activity against E. coli and S. aureus has also been examined for porcine liver tissue and superficial layers of the porcine urinary bladder [77]. Although the exact mechanism of killing bacteria by action of peptides (produced during the degradation of the goat-lung ECM) is poorly understood [78], but it has been reported that either the antibacterial peptides may get directly associated with the bacterial cell membrane leading to lysis of the membrane or they get diffused into the bacterial cell cytoplasm and interferes with their protein synthesis [79].…”

Section: Antibacterial Activity Of Decellularized Goat-lung Matrixmentioning

confidence: 72%

Antibacterial activity and composition of decellularized goat lung extracellular matrix for its tissue engineering applications

Gupta¹,

Dinda²,

Mishra³

2017

Biol Eng Med

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In this study, scaffold was fabricated from goat-lung of cadaver goat by decellularization method for its potential application in tissue engineering. The cellular components of goat-lung were removed by employing trypsin-SDS based method of decellularization. DNA quantification and DAPI staining verified the effective removal of native cells from the goat-lung. Verhoeff-Van Gieson (VVG) staining, H&E staining and Periodic-Acid Schiff (PAS) staining histologically assessed the composition of native and decellularized goat-lung matrix-demonstrating the presence of collagen, elastin and glycoproteins in the decellularized goat-lung matrix. Antibacterial activity of decellularized goat-lung matrix was evaluated against gram-negative (Escherichiacoli) and gram-positive (Staphylococcusaureus) bacteria, which shows the presence of naturally occurring bioactive peptides-exhibiting the antibacterial activity against E. coli for up to 9h and against S. aureus for up to 5h. The decellularized goat-lung matrix, as demonstrated by MTT assay, was found to be biocompatibile to L929 mouse fibroblasts, HepG2, human skin derived mesenchymal stem cells (hS-MSCs), osteoblasts and BMMSCs. All the above results confer the applicability of the decellularized goat-lung matrix as a potential scaffold for tissue engineering applications.

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Section: Antibacterial Activity Of Decellularized Goat-lung Matrixmentioning

confidence: 72%

Antibacterial activity and composition of decellularized goat lung extracellular matrix for its tissue engineering applications

Gupta¹,

Dinda²,

Mishra³

2017

Biol Eng Med

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“…Because ECM scaffolds consist of various molecules such as collagen and fibronectin, proteoglycans, glycoproteins, growth factors, and cytokines (46), degradation of these ECM scaffolds releases a heterogeneous set of molecules (13,21), each with varying biologic properties in vivo. Subsets of these peptides have been found to have different bioactive properties in vitro (13,17,19,44,47,48). Although a subset of generated peptides is clearly chemotactic for stem cells, the overall contribution of these peptides to stem cell recruitment in vivo is as of yet unknown.…”

Section: Discussionmentioning

confidence: 99%

“…Although full characterization of these bioactive peptides has not been completed to date, ex vivo enzymatic, chemical, and physical methods (17)(18)(19), and in vivo physiologic methods (20), have generated a heterogeneous population of ECM peptides (13,21) with both chemotactic and mitogenic properties for a variety of stem and progenitor cells.…”

mentioning

confidence: 99%

Epimorphic regeneration approach to tissue replacement in adult mammals

Agrawal

Johnson²,

Reing³

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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138

134

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Urodeles and fetal mammals are capable of impressive epimorphic regeneration in a variety of tissues, whereas the typical default response to injury in adult mammals consists of inflammation and scar tissue formation. One component of epimorphic regeneration is the recruitment of resident progenitor and stem cells to a site of injury. Bioactive molecules resulting from degradation of extracellular matrix (ECM) have been shown to recruit a variety of progenitor and stem cells in vitro in adult mammals. The ability to recruit multipotential cells to the site of injury by in vivo administration of chemotactic ECM degradation products in a mammalian model of digit amputation was investigated in the present study. Adult, 6- to 8-week-old C57/BL6 mice were subjected to midsecond phalanx amputation of the third digit of the right hind foot and either treated with chemotactic ECM degradation products or left untreated. At 14 days after amputation, mice treated with ECM degradation products showed an accumulation of heterogeneous cells that expressed markers of multipotency, including Sox2, Sca1, and Rex1 (Zfp42). Cells isolated from the site of amputation were capable of differentiation along neuroectodermal and mesodermal lineages, whereas cells isolated from control mice were capable of differentiation along only mesodermal lineages. The present findings demonstrate the recruitment of endogenous stem cells to a site of injury, and/or their generation/proliferation therein, in response to ECM degradation products.

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“…The extracellular matrix, with its natural three-dimensional structure and composition, provides a scaffold for cell proliferation [30][31][32]. Such biological scaffolds have been shown to resist deliberate bacterial contamination [33][34], which is essential for creation of a barrier against infection in the direct skeletal attachment of a limb prosthesis. Therefore, in our in vitro experiments, we investigated whether collagen and fibrin treatment of a porous implant would affect migration of skin cells inside the structure of the implant.…”

Section: Discussionmentioning

confidence: 99%

Porous composite prosthetic pylon for integration with skin and bone

Pitkin¹,

Raykhtsaum²,

Pilling³

et al. 2007

JRRD

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Abstract-This article presents results of the further development and testing of the "skin and bone integrated pylon" (SBIP-1) for percutaneous (through skin) connection of the residual bone with an external limb prosthesis. We investigated a composite structure (called the SBIP-2) made of titanium particles and fine wires using mathematical modeling and mechanical testing. Results showed that the strength of the pylon was comparable with that of anatomical bone. In vitro and in vivo animal studies on 30 rats showed that the reinforcement of the composite pylon did not compromise its previously shown capacity for inviting skin and bone cell ingrowth through the device. These findings provide evidence for the safe and reliable long-term percutaneous transfer of vital and therapeutic substances, signals, and necessary forces and moments from a prosthetic device to the body.

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Antibacterial Activity within Degradation Products of Biological Scaffolds Composed of Extracellular Matrix

Cited by 209 publications

References 50 publications

Antibacterial activity and composition of decellularized goat lung extracellular matrix for its tissue engineering applications

Antibacterial activity and composition of decellularized goat lung extracellular matrix for its tissue engineering applications

Epimorphic regeneration approach to tissue replacement in adult mammals

Porous composite prosthetic pylon for integration with skin and bone

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