Peptide hydrogel <i>in vitro</i> non‐inflammatory potential

Markey, A.L.; Workman, Victoria L.; Bruce, Iain; Woolford, T. J.; Derby, Brian; Miller, Aline F.; Cartmell, Sarah H.; Saiani, Alberto

doi:10.1002/psc.2940

Cited by 24 publications

(19 citation statements)

References 46 publications

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“…97 Today, most peptide formulations designed in the field offer good biocompatibility, however, the potential immunogenicity derived from peptides itself or peptide-derived aggregates is still controversial. [111][112][113] This fact makes it necessary to carry out further research to discard any immunological effects related to peptide gels, when transferred into pancreatic tissues in vivo, before considering their therapeutic applications.…”

Section: Acellular Self-assembled Peptide Hydrogels For the Treatmentmentioning

confidence: 99%

Self-Assembling Peptides as an Emerging Platform for the Treatment of Metabolic Syndrome

Castillo-Díaz¹,

Ruíz-Pacheco²,

Elsawy³

et al. 2020

IJN

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Metabolic syndrome comprises a cluster of comorbidities that represent a major risk of developing chronic diseases, such as type II diabetes, cardiovascular diseases, and stroke. Alarmingly, metabolic syndrome reaches epidemic proportions worldwide. Today, lifestyle changes and multiple drug-based therapies represent the gold standard to address metabolic syndrome. However, such approaches face two major limitations: complicated drug therapeutic regimes, which in most cases could lead to patient incompliance, and limited drug efficacy. This has encouraged scientists to search for novel routes to deal with metabolic syndrome and related diseases. Within such approaches, self-assembled peptide formulations have emerged as a promising alternative for treating metabolic syndrome. In particular, self-assembled peptide hydrogels, either as acellular or cell-load three-dimensional scaffoldings have reached significant relevance in the biomedical field to prevent and restore euglycemia, as well as for controlling cardiovascular diseases and obesity. This has been possible thanks to the physicochemical tunability of peptides, which are developed from a chemical toolbox of versatile amino acids enabling flexibility of designing a wide range of self-assembled/co-assembled nanostructures forming biocompatible viscoelastic hydrogels. Peptide hydrogels can be combined with several biological entities, such as extracellular matrix proteins, drugs or cells, forming functional biologics with therapeutic ability for treatment of metabolic syndrome-comorbidities. Additionally, self-assembly peptides combine safety, tolerability, and effectivity attributes; by this presenting a promising platform for the development of novel pharmaceuticals capable of addressing unmet therapeutic needs for diabetes, cardiovascular disorders and obesity. In this review, recent advances in developing self-assembly peptide nanostructures tailored for improving treatment of metabolic syndrome and related diseases will be discussed from basic research to preclinical research studies. Challenges facing the development of approved medicinal products based on self-assembling peptide nanomaterials will be discussed in light of regulatory requirement for clinical authorization.

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Section: Acellular Self-assembled Peptide Hydrogels For the Treatmentmentioning

confidence: 99%

Self-Assembling Peptides as an Emerging Platform for the Treatment of Metabolic Syndrome

Castillo-Díaz¹,

Ruíz-Pacheco²,

Elsawy³

et al. 2020

IJN

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“…SAP hydrogels provide a three‐dimensional (3‐D) environment that fosters proliferation and migration of many types of cells 9,10 . They have been shown not to elicit immunogenic or inflammatory responses 11‐13 . An SAP hydrogel, RADA16, has been proposed as a scaffold because it has unique 3‐D structure 6,14 .…”

Section: Introductionmentioning

confidence: 99%

Treatment with functionalized designer self‐assembling peptide hydrogels promotes healing of experimental periodontal defects

Matsugami

Murakami

Yoshida

et al. 2020

J of Periodontal Research

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Background/Objectives It has been reported that self‐assembling peptide (SAP) hydrogels with functionalized motifs enhance proliferation and migration of host cells. How these designer SAP hydrogels perform in the treatment of periodontal defects remains unknown. This study aimed to test the potential of local application of designer SAP hydrogels with two different functionalized motifs in the treatment of experimental periodontal defects. Material and Methods In vitro, viability/proliferation of rat periodontal ligament‐derived cells (PDLCs) cultured on an SAP hydrogel RADA16 and RADA16 with functionalized motifs, PRG (integrin binding sequence) and PDS (laminin cell adhesion motif), was assessed. Cell morphology was analyzed by scanning electron microscopy (SEM) and confocal laser scanning microscopy (CLSM). In vivo, standardized periodontal defects were made mesially in the maxillary first molars of Wistar rats. Defects received RADA16, PRG, PDS or left unfilled. At 2 or 4 weeks postoperatively, healing was assessed by microcomputed tomography, histological and immunohistochemical methods. Results Viability/proliferation of PDLCs was significantly greater on PRG than on RADA16 or PDS at 72 hours. rPDLCs in the PRG group showed enhanced elongations and cell protrusions. In vivo, at 4 weeks, bone volume fractions in the PRG and PDS groups were significantly greater than the RADA16 group. Histologically, bone formation was more clearly observed in the PRG and PDS groups compared with the RADA16 group. At 4 weeks, epithelial downgrowth in the hydrogel groups was significantly reduced compared to the Unfilled group. In Azan‐Mallory staining, PDL‐like bundles ran in oblique direction in the hydrogel groups. At 2 weeks, in the area near the root, proliferating cell nuclear antigen (PCNA)‐positive cells were detected significantly more in the PRG group than other groups. At 4 weeks, in the middle part of the defect, a significantly greater level of vascular endothelial growth factor (VEGF)‐positive cells and α‐smooth muscle actin (SMA)‐positive blood vessels were observed in the PRG group than in other groups. Conclusion The results indicate that local application of the functionalized designer SAP hydrogels, especially PRG, promotes periodontal healing by increasing cell proliferation and angiogenesis.

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“…[7][8][9][10][11][12] In contrast to other natural material-based hydrogels such as collagen, fibrin, alginate, or hyaluronan, advantages of such synthetic material include low risks of biological pathogen transmission and homogeneous batches in production. 13,14 Moreover, studies have shown that SAPs do not elicit immunogenic or inflammatory response in vitro 15 or in vivo. 10,16 In the specific context of cartilage repair, SAPs are interesting materials since the self-assembling process results in highly hydrated material (more than 90% water content) 17 and native cartilage is highly hydrated (80% water content), 18 a feature offering the tissue its "shock absorber" capabilities.…”

Section: Introductionmentioning

confidence: 99%

“…In contrast to other natural material‐based hydrogels such as collagen, fibrin, alginate, or hyaluronan, advantages of such synthetic material include low risks of biological pathogen transmission and homogeneous batches in production . Moreover, studies have shown that SAPs do not elicit immunogenic or inflammatory response in vitro or in vivo …”

Section: Introductionmentioning

confidence: 99%

Combination of bioactive factors and IEIK13 self‐assembling peptide hydrogel promotes cartilage matrix production by human nasal chondrocytes

Dufour

Buffier²,

Vertu-Ciolino

et al. 2019

J Biomedical Materials Res

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Nasal reconstruction remains a challenge for every reconstructive surgeon. Alloplastic implants are proposed to repair nasal cartilaginous defects but they are often associated with high rates of extrusion and infection and poor biocompatibility. In this context, a porous polymeric scaffold filled with an autologous cartilage gel would be advantageous. In this study, we evaluated the capacity of IEIK13 self‐assembling peptide (SAP) to serve as support to form such cartilage gel. Human nasal chondrocytes (HNC) were first amplified with FGF‐2 and insulin, and then redifferentiated in IEIK13 with BMP‐2, insulin, and T3 (BIT). Our results demonstrate that IEIK13 fosters HNC growth and survival. HNC phenotype was assessed by RT‐PCR analysis and neo‐synthesized extracellular matrix was characterized by western blotting and immunohistochemistry analysis. BIT‐treated cells embedded in IEIK13 displayed round morphology and expressed cartilage‐specific markers such as type II and type IX collagens and aggrecan. In addition, we did not detect significant production of type I and type X collagens and gene products of dedifferentiated and hypertrophic chondrocytes that are unwanted in hyaline cartilage. The whole of these results indicates that the SAP IEIK13 represents a suitable support for hydrogel‐based tissue engineering of nasal cartilage. © 2018 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 107A: 893–903, 2019.

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Peptide hydrogel in vitro non‐inflammatory potential

Cited by 24 publications

References 46 publications

Self-Assembling Peptides as an Emerging Platform for the Treatment of Metabolic Syndrome

Self-Assembling Peptides as an Emerging Platform for the Treatment of Metabolic Syndrome

Treatment with functionalized designer self‐assembling peptide hydrogels promotes healing of experimental periodontal defects

Combination of bioactive factors and IEIK13 self‐assembling peptide hydrogel promotes cartilage matrix production by human nasal chondrocytes

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