Your search keyword '"Sawicka, Justyna"' showing total 2 results

1. Release systems based on self-assembling RADA16-I hydrogels with a signal sequence which improves wound healing processes.

Author

Dzierżyńska, Maria, Sawicka, Justyna, Deptuła, Milena, Sosnowski, Paweł, Sass, Piotr, Peplińska, Barbara, Pietralik-Molińska, Zuzanna, Fularczyk, Martyna, Kasprzykowski, Franciszek, Zieliński, Jacek, Kozak, Maciej, Sachadyn, Paweł, Pikuła, Michał, and Rodziewicz-Motowidło, Sylwia

Subjects

*ELASTASES, *PEPTIDES, *LEUCOCYTE elastase, *HYDROGELS, *HEALING, *ELECTRON cryomicroscopy, *ATOMIC force microscopy, *MOLECULAR self-assembly

Abstract

Self-assembling peptides can be used for the regeneration of severely damaged skin. They can act as scaffolds for skin cells and as a reservoir of active compounds, to accelerate scarless wound healing. To overcome repeated administration of peptides which accelerate healing, we report development of three new peptide biomaterials based on the RADA16-I hydrogel functionalized with a sequence (AAPV) cleaved by human neutrophil elastase and short biologically active peptide motifs, namely GHK, KGHK and RDKVYR. The peptide hybrids were investigated for their structural aspects using circular dichroism, thioflavin T assay, transmission electron microscopy, and atomic force microscopy, as well as their rheological properties and stability in different fluids such as water or plasma, and their susceptibility to digestion by enzymes present in the wound environment. In addition, the morphology of the RADA-peptide hydrogels was examined with a unique technique called scanning electron cryomicroscopy. These experiments enabled us to verify if the designed peptides increased the bioactivity of the gel without disturbing its gelling processes. We demonstrate that the physicochemical properties of the designed hybrids were similar to those of the original RADA16-I. The materials behaved as expected, leaving the active motif free when treated with elastase. XTT and LDH tests on fibroblasts and keratinocytes were performed to assess the cytotoxicity of the RADA16-I hybrids, while the viability of cells treated with RADA16-I hybrids was evaluated in a model of human dermal fibroblasts. The hybrid peptides revealed no cytotoxicity; the cells grew and proliferated better than after treatment with RADA16-I alone. Improved wound healing following topical delivery of RADA-GHK and RADA-KGHK was demonstrated using a model of dorsal skin injury in mice and histological analyses. The presented results indicate further research is warranted into the engineered peptides as scaffolds for wound healing and tissue engineering. [ABSTRACT FROM AUTHOR]

Published

2023

2. Functionalized Peptide Fibrils as a Scaffold for Active Substances in Wound Healing.

Author

Sawicka, Justyna, Iłowska, Emilia, Deptuła, Milena, Sosnowski, Paweł, Sass, Piotr, Czerwiec, Katarzyna, Chmielewska, Klaudia, Szymańska, Aneta, Pietralik-Molińska, Zuzanna, Kozak, Maciej, Sachadyn, Paweł, Pikuła, Michał, and Rodziewicz-Motowidło, Sylwia

Subjects

*WOUND healing, *ELASTASES, *AMINO acid sequence, *ANTIBODY-dependent cell cytotoxicity, *LABORATORY mice, *SKIN injuries

Abstract

Technological developments in the field of biologically active peptide applications in medicine have increased the need for new methods for peptide delivery. The disadvantage of peptides as drugs is their low biological stability. Recently, great attention has been paid to self-assembling peptides that can form fibrils. Such a formulation makes bioactive peptides more resistant to enzymatic degradation and druggable. Peptide fibrils can be carriers for peptides with interesting biological activities. These features open up prospects for using the peptide fibrils as long-acting drugs and are a valid alternative to conventional peptidic therapies. In our study, we designed new peptide scaffolds that are a hybrid of three interconnected amino acid sequences and are: pro-regenerative, cleavable by neutrophilic elastase, and fibril-forming. We intended to obtain peptides that are stable in the wound environment and that, when applied, would release a biologically active sequence. Our studies showed that the designed hybrid peptides show a high tendency toward regular fibril formation and are able to release the pro-regenerative sequence. Cytotoxicity studies showed that all the designed peptides were safe, did not cause cytotoxic effects and revealed a pro-regenerative potential in human fibroblast and keratinocyte cell lines. In vivo experiments in a dorsal skin injury model in mice indicated that two tested peptides moderately promote tissue repair in their free form. Our research proves that peptide fibrils can be a druggable form and a scaffold for active peptides. [ABSTRACT FROM AUTHOR]

Published

2021