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Rusztowania (scaffolds) stosowane w medycynie regenaracyjnej

Chaberska A., Rosiak P., Kamiński Z. J., Kolesińska B.

Wiadomości Chemiczne

2017

[Z] 71, 3-4

263--286

The presence of three dimensional support is indispensable condition for successful regeneration of the tissue. In the absence of natural scaffold, or absence of its artificial substitute, regeneration is not possible. The advantage of natural building blocks to create new scaffolds results from the requirements of the materials structures used for tissue regeneration: biocompatibility, biodegradability, lack of cytotoxicity and desirable mechanical properties. Application of these building blocks for the preparation of three dimensional materials should ensure completely biocompatibility of the temporary extracellular matrix equivalent, thus offering construct resembling a natural milieu for the cells and finally regeneration of tissues. These include framework with elements stimulating adhesion of in vitro grown cells, growth factors, hormones and vitamins offered as a completed ingredients in the commercially available culture media. 3D frameworks applied for cell growing should facilitate formation of required tissue shape and size as well as appropriate functioning of the cells. The key factor for the successful regeneration of tissues is the function of the scaffold determining the environment for growing cells, directing proliferation and regulating differentiation processes. The basic feature of the cellular scaffold, determining its functioning is porosity. Pore diameter and their abundance consists a critical factor for penetration of cells into the interior of the implant and finally for successful regeneration of damaged tissue. The progress of tissue regeneration in vitro depends on the presence of cytokines and growth factors, which are controlling cell differentiation process. Nowadays neither of implant material offered on the market has a property comparable to the natural tissue. However, there are many reports presenting preliminary experiments conducted towards attaining novel supports for regenerative medicine derived from peptides and formed by their self-organization. The most advanced of them are known under trade name PuraMatrix, which recently were applied for the regeneration of soft tissues. However, due to tendency of this materials for hydrogels formation, characteristic for them are disadvantageous mechanical properties. The alternative approach based on application of native ECM proteins was also taken into consideration. The weak points of this materials are the susceptibility of proteins towards proteolytic enzymes and theirs immunogenic properties. The diversity of peptide modules give the opportunity to design and synthesize a variety of biomaterials that mimic the structural complexity of the natural ECM.

Fabrication of Pure Electrospun Materials from Hyaluronic Acid

Pabjańczyk-Wlazło E., Krucińska I., Chrzanowski M., Szparaga G., Chaberska A., Kolesińska B., Komisarczyk A., Boguń M.

Fibres & Textiles in Eastern Europe

2017

Vol. 25, no. 3 (123)

45--52

The aim of the research was to develop optimal conditions for manufacturing materials based on hyaluronic acid by the electrospun method. The studies were composed of three stages: the process of selection of the optimal solvent (mixture of solvents), the molecular weight of hyaluronic acid, and the concentration of biopolymer in the spinning solution. The influence of variable parameters on the rheological properties of the spinning solutions and electrospinning trails was tested. Depending on the electrospinning regime applied, the fibers obtained were characterised by a diameter of the order of 20 to 400 nm. As a result of the development works presented, an optimal molecular weight of the polymer, its concentration and system of solvents were determined, together with process parameters, ensuring a stable electrospinning process and relatively homogeneous nanofibers. Additionally studies on the residues of solvents used during electrosun formation were done and parameters of drying of the final materials were examined. This approach (verification of the presence of organic solvent residue in the nanofibrous formed) is important for the suitability of nanofibres as scaffolds for regenerative medicine. This study provides an opportunity for the understanding and identification of process parameters, allowing for predictable manufacturing nanofibers based on natural biopolymers, which makes it tremendously beneficial in terms of customisation.

Celem badań było opracowanie optymalnych warunków otrzymywania nanowłókien z kwasu hialuronowego. Badania obejmowały następujące etapy realizacji pracy: proces doboru optymalnego rozpuszczalnika dla polimeru oraz dobór masy cząsteczkowej kwasu hialuronowego. Zbadano właściwości reologiczne roztworów oraz wpływ zmiennych parametrów procesowych na strukturę mikroskopową włókien. W zależności od zastosowanych parametrów elektroprzędzenia otrzymane włókna charakteryzowały się średnią rzędu od 20 do 400 nm. Dodatkowo przeprowadzono badania dotyczące pozostałości rozpuszczalników stosowanych w przygotowaniu roztworów przędzalniczych, co jest istotne z punktu widzenia wykorzystania tych materiałów w obrębie medycyny regeneracyjnej.