Your search keyword '"Beata Niemczyk-Soczynska"' showing total 9 results

1. Methylcellulose/agarose hydrogel loaded with short electrospun PLLA/laminin fibers as an injectable scaffold for tissue engineering/3D cell culture model for tumour therapies

Author

Beata Niemczyk-Soczynska, Dorota Kolbuk, Grzegorz Mikulowski, Iwona A. Ciechomska, and Pawel Sajkiewicz

Subjects

General Chemical Engineering, General Chemistry

Abstract

The PLLA/laminin fiber addition to the methylcellulose/agarose hydrogel system enables its injectability, ensures ECM-mimicking morphology and biochemical cues, and good cell–material interactions.

Published

2023

2. A methylcellulose/agarose hydrogel as an innovative scaffold for tissue engineering

Author

Beata Niemczyk-Soczynska, Arkadiusz Gradys, Dorota Kolbuk, Anna Krzton-Maziopa, Piotr Rogujski, Luiza Stanaszek, Barbara Lukomska, and Pawel Sajkiewicz

Subjects

General Chemical Engineering, General Chemistry

Abstract

Agarose addition to a methylcellulose (MC) solution accelerates MC thermal crosslinking, enhances mechanical properties, provides an ECM-mimicking environment, and allows homogenous cell infiltration into hydrogel volume.

Published

2022

3. A Comprehensive Review of Electrospun Fibers, 3D-Printed Scaffolds, and Hydrogels for Cancer Therapies

Author

Beata Niemczyk-Soczynska, Paweł Sajkiewicz, and Angelika Zaszczyńska

Subjects

Polymers and Plastics, General Chemistry

Abstract

Anticancer therapies and regenerative medicine are being developed to destroy tumor cells, as well as remodel, replace, and support injured organs and tissues. Nowadays, a suitable three-dimensional structure of the scaffold and the type of cells used are crucial for creating bio-inspired organs and tissues. The materials used in medicine are made of non-degradable and degradable biomaterials and can serve as drug carriers. Developing flexible and properly targeted drug carrier systems is crucial for tissue engineering, regenerative medicine, and novel cancer treatment strategies. This review is focused on presenting innovative biomaterials, i.e., electrospun nanofibers, 3D-printed scaffolds, and hydrogels as a novel approach for anticancer treatments which are still under development and awaiting thorough optimization.

Published

2022

4. Solution-Blown Poly(hydroxybutyrate) and ε-Poly-<scp>l</scp>-lysine Submicro- and Microfiber-Based Sustainable Nonwovens with Antimicrobial Activity for Single-Use Applications

Author

Behnam Pourdeyhimi, Suman Sinha-Ray, Jeremiah T. Abiade, Alexander L. Yarin, Yasmin J. Dias, Paweł Sajkiewicz, Jaqueline Rojas Robles, Beata Niemczyk-Soczynska, and Dorota Kołbuk

Subjects

chemistry.chemical_classification, Materials science, business.product_category, Single use, Polymer science, Polymers, First line, Lysine, Biomedical Engineering, Hydroxybutyrates, C. albicans, Polymer, Antimicrobial, Anti-Bacterial Agents, Biomaterials, Anti-Infective Agents, chemistry, Prohibitins, Microfiber, Humans, Polylysine, business

Abstract

Antimicrobial nonwovens for single use applications (e.g., diapers, sanitary napkins, medical gauze, etc.) are of utmost importance as the first line of defense against bacterial infections. However, the utilization of petrochemical nondegradable polymers in such nonwovens creates sustainability-related issues. Here, sustainable poly(hydroxybutyrate) (PHB) and e-poly-l-lysine (e-PLL) submicro- and microfiber-based antimicrobial nonwovens produced by a novel industrially scalable process, solution blowing, have been proposed. In such nonwovens, e-PLL acts as an active material. In particular, it was found that most of e-PLL is released within the first hour of deployment, as is desirable for the applications of interest. The submicro- and microfiber mat was tested against C. albicans and E. coli, and it was found that e-PLL-releasing microfibers result in a significant reduction of bacterial colonies. It was also found that e-PLL-releasing antimicrobial submicro- and microfiber nonwovens are safe for human cells in fibroblast culture. Mechanical characterization of these nonwovens revealed that, even though they are felt as soft and malleable, they possess sufficient strength, which is desirable in the end-user applications.

Published

2021

5. Toward a Better Understanding of the Gelation Mechanism of Methylcellulose via Systematic DSC Studies

Author

Beata Niemczyk-Soczynska, Pawel Sajkiewicz, and Arkadiusz Gradys

Subjects

methylcellulose, thermosensitive hydrogel, crosslinking, DSC, Polymers and Plastics, General Chemistry

Abstract

A methylcellulose (MC) is one of the materials representatives performing unique thermal-responsive properties. While reaching a critical temperature upon heating MC undergoes a physical sol-gel transition and consequently becomes a gel. The MC has been studied for many years and researchers agree that the MC gelation is related to the lower critical solution temperature (LCST). Nevertheless, a precise description of the MC gelation mechanism remains under discussion. In this study, we explained the MC gelation mechanism through examination of a wide range of MC concentrations via differential scanning calorimetry (DSC). The results evidenced that MC gelation is a multistep thermoreversible process, manifested by three and two endotherms depending on MC concentration. The occurrence of the three endotherms for low MC concentrations during heating has not been reported in the literature before. We justify this phenomenon by manifestation of three various transitions. The first one manifests water–water interactions, i.e., spanning water network breakdown into small water clusters. It is clearly evidenced by additional normalization to the water content. The second effect corresponds to polymer–water interactions, i.e., breakdown of water cages surrounded methoxy groups of MC. The last one is related to the polymer–polymer interactions, i.e., fibril hydrophobic domain formation. Not only did these results clarify the MC crosslinking mechanism, but also in the future will help to assess MC relevance for various potential application fields.

Published

2022

6. Hydrogel, Electrospun and Composite Materials for Bone/Cartilage and Neural Tissue Engineering

Author

Konrad Zabielski, Paweł Sajkiewicz, Beata Niemczyk-Soczynska, and Angelika Zaszczynska

Subjects

Technology, Materials science, Review, composites, Neural tissue engineering, Tissue engineering, Electrospun nanofibers, medicine, General Materials Science, injectable materials, polymers, hydrogels, Microscopy, QC120-168.85, Cartilage, Regeneration (biology), QH201-278.5, technology, industry, and agriculture, Engineering (General). Civil engineering (General), TK1-9971, medicine.anatomical_structure, Descriptive and experimental mechanics, scaffolds, tissue engineering, electrospun nanofibers, Self-healing hydrogels, nanoparticles, Electrical engineering. Electronics. Nuclear engineering, TA1-2040, Biomedical engineering

Abstract

Injuries of the bone/cartilage and central nervous system are still a serious socio-economic problem. They are an effect of diversified, difficult-to-access tissue structures as well as complex regeneration mechanisms. Currently, commercially available materials partially solve this problem, but they do not fulfill all of the bone/cartilage and neural tissue engineering requirements such as mechanical properties, biochemical cues or adequate biodegradation. There are still many things to do to provide complete restoration of injured tissues. Recent reports in bone/cartilage and neural tissue engineering give high hopes in designing scaffolds for complete tissue regeneration. This review thoroughly discusses the advantages and disadvantages of currently available commercial scaffolds and sheds new light on the designing of novel polymeric scaffolds composed of hydrogels, electrospun nanofibers, or hydrogels loaded with nano-additives.

Published

2021

7. Shortening of electrospun PLLA fibers by ultrasonication

Author

Dorota Kołbuk, Beata Niemczyk-Soczynska, Judyta Dulnik, Oliwia Jeznach, and Paweł Sajkiewicz

Subjects

010302 applied physics, chemistry.chemical_classification, Materials science, Sonication, General Physics and Astronomy, 02 engineering and technology, Cell Biology, Polymer, 021001 nanoscience & nanotechnology, 01 natural sciences, Electrospinning, law.invention, Gel permeation chromatography, chemistry, Structural Biology, law, 0103 physical sciences, General Materials Science, Ultrasonic sensor, Fiber, Fragmentation (cell biology), Composite material, 0210 nano-technology, Filtration

Abstract

This research work is aimed at studying the effect of ultrasounds on the effectiveness of fiber fragmentation by taking into account the type of sonication medium, processing time, and various PLLA molecular weights. Fragmentation was followed by an appropriate filtration in order to decrease fibers length distribution. It was evidenced by fiber length determination using SEM that the fibers are shortened after ultrasonic treatment, and the effectiveness of shortening depends on the two out of three investigated parameters, mostly on the sonication medium, and processing time. The gel permeation chromatography (GPC) confirmed that such ultrasonic treatment does not change the polymers' molecular weight. Our results allowed to optimize the ultrasonic fragmentation procedure of electrospun fibers while preliminary viscosity measurements of fibers loaded into hydrogel confirmed their potential in further use as fillers for injectable hydrogels for regenerative medicine applications.

Published

2021

8. Crosslinking Kinetics of Methylcellulose Aqueous Solution and Its Potential as a Scaffold for Tissue Engineering

Author

Dorota Kołbuk, Arkadiusz Gradys, Beata Niemczyk-Soczynska, Paweł Sajkiewicz, and Anna Krzton-Maziopa

Subjects

Polymers and Plastics, Kinetics, 02 engineering and technology, macromolecular substances, DMA, 010402 general chemistry, 01 natural sciences, Endothermic process, Viscoelasticity, Article, DSC, lcsh:QD241-441, Hydrophobic effect, Differential scanning calorimetry, lcsh:Organic chemistry, Tissue engineering, thermosensitive hydrogel, methylcellulose, cellular tests, Aqueous solution, Chemistry, technology, industry, and agriculture, General Chemistry, Dynamic mechanical analysis, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Chemical engineering, crosslinking kinetics, 0210 nano-technology

Abstract

Thermosensitive, physically crosslinked injectable hydrogels are in the area of interests of various scientific fields. One of the representatives of this materials group is an aqueous solution of methylcellulose. At ambient conditions, methylcellulose (MC) is a sol while on heating up to 37 &deg, C, MC undergoes physical crosslinking and transforms into a gel. Injectability at room temperature, and crosslinkability during subsequent heating to physiological temperature raises hopes, especially for tissue engineering applications. This research work aimed at studying crosslinking kinetics, thermal, viscoelastic, and biological properties of MC aqueous solution in a broad range of MC concentrations. It was evidenced by Differential Scanning Calorimetry (DSC) that crosslinking of MC is a reversible two-stage process, manifested by the appearance of two endothermic effects, related to the destruction of water cages around methoxy groups, followed by crosslinking via the formation of hydrophobic interactions between methoxy groups in the polymeric chains. The DSC results also allowed the determination of MC crosslinking kinetics. Complementary measurements of MC crosslinking kinetics performed by dynamic mechanical analysis (DMA) provided information on the final storage modulus, which was important from the perspective of tissue engineering applications. Cytotoxicity tests were performed using mouse fibroblasts and showed that MC at low concentration did not cause cytotoxicity. All these efforts allowed to assess MC hydrogel relevance for tissue engineering applications.

Published

2019

9. Hydrophilic Surface Functionalization of Electrospun Nanofibrous Scaffolds in Tissue Engineering

Author

Beata Niemczyk-Soczynska, Paweł Sajkiewicz, and Arkadiusz Gradys

Subjects

chemistry.chemical_classification, Scaffold, Polymers and Plastics, Biocompatibility, Biomolecule, Nanotechnology, Review, General Chemistry, Polymer, Electrospinning, lcsh:QD241-441, lcsh:Organic chemistry, chemistry, Tissue engineering, tissue engineering, Nanofiber, immobilization, Surface modification, nanofiber, electrospinning, polymers, surface functionalization

Abstract

Electrospun polymer nanofibers have received much attention in tissue engineering due to their valuable properties such as biocompatibility, biodegradation ability, appropriate mechanical properties, and, most importantly, fibrous structure, which resembles the morphology of extracellular matrix (ECM) proteins. However, they are usually hydrophobic and suffer from a lack of bioactive molecules, which provide good cell adhesion to the scaffold surface. Post-electrospinning surface functionalization allows overcoming these limitations through polar groups covalent incorporation to the fibers surface, with subsequent functionalization with biologically active molecules or direct deposition of the biomolecule solution. Hydrophilic surface functionalization methods are classified into chemical approaches, including wet chemical functionalization and covalent grafting, a physiochemical approach with the use of a plasma treatment, and a physical approach that might be divided into physical adsorption and layer-by-layer assembly. This review discusses the state-of-the-art of hydrophilic surface functionalization strategies of electrospun nanofibers for tissue engineering applications. We highlighted the major advantages and drawbacks of each method, at the same time, pointing out future perspectives and solutions in the hydrophilic functionalization strategies.

Published

2020