Partner: Ewa Kijeńska-Gawrońska |
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Recent publications
1. | Rinoldi C., Kijeńska-Gawrońska E.♦, Khademhosseini A.♦, Tamayol A.♦, Swieszkowski W.♦, Fibrous systems as potential solutions for tendon and ligament repair, healing, and regeneration, ADVANCED HEALTHCARE MATERIALS, ISSN: 2192-2659, DOI: 10.1002/adhm.202001305, Vol.10, No.7, pp.2001305 - 1-26, 2021 | |||||||||||||||||||||||||||||||||||||||||||
2. | Rinoldi C.♦, Costantini M.♦, Kijeńska-Gawrońska E.♦, Testa S.♦, Fornetti E.♦, Heljak M.♦, Ćwiklińska M.♦, Buda R.♦, Baldi J.♦, Cannata S.♦, Guzowski J.♦, Gargioli C.♦, Khademhosseini A.♦, Święszkowski W.♦, Tendon tissue engineering: effects of mechanical and biochemical stimulation on stem cell alignment on cell‐laden hydrogel yarns, ADVANCED HEALTHCARE MATERIALS, ISSN: 2192-2659, DOI: 10.1002/adhm.201801218, Vol.8, No.7, pp.1801218-1-10, 2019 Abstract: Fiber-based approaches hold great promise for tendon tissue engineering enabling the possibility of manufacturing aligned hydrogel filaments that can guide collagen fiber orientation, thereby providing a biomimetic micro-environment for cell attachment, orientation, migration, and proliferation. In this study, a 3D system composed of cell-laden, highly aligned hydrogel yarns is designed and obtained via wet spinning in order to reproduce the morphology and structure of tendon fascicles. A bioink composed of alginate and gelatin methacryloyl (GelMA) is optimized for spinning and loaded with human bone morrow mesenchymal stem cells (hBM-MSCs). The produced scaffolds are subjected to mechanical stretching to recapitulate the strains occurring in native tendon tissue. Stem cell differentiation is promoted by addition of bone morphogenetic protein 12 (BMP-12) in the culture medium. The aligned orientation of the fibers combined with mechanical stimulation results in highly preferential longitudinal cell orientation and demonstrates enhanced collagen type I and III expression. Additionally, the combination of biochemical and mechanical stimulations promotes the expression of specific tenogenic markers, signatures of efficient cell differentiation towards tendon. The obtained results suggest that the proposed 3D cell-laden aligned system can be used for engineering of scaffolds for tendon regeneration. Keywords:hydrogel fibers, static mechanical stretching, stem cell alignment, tenogenic differentiation, wet spinning Affiliations:
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3. | Rinoldi C.♦, Fallahi A.♦, Yazdi I.K.♦, Paras J.C.♦, Kijeńska-Gawrońska E.♦, Trujillo-de Santiago G.♦, Tuoheti A.♦, Demarchi D.♦, Annabi N.♦, Khademhosseini A.♦, Święszkowski W.♦, Tamayol A.♦, Mechanical and biochemical stimulation of 3D multilayered scaffolds for tendon tissue engineering, ACS BIOMATERIALS SCIENCE & ENGINEERING, ISSN: 2373-9878, DOI: 10.1021/acsbiomaterials.8b01647, Vol.5, No.6, pp.2953-2964, 2019 Abstract: Tendon injuries are frequent and occur in the elderly, young, and athletic populations. The inadequate number of donors combined with many challenges associated with autografts, allografts, xenografts, and prosthetic devices have added to the value of engineering biological substitutes, which can be implanted to repair the damaged tendons. Electrospun scaffolds have the potential to mimic the native tissue structure along with desired mechanical properties and, thus, have attracted noticeable attention. In order to improve the biological responses of these fibrous structures, we designed and fabricated 3D multilayered composite scaffolds, where an electrospun nanofibrous substrate was coated with a thin layer of cell-laden hydrogel. The whole construct composition was optimized to achieve adequate mechanical and physical properties as well as cell viability and proliferation. Mesenchymal stem cells (MSCs) were differentiated by the addition of bone morphogenetic protein 12 (BMP-12). To mimic the natural function of tendons, the cell-laden scaffolds were mechanically stimulated using a custom-built bioreactor. The synergistic effect of mechanical and biochemical stimulation was observed in terms of enhanced cell viability, proliferation, alignment, and tenogenic differentiation. The results suggested that the proposed constructs can be used for engineering functional tendons. Keywords:tendon tissue engineering, composite scaffolds, nanofibrous materials, mechanical stimulation, stem cell differentiation Affiliations:
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4. | Chlanda A.♦, Kijeńska E.♦, Rinoldi C.♦, Tarnowski M.♦, Wierzchoń T.♦, Święszkowski W.♦, Structure and physico-mechanical properties of low temperature plasma treated electrospun nanofibrous scaffolds examined with atomic force microscopy, Micron, ISSN: 0968-4328, DOI: 10.1016/j.micron.2018.01.012, Vol.107, pp.79-84, 2018 Abstract: Electrospun nanofibrous scaffolds are willingly used in tissue engineering applications due to their tunable mechanical, chemical and physical properties. Additionally, their complex openworked architecture is similar to the native extracellular matrix of living tissue. After implantation such scaffolds should provide sufficient mechanical support for cells. Moreover, it is of crucial importance to ensure sterility and hydrophilicity of the scaffold. For this purpose, a low temperature surface plasma treatment can be applied. In this paper, we report physico-mechanical evaluation of stiffness and adhesive properties of electrospun mats after their exposition to low temperature plasma. Complex morphological and mechanical studies performed with an atomic force microscope were followed by scanning electron microscope imaging and a wettability assessment. The results suggest that plasma treatment can be a useful method for the modification of the surface of polymeric scaffolds in a desirable manner. Plasma treatment improves wettability of the polymeric mats without changing their morphology. Keywords:Atomic force microscopy, Surface modification, Electrospun fibers, RF plasma treatment, Tissue engineering, Nanomaterial Affiliations:
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5. | Rinoldi C.♦, Kijeńska E.♦, Chlanda A.♦, Choińska E.♦, Khenoussi N.♦, Tamayol A.♦, Khademhosseini A.♦, Święszkowski W.♦, Nanobead-on-string composites for tendon tissue engineering, JOURNAL OF MATERIALS CHEMISTRY B , ISSN: 2050-7518, DOI: 10.1039/c8tb00246k, Vol.6, No.19, pp.3116-3127, 2018 Abstract: Tissue engineering holds great potential in the production of functional substitutes to restore, maintain or improve the functionality in defective or lost tissues. So far, a great variety of techniques and approaches for fabrication of scaffolds have been developed and evaluated, allowing researchers to tailor precisely the morphological, chemical and mechanical features of the final constructs. Electrospinning of biocompatible and biodegradable polymers is a popular method for producing homogeneous nanofibrous structures, which might reproduce the nanosized organization of the tendons. Moreover, composite scaffolds obtained by incorporating nanoparticles within electrospun fibers have been lately explored in order to enhance the properties and the functionalities of the pristine polymeric constructs. The present study is focused on the design and fabrication of biocompatible electrospun nanocomposite fibrous scaffolds for tendon regeneration. A mixture of poly(amide 6) and poly(caprolactone) is electrospun to generate constructs with mechanical properties comparable to that of native tendons. To improve the biological activity of the constructs and modify their topography, wettability, stiffness and degradation rate, we incorporated silica particles into the electrospun substrates. The use of nanosize silica particles enables us to form bead-on-fiber topography, allowing the better exposure of ceramic particles to better profit their beneficial characteristics. In vitro biocompatibility studies using L929 fibroblasts demonstrated that the presence of 20 wt% of silica nanoparticles in the engineered scaffolds enhanced cell spreading and proliferation as well as extracellular matrix deposition. The results reveal that the electrospun nanocomposite scaffold represents an interesting candidate for tendon tissue engineering. Affiliations:
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