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Bioinspired Biomaterials : Advances in Tissue Engineering and Regenerative Medicine (2020)

Chun, Heung Jae. [editor.] ; Reis, Rui L. [editor.] ; Motta, Antonella. [editor.] ; [et al.]

Singapore :Springer Nature Singapore :

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Keywords: Biotechnology. ; Regenerative medicine. ; Pharmaceutical chemistry. ; Neurosciences. ; Biotechnology. ; Regenerative Medicine and Tissue Engineering. ; Pharmaceutics. ; Neuroscience. ; Chemical Bioengineering.

Description / Table of Contents: Part I. Novel Bioinspired Biomaterials for Regenerative Medicine -- Chapter 1. Natural Sources and Applications of Demineralized Bone Matrix in the Field of Bone and Cartilage Tissue Engineering -- Chapter 2. Application of Gellan Gum-based Scaffold for Regenerative Medicine -- Chapter 3. Natural Fibrous Protein for Advanced Tissue Engineering Applications: Focusing on Silk Fibroin and Keratin -- Part II. Bioinspired 3D Bioprinting Hydrogel for Regenerative Medicine -- Chapter 4. Silk Fibroin Bioinks for Digital Light Processing (DLP) 3D Bioprinting -- Chapter 5. 3D-Bioprinting of Tissue Models with Customized Bioinks -- Chapter 6. Visible Light-curable Hydrogel Systems for Tissue Engineering and Drug Delivery -- Part III. Regulation of Stem Cell Fate by Bioinspired Biomaterials -- Chapter 7. Scaffolds for Cartilage Regeneration: To Use or Not to Use -- Chapter 8. Bio-application of Inorganic Nanomaterials in Tissue Engineering -- Chapter 9. Directional Cell Migration Guide for Improved Tissue Regeneration -- Part IV. Cutting-Edge Enabling Technology for Regenerative Medicine -- Chapter 10. Extracellular Vesicles: The Next Frontier in Regenerative Medicine and Drug Delivery -- Chapter 11. Application of Tissue Engineering and Regenerative Medicine in Maternal-fetal Medicine -- Chapter 12. Fundamentals and Current Strategies for Peripheral Nerve Repair and Regeneration -- Chapter 13. Protein-based Drug Delivery in Brain Tumor Therapy -- Chapter 14. Human Hair: Scaffold Materials for Regenerative Medicine.

Abstract: This book is the first of two volumes that together offer a comprehensive account of cutting-edge advances in the development of biomaterials for use within tissue engineering and regenerative medicine. Topics addressed in this volume, which is devoted to bioinspired biomaterials, range from novel biomaterials for regenerative medicine through to emerging enabling technologies with applications in, for example, drug delivery, maternal–fetal medicine, peripheral nerve repair and regeneration, and brain tumor therapy. New bioinspired hydrogels receive detailed attention in the book, and a further focus is the use of bioinspired biomaterials in the regulation of stem cell fate. Here the coverage includes the role of scaffolds in cartilage regeneration, the bioapplication of inorganic nanomaterials in tissue engineering, and guidance of cell migration to improve tissue regeneration. The authors are recognized experts in the interdisciplinary field of regenerative medicine and the book will be of value for all with an interest in regenerative medicine based on biomaterials. .

Type of Medium: Online Resource

Pages: X, 229 p. 45 illus., 37 illus. in color. , online resource.

Edition: 1st ed. 2020.

ISBN: 9789811532580

Series Statement: Advances in Experimental Medicine and Biology, 1249

URL: https://doi.org/10.1007/978-981-15-3258-0

DOI: 10.1007/978-981-15-3258-0

DDC: 660.6

Language: English

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Biomimicked Biomaterials : Advances in Tissue Engineering and Regenerative Medicine (2020)

Chun, Heung Jae. [editor.] ; Reis, Rui L. [editor.] ; Motta, Antonella. [editor.] ; [et al.]

Singapore :Springer Nature Singapore :

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Description / Table of Contents: Part I. Novel Biomimicked Biomaterials for Regenerative Medicine -- Chapter 1. Bone Regeneration using Duck’s Feet Derived Collagen Scaffold as an Alternative Collagen Source -- Chapter 2. Decellularized Extracellular Matrices for Tissue Engineering and Regeneration -- Part II. Novel Biomimicked Hydrogel for Regenerative Medicine -- Chapter 3. Injectable in situ-forming Hydrogels for Protein and Peptide Delivery -- Chapter 4. Alginate Hydrogels as 3D Cell Encapsulation Matrices for Tissue Engineering and Regenerative Medicine -- Chapter 5. Design of Advanced Polymeric Hydrogels for Tissue Regenerative Medicine: Oxygen-controllable Hydrogel Materials -- Chapter 6. Enhancing Osteochondral Tissue Regeneration of Gellan Gum by Incorporating Gallus Gallus var Domesticus Derived Demineralized Bone Particle -- Part III. Control of Stem Cell Fate by Biomaterials for Regenerative Medicine -- Chapter 7. The Development of Extracellular Vesicles-Integrated Biomaterials for Bone Regeneration -- Chapter 8. In vivo Evaluation of the Biocompatibility of Biomaterial Device -- Chapter 9. Cell Response to Materials for Biomedical Engineering -- Chapter 10. Regulation of Stem Cell Functions by Micro-patterned Structures -- Part IV. Nano-Intelligent Biocomposites for Regenerative Medicine -- Chapter 11. Natural Polyphenols as Modulators of the Fibrillization of Islet Amyloid Polypeptide -- Chapter 12.Recent Advances of Biphasic Calcium Phosphate Bioceramics for Bone Tissue Regeneration -- Chapter 13. Surface-modifying Polymers for Blood-Contacting Polymeric Biomaterials.

Abstract: This book is the second of two volumes that together offer a comprehensive account of cutting-edge advances in the development of biomaterials for use within tissue engineering and regenerative medicine. In this volume, which is devoted to biomimetic biomaterials, the opening section discusses bone regeneration by means of duck’s feet-derived collagen scaffold and the use of decellularized extracellular matrices. The role of various novel biomimetic hydrogels in regenerative medicine is then considered in detail. The third section focuses on the control of stem cell fate by biomimetic biomaterials, covering exosome-integrated biomaterials for bone regeneration, cellular responses to materials for biomedical engineering, and the regulation of stem cell functions by micropatterned structures. Finally, the use of nano-intelligent biocomposites in regenerative medicine is addressed, with discussion of, for example, recent advances in biphasic calcium phosphate bioceramics and blood-contacting polymeric biomaterials. The authors are recognized experts in the interdisciplinary field of regenerative medicine and the book will be of value for all with an interest in regenerative medicine based on biomaterials.

Type of Medium: Online Resource

Pages: X, 198 p. 60 illus., 58 illus. in color. , online resource.

Edition: 1st ed. 2020.

ISBN: 9789811532627

Series Statement: Advances in Experimental Medicine and Biology, 1250

URL: https://doi.org/10.1007/978-981-15-3262-7

DOI: 10.1007/978-981-15-3262-7

DDC: 660.6

Language: English

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Microfluidics and Biosensors in Cancer Research : Applications in Cancer Modeling and Theranostics (2022)

Caballero, David. [editor.] ; Kundu, Subhas C. [editor.] ; Reis, Rui L. [editor.]

Cham :Springer International Publishing :

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Keywords: Cancer. ; Biochemical markers. ; Microfluidics. ; Pharmacology. ; Cancer Treatment. ; Cancer Biology. ; Biomarkers. ; Microfluidics. ; Pharmacology. ; Cancer Therapy.

Description / Table of Contents: Part 1. Fundamentals of Microfluidics and Biosensors -- Chapter 1. Fundamentals of Biosensors and Detection Methods -- Chapter 2. How to Get Away with Gradients -- Chapter 3. Sensors and Biosensors in Organs-on-a-chip Platforms -- Chapter 4. Current Trends in Microfluidics and Biosensors for Cancer Research Applications -- Part 2. Modelling the Tumor Microenvironment and Its Dynamic Events -- Chapter 5. The Tumor Microenvironment — an Introduction for the Development of Microfluidic Devices -- Chapter 6. Biomaterials for Mimicking and Modelling Tumor Micro-environment -- Chapter 7. Advancing Tumor Microenvironment Research by Combining Organs-on-chips and Biosensors -- Chapter 8. Microfluidic-driven Biofabrication and the Engineering of Cancer-like Microenvironments -- Chapter 9. Advances in 3d Vascularized Tumor-on-a-chip Technology -- Part 3. Cancer Detection and Diagnosis -- Chapter 10. Biosensors Advances: Contributions to Cancer Diagnostics and Treatment -- Chapter 11. Flexible Sensing Systems for Cancer Diagnostics -- Chapter 12. Coupling Micro-physiological Systems and Biosensors for Improving Cancer Biomarkers Detection -- Chapter 13. Microfluidic Biosensor-based Devices for Rapid Diagnosis and Effective Anti-cancer Therapeutic Monitoring for Breast Cancer Metastasis -- Chapter 14. Liquid Biopsies: Flowing Biomarkers -- Chapter 15. From Exosomes to Circulating Tumor Cells: Using Microfludics to Detect High Predictive Cancer Biomarkers -- Chapter 16. Microfluidics for the Isolation and Detection of Circulating Tumor Cells -- Chapter 17. Evolution in Automatized Detection of Cancer Cells: Advances in Magnetic Microcytometers -- Chapter 18. Droplet-based Microfluidic Chip Design, Fabrication and Use for Ultrahigh-throughput DNA Analysis and Quantification -- Chapter 19. Emerging Microfluidic and Biosensor Technologies for Improved Cancer Theranostics -- Part 4. Clinical Applications: Towards Personalized Medicine -- Chapter 20. Microfluidics for Cancer Biomarker Discovery, Research and Clinical Application -- Chapter 21. Methods for the Detection of Circulating Biomarkers in Cancer Patients -- Chapter 22. Advances in Microfluidics for the Implementation of Liquid Biopsy in Clinical Routine.

Abstract: This book offers a comprehensive overview of the development and application of microfluidics and biosensors in cancer research, in particular, their applications in cancer modeling and theranostics. Over the last decades, considerable effort has been made to develop new technologies to improve the diagnosis and treatment of cancer. Microfluidics has proven to be a powerful tool for manipulating biological fluids with high precision and efficiency and has already been adopted by the pharmaceutical and biotechnology industries. With recent technological advances, particularly biosensors, microfluidic devices have increased their usefulness and importance in oncology and cancer research. The aim of this book is to bring together in a single volume all the knowledge and expertise required for the development and application of microfluidic systems and biosensors in cancer modeling and theranostics. It begins with a detailed introduction to the fundamental aspects of tumor biology, cancer biomarkers, biosensors and microfluidics. With this knowledge in mind, the following sections highlight important advances in developing and applying biosensors and microfluidic devices in cancer research at universities and in the industry. Strategies for identifying and evaluating potent disease biomarkers and developing biosensors and microfluidic devices for their detection are discussed in detail. Finally, the transfer of these technologies into the clinical environment for the diagnosis and treatment of cancer patients will be highlighted. By combining the recent advances made in the development and application of microfluidics and biosensors in cancer research in academia and clinics, this book will be useful literature for readers from a variety of backgrounds. It offers new visions of how this technology can influence daily life in hospitals and companies, improving research methodologies and the prognosis of cancer patients.

Type of Medium: Online Resource

Pages: XIX, 590 p. 100 illus., 99 illus. in color. , online resource.

Edition: 1st ed. 2022.

ISBN: 9783031040399

Series Statement: Advances in Experimental Medicine and Biology, 1379

URL: https://doi.org/10.1007/978-3-031-04039-9

DOI: 10.1007/978-3-031-04039-9

DDC: 571.978

Language: English

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Biomaterials- and Microfluidics-Based Tissue Engineered 3D Models (2020)

Oliveira, J. Miguel. [editor.] ; Reis, Rui L. [editor.]

Cham :Springer International Publishing :

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Keywords: Medicine Research. ; Biology Research. ; Regenerative medicine. ; Biomedical engineering. ; Biomaterials. ; Biomedical Research. ; Regenerative Medicine and Tissue Engineering. ; Biomedical Engineering and Bioengineering. ; Biomaterials.

Description / Table of Contents: Microfluidic devices and three dimensional-printing strategies for in vitro models of bone -- Microfluidics for Processing of biomaterials -- Organ-on-a-chip -- Body-on-a-chip: Current challenges -- Biomaterials and microfluidics for liver models -- Microfluidics for CNS research -- Biomaterials and microfluidics for angiogenesis research -- Biomaterials and microfluidics for drug discovery and development -- Microfluidics for diagnostics -- Nanoparticles and Microfluidic devices in cancer research.

Abstract: This contributed volume reviews the latest advances on relevant 3D tissue engineered in vitro models of disease making use of biomaterials and microfluidics. The main focus of this book is on advanced biomaterials and microfluidics technologies that have been used in in vitro mimetic 3D models of human diseases and show great promise in revolutionizing personalized medicine. Readers will discover important topics involving biomaterials and microfluidics design, advanced processing techniques, and development and validation of organ- and body-on-a-chip models for bone, liver, and cancer research. An in depth discussion of microfabrication methods for microfluidics development is also provided. This work is edited by two truly multidisciplinary scientists and includes important contributions from well-known experts in their fields. The work is written for both early stage and experienced researchers, and well-established scientists enrolled in the fields of biomaterials, microfluidics, and tissue engineering, and is especially suited to those who wish to become acquainted with the principles and latest developments of in vitro models of diseases, such as professionals working in pharma, medicine, and engineering.

Type of Medium: Online Resource

Pages: VII, 175 p. 42 illus., 40 illus. in color. , online resource.

Edition: 1st ed. 2020.

ISBN: 9783030365882

Series Statement: Advances in Experimental Medicine and Biology, 1230

URL: https://doi.org/10.1007/978-3-030-36588-2

DOI: 10.1007/978-3-030-36588-2

DDC: 610.72

Language: English

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Biomimetic Synthesis of a Strontium-Substituted Apatite Coating Grown on Ti〈sub〉6〈/sub〉Al〈sub〉4〈/sub〉V Substrate (2007)

Oliveira, A.L. ; Reis, Rui L. ; Li, Pan Jian

s.l. ; Stafa-Zurich, Switzerland

Key engineering materials Vol. 330-332 (Feb. 2007), p. 585-588

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ISSN: 1013-9826

Source: Scientific.Net: Materials Science & Technology / Trans Tech Publications Archiv 1984-2008

Topics: Mechanical Engineering, Materials Science, Production Engineering, Mining and Metallurgy, Traffic Engineering, Precision Mechanics

Notes: In this study we explore the possibility of incorporating Sr into nano-apatite coatingsprepared by a solution-derived biomimetic methodology for coating titanium based implants. Theway this element is incorporated in the apatite structure and its effects on the stereochemistry andmorphology of the resulting apatite layers were investigated, as well as the resulting mineralizationkinetics. The presence of Sr in solution induced an inhibitory effect on mineralization, leading to adecrease in the thickness of the mineral layers. This ion was incorporated in the apatite structurethrough a substitution mechanism by replacing Ca in the crystal lattice. The obtained Sr-substitutedbiomimetic coatings are expected to enhance bone formation and osteointegration

Type of Medium: Electronic Resource

URL: http://www.tib-hannover.de/fulltexts/2011/0528/01/52/transtech_doi~10.4028%252Fwww.scientific.net%252FKEM.330-332.585.pdf

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Formation of Bone-Like Apatite on Polymeric Surfaces Modified with -SO〈sub〉3〈/sub〉H Groups (2006)

Leonor, Isabel B. ; Kim, Hyun Min ; Balas, Francisco ; [et al.]

s.l. ; Stafa-Zurich, Switzerland

Materials science forum Vol. 514-516 (May 2006), p. 966-969

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ISSN: 1662-9752

Source: Scientific.Net: Materials Science & Technology / Trans Tech Publications Archiv 1984-2008

Topics: Mechanical Engineering, Materials Science, Production Engineering, Mining and Metallurgy, Traffic Engineering, Precision Mechanics

Notes: Sulfonic groups (-SO3H) were covalently attached on different polymeric surfaces enabling them to induce apatite nucleation, for developing bioactive apatite-polymer composites with a bonelike 3-dimensional structure. High molecular weight polyethylene (HMWPE) and ethylene-co-vinyl alcohol co-polymer (EVOH) were used. The polymers were soaked in two types of sulphate-containing solutions with different concentrations, sulphuric acid (H2SO4) and chlorosulfonic acid (ClSO3H). To incorporate calcium ions into to the sulfonated polymers, thesamples were soaked in a saturated Ca(OH)2 solution for 24 hours. After soaking of the samples in a simulated body fluid (SBF), formation of an apatite layer on both surfaces was observed. The results obtained prove the validity of the proposed concept and show that the -SO3H groups are effective on inducing apatite nucleation on the surface of these polymers

Type of Medium: Electronic Resource

URL: http://www.tib-hannover.de/fulltexts/2011/0528/02/12/transtech_doi~10.4028%252Fwww.scientific.net%252FMSF.514-516.966.pdf

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Bone Tissue Engineering Constructs Based on Starch Scaffolds and Bone Marrow Cells Cultured in a Flow Perfusion Bioreactor (2006)

Gomes, Manuela E. ; Reis, Rui L. ; Mikos, Antonious G.

s.l. ; Stafa-Zurich, Switzerland

Materials science forum Vol. 514-516 (May 2006), p. 980-984

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ISSN: 1662-9752

Source: Scientific.Net: Materials Science & Technology / Trans Tech Publications Archiv 1984-2008

Topics: Mechanical Engineering, Materials Science, Production Engineering, Mining and Metallurgy, Traffic Engineering, Precision Mechanics

Notes: This study aims to investigate the effect of culturing conditions (static and flow perfusion) on the proliferation and osteogenic differentiation of rat bone marrow (RBM) stromal cells seeded on two starch based three-dimensional scaffolds exhibiting distinct porous structures. For this purpose, it was selected: i) a scaffold based on SEVA-C (a blend of starch with ethylene vinyl alcohol) obtainedby extrusion with a blowing agent and ii) a scaffold based on SPCL (a blend of starch with polycaprolactone) obtained by a fiber bonding process.The obtained results suggest that flow perfusion culture enhances the osteogenic differentiation of RBM cells and improves their distribution in 3-D starch-based scaffolds, by improving nutrients delivery in the interior of the scaffolds and simultaneously by stimulating the seeded cells by exposingthem to fluid shear forces. They also indicate that scaffold architecture and pore interconnectivity affect the homogeneity of the formed tissue

Type of Medium: Electronic Resource

URL: http://www.tib-hannover.de/fulltexts/2011/0528/02/12/transtech_doi~10.4028%252Fwww.scientific.net%252FMSF.514-516.980.pdf

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Physicochemical Characterization of Novel Chitosan-Soy Protein/ TEOS Porous Hybrids for Tissue Engineering Applications (2006)

Silva, S.S. ; Oliveira, J. Miguel ; Mano, João F. ; [et al.]

s.l. ; Stafa-Zurich, Switzerland

Materials science forum Vol. 514-516 (May 2006), p. 1000-1004

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ISSN: 1662-9752

Source: Scientific.Net: Materials Science & Technology / Trans Tech Publications Archiv 1984-2008

Topics: Mechanical Engineering, Materials Science, Production Engineering, Mining and Metallurgy, Traffic Engineering, Precision Mechanics

Notes: In this paper we report a new type of cross-linked porous structure based on a chitosansoy protein blend system developed by means of combining a sol-gel process with the freeze-drying technique. The final structure was investigated by Fourier transform infrared spectroscopy with attenuated total reflectance (FTIR-ATR), contact angle measurements and the morphology by scanning electron microscopy (SEM). The water uptake capability and the weight loss weremeasured up to 14 days and their mechanical properties were assessed with compression tests. Results showed that the addition of tetraethyl orthosilicate (TEOS) to the chitosan-soy protein blend system provide specific interactions at the interface between the two polymers allowing to tailor the size and distribution as well as the degradation rate of the hybrids. Finally, TEOS incorporation induces an increase of the surface energy that influences the final physicochemical properties of the materials

Type of Medium: Electronic Resource

URL: http://www.tib-hannover.de/fulltexts/2011/0528/02/12/transtech_doi~10.4028%252Fwww.scientific.net%252FMSF.514-516.1000.pdf

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Enzymatic Degradation Behaviour of Starch Conjugated Phosphorylated Chitosan (2006)

Baran, Erkan Turker ; Jayakumar, Rangasamy ; Mano, João F. ; [et al.]

s.l. ; Stafa-Zurich, Switzerland

Materials science forum Vol. 514-516 (May 2006), p. 995-999

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ISSN: 1662-9752

Source: Scientific.Net: Materials Science & Technology / Trans Tech Publications Archiv 1984-2008

Topics: Mechanical Engineering, Materials Science, Production Engineering, Mining and Metallurgy, Traffic Engineering, Precision Mechanics

Notes: Phosphorylated chitosan (P-chitosan) was synthesized by means of graftcopolymerization technique. The conjugate membranes were prepared from oxidised starch and Pchitosan using reductive alkylation crosslinking. The synthesized membranes were characterised by FT-IR. In order to characterize degradation behaviour of this conjugated system, the membranes were incubated in enzyme solutions of alpha-amylase and lysozyme as well as a physiologicalsaline solution (PBS) used as control solution. In PBS, low starch containing membranes (0.16-0.38 weight (starch)/weight (P-chitosan), (ws/wc)) and control membranes have not showed significant change in their weight during two months of incubation. High starch containing membranes (0.73-1.04ws/wc) indicated less than 20 % weight loss after this period. After α-amylase incubation, a distinct degradation behaviour was observed from starch-P-chitosan membranes. The degradation of the conjugate membranes was found to be fast with increasing starch content. Weight losses between 20 to 55 % were detected for the lowest (0.16 ws/wc) starch and highest (1.04 ws/wc) starch containing membranes, respectively. In the lysozyme degradation study, the conjugate membranes were not degraded by enzymatic activity and the weights of membranes were seen to be increased about 20 % because of swelling. The control membranes showed gradual weight loss in enzyme solutions. These results indicated the lysozyme degradation of starch-free P-chitosan membranes and inhibition of degradation P-chitosan by highly conjugated starch molecules

Type of Medium: Electronic Resource

URL: http://www.tib-hannover.de/fulltexts/2011/0528/02/12/transtech_doi~10.4028%252Fwww.scientific.net%252FMSF.514-516.995.pdf

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β-PVDF Membranes Induce Cellular Proliferation and Differentiation in Static and Dynamic Conditions (2008)

Rodrigues, M.T. ; Gomes, Manuela E. ; Mano, João F. ; [et al.]

s.l. ; Stafa-Zurich, Switzerland

Materials science forum Vol. 587-588 (June 2008), p. 72-76

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ISSN: 1662-9752

Source: Scientific.Net: Materials Science & Technology / Trans Tech Publications Archiv 1984-2008

Topics: Mechanical Engineering, Materials Science, Production Engineering, Mining and Metallurgy, Traffic Engineering, Precision Mechanics

Notes: Bone marrow cells are a potential source to induce different lineage cells which can beused to rebuild or replace damaged tissues using a Tissue Engineering (TE) approach. However, TEstrategies usually require the use of a material to support the development of a biological tissue.Beta-polyvinylidene fluoride (β-PVDF) is a biocompatible, thermoplastic with piezo-electricalproperties that has been shown to provide a good cellular attachment and therefore might presentadvantageous properties as a scaffold material for cell seeding/culturing. The present studydescribes the characterization of β-PVDF membranes as a support material for growth anddifferentiation of goat marrow cells (GMCs) into osteoblasts, leading to the formation of substitutesfor tissue regeneration.The obtained results suggest that β-PVDF piezoelectric properties influence cellular behavior. β-PVDF membranes not only enhance GMCs adherence and proliferation but also improvedifferentiation towards the osteogenic phenotype both in static and dynamic culture conditions.Furthermore, β-PVDF membranes exhibit very promising properties, suggesting that this materialprovides adequate support for the seeding and the development of undifferentiated cells towards adesired phenotype

Type of Medium: Electronic Resource

URL: http://www.tib-hannover.de/fulltexts/2011/0528/02/19/transtech_doi~10.4028%252Fwww.scientific.net%252FMSF.587-588.72.pdf

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