Journal Of Tissue Science & Engineering Impact Factor – Journal of Tissue Science and Engineering uses physical, chemical, and biological agents to replace and/or improve the biological functions of the cell. The journal covers a wide range of applications in cell biology including seeding, cultivation and promotion, new drug design and delivery, nanomedicine and technology, non-invasive surgical techniques, stem cell therapy, gene therapy, regenerative medicine, and stem cell transplantation techniques. .

The journal includes a wide range of disciplines in its training to create a platform for authors to contribute to the journal and the editorial office undertakes a peer review process for submitted manuscripts for publication.

Journal Of Tissue Science & Engineering Impact Factor

Journal Of Tissue Science & Engineering Impact Factor

The Journal of Tissue Science and Engineering is a multidisciplinary journal that promotes the publication of well-reviewed original manuscripts such as research articles, review articles, case studies, short communications and letters to the editor in open access.

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Hilaris Publishing offers many opportunities, options and services for would-be authors to publish their academic contributions.

The journal addresses the needs of rapid publication without compromising on editorial quality including manuscript review. This flexibility is provided for the purpose of ensuring the author’s credibility from the outset in their contribution and this will ensure the timely dissemination of research results for better integration, effective translation and reduction of redundancy.

Authors have the option to choose between a regular open publishing service that takes its time for the full publication process or they can choose an accelerated publishing service where the article is published on the first day (Includes many academic experts authorized for early peer protection. -review comments). Authors may use this flexibility based on personal preference, funding agency guidelines or Institutional or organizational requirements.

Authors who wish to publish their articles under this mode can make an upfront payment of $99 in exchange for peer review and an editorial decision. Initial editorial decision within 3 days and final decision and review comments within 5 days from submission date. The production of Galley proof will be done in the next 2 days from the approval or a maximum of 5 days (For manuscripts brought to be reviewed by an external reviewer).

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The authors retain the copyright of their publication and the final version of the article will be published in both HTML and PDF formats as well as XML formats for posting to the database. The Journal’s editorial team will ensure compliance with the principles of scientific publication.

Articles published in the Journal of Tissue Science and Engineering are cited by respected scholars and scientists worldwide. The Journal of Tissue Science and Engineering has an h-index of 14, which means that every article in the Journal of Tissue Science and Engineering has 14 citations. Early Fragmentation of Bovine Dermis-Derived Collagen Barrier Membrane Contributes to Transmembraneous Vascularization-A Possible Paradigm Shift for Guided Bone Remodeling

Center’s Open Access Program on Special Issues Guidelines for Research Design and Research Ethics Article Payment Arrangements Special Awards

Journal Of Tissue Science & Engineering Impact Factor

All published articles are made immediately available worldwide under an open access license. No special permission is required to reproduce all or part of an article published by , including figures and tables. For articles published under the open access Creative Commons CC BY license, any part of the article may be reused without permission unless the original article is clearly cited. For more information, please visit https:///openaccess.

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Brand papers represent the highest quality research with significant potential for high impact in the field. A Feature Paper should be a large original article that covers several methods or approaches, provides an overview of future research directions and describes possible research applications.

Submitted papers are submitted on invitation or individual recommendation by scientific editors and must receive positive feedback from reviewers.

Editor’s Choice articles are based on the recommendations of scientific editors of journals from around the world. The editors select a small number of recently published articles in the journal that they believe will be of particular interest to readers, or of particular importance to the research area. The aim is to provide a summary of the most interesting work published in different areas of research in the journal.

By Mathilde Fénelon Mathilde Fénelon Scilit Google Scholar View Publications 1, 2 , Sylvain Catros Scilit Google Scholar View Publications -Christophe Fricain Jean-Christophe Fricain Scilit Google Scholar View Publications 1, 2 , Laurent Obert Laurent Obert Scilit Google Scholar View Publications 3, 5 , 7 , Aurélien Louvrier Aurélien Louvrier Scilit Google Scholar View Publications 4, 8 and Florelle Gindraux Florelle Gindraux Scilit Google Scholar View Publications 3, 5, *

Using Migrating Cells As Probes To Illuminate Features In Live Embryonic Tissues

Entry Received: 10 April 2021 / Revised: 18 May 2021 / Accepted: 20 May 2021 / Published: 25 May 2021

An important part of tissue engineering (TE) is the supporting matrix in which cells and tissues grow, known as the scaffold. The scaffolds should integrate easily with the host tissue and provide an excellent environment for cell growth and differentiation. Human amniotic membrane (hAM) is considered a surgical waste without ethical issues, so it is an abundant, inexpensive, and readily available biomaterial. Biocompatibility, low immunogenicity, adequate mechanical properties (tolerance, stability, durability, flexibility, reconfiguration), and good cell adhesion. It uses anti-inflammatory, antifibrotic, and antimutagenic properties and pain-relieving effects. It is also a source of growth factors, cytokines, and hAM cells with stem cell properties. This important source of scaffolding material has been widely studied and used in different areas of tissue repair: corneal repair, chronic wound treatment, genital regeneration, tendon repair, microvascular repair, nerve repair, and intraoral regeneration. Depending on the intended application, hAM is used as a simple scaffold or seed with different types of cells capable of growth and differentiation. Thus, this natural biomaterial offers a wide range of applications in TE applications. Here, we explore the properties of hAM as a biocompatible and biodegradable scaffold. Strategies for its use (ie, alone or in combination with cells, cell seeding) and its degradation rate have also been demonstrated.

Tissue engineering (TE) aims to stimulate tissue growth by combining cells, scaffolds, and growth factors or biomolecules [1]. Therefore, cells require the development of a scaffold from natural or synthetic biomaterials, or a combination of the two, which mimics the extracellular matrix (ECM) [2]. The scaffold must have tissue integration properties and must be easily incorporated with cells and able to adhere, grow/survive, differentiate, and regenerate cell/tissue [3]. An ideal scaffold requires easy handling and production, as well as biocompatibility, biodegradability, and mechanical properties that match the anatomical location of the implant. Depending on the application, it can be selective (to avoid the attack of fibrous tissue [4]) or porous (to ensure cellular penetration and adequate distribution of nutrients to the cells within the structure and the ECM formed by these cells [3] ). When necessary, it must create and maintain a location [4].

Journal Of Tissue Science & Engineering Impact Factor

We have developed several TE products that combine cells with biocompatible scaffolds [5, 6]. We have been studying the benefits of amniotic membrane (hAM) in bone and nerve repair and oral and maxillofacial surgery for the past few years [7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18 , 19, 20, 21, 22, 23, 24].

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HAM from the placenta is considered surgical waste that may be recovered after elective surgical procedures. It is thus a highly abundant, readily available, and economical biological tissue that does not raise ethical issues. Thanks to its unique biological properties, this natural membrane has been used for more than a century in medicine, especially in the field of ophthalmology and dermatology [25, 26]. hAM is known to exhibit several biological properties capable of promoting wound healing. It is a biocompatible immune-privileged tissue that produces anti-inflammatory, antifibrotic, antimicrobial, and antimutagenic effects [27, 28]. hAM is a source of growth factors, cytokines, and hAM cells have stem cell properties [26, 29, 30]. Moreover, it combines sufficient mechanical properties (permeability, stability, elasticity, flexibility, resorbability) [31, 32] with cell adhesion capacity, due to the natural ECM structure (the hyaluronic acid, collagens, lamin, fibronectin, and proteoglycans) [33].

As a result, hAM represents a “ready to use” TE product, which contains natural cells and growth factors [34, 35, 36] (Figure 1). In addition, it is an ideal natural scaffold for cell seeding, proliferation, and/or differentiation. Thus, scaffolds based on hAM have been developed to improve their healing capacity and, in particular, to produce suitable TE structures.

The efficacy of hAM alone or in combination with cells has been extensively investigated in experimental and clinical studies. Therefore, its support function is emphasized by the development of ham composites and commercial products [9, 31, 32, 36]. The use of hAM cells in the field of TE is sporadic [37].

The purpose of this review is to describe the properties of hAM as a biocompatible and degradable scaffold for TE applications. Furthermore, expression of hAM used alone or in combination with cells is shown. We also aim to examine cell growth and degradation rate

Engineered Whole Cut Meat Like Tissue By The Assembly Of Cell Fibers Using Tendon Gel Integrated Bioprinting

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