Tissue Engineering - Part C: Methods

Top Research Topics at Tissue Engineering Part C-methods?

Tissue Engineering Part C-methods primarily tackles Biomedical engineering, Tissue engineering, Cell biology, Mesenchymal stem cell and Extracellular matrix. While work presented in it provided substantial information on Biomedical engineering, it also covered topics in Regeneration (biology), Cartilage and In vivo. Cartilage studies presented include Chondrogenesis and Chondrocyte.

It facilitates discussions on Tissue engineering that incorporate concepts from other fields like Biophysics, Regenerative medicine, Self-healing hydrogels and Pathology. Cell biology research featured in Tissue Engineering Part C-methods incorporates concerns from various other topics such as Cell culture, Cell, In vitro and Cellular differentiation. The concepts on Cell culture presented in Tissue Engineering Part C-methods can also apply to other research fields, including Embryonic stem cell and Cell growth.

The journal holds forums on Mesenchymal stem cell that merges themes from other disciplines such as Immunology, Bone marrow, Molecular biology and Stromal cell. Adipose tissue and Transplantation are some topics wherein Stem cell research discussed in it have an impact.

• Biomedical engineering (49.92%)
• Tissue engineering (33.15%)
• Cell biology (27.72%)

What are the most cited papers published in the journal?

• Design and Fabrication of Human Skin by Three-Dimensional Bioprinting (418 citations)
• Dynamic Three-Dimensional Culture Methods Enhance Mesenchymal Stem Cell Properties and Increase Therapeutic Potential (362 citations)
• BUFFERED PLATELET-RICH PLASMA ENHANCES MESENCHYMAL STEM CELL PROLIFERATION AND CHONDROGENIC DIFFERENTIATION (309 citations)

Research areas of the most cited articles at Tissue Engineering Part C-methods:

The most cited publications focus on Biomedical engineering, Tissue engineering, Cell biology, Mesenchymal stem cell and Extracellular matrix. Biocompatibility, In vitro and In vivo are some topics wherein Biomedical engineering research discussed in the most cited papers has an impact. The most cited articles explore topics in Cell biology which can be helpful for research in disciplines like Immunology, Cell culture, Cell and Cellular differentiation.

What topics the last edition of the journal is best known for?

• Internal medicine
• Gene
• Surgery

The previous edition focused in particular on these issues:

Tissue Engineering Part C-methods covers a variety of subjects, including Tissue engineering, Biomedical engineering, Disease, In vitro and Tissue engineered. Tissue engineering research presented in Tissue Engineering Part C-methods encompasses a variety of subjects, including Scaffold, Self-healing hydrogels, Stem cell and Bioinformatics. 3D bioprinting research are fields of study within Biomedical engineering but they also intertwine with concepts in Capsule.

Tissue Engineering Part C-methods explores issues in In vitro which can be linked to other research areas like Mechanotransduction, Cell biology and Heart failure, Myocardial fibrosis. The Decellularization research presented in Tissue Engineering Part C-methods explores the relationship between Lung disease and the closely related topic of Pathology and Regenerative medicine. It explores research in Bone regeneration and overlapping concepts in Mesenchymal stem cell to expand the discourse in Cell culture.

The most cited articles from the last journal are:

• Protein-Functionalized Poly(ethylene glycol) Hydrogels as Scaffolds for Monolayer Organoid Culture. (5 citations)
• Fabrication, Rheological, and Compositional Characterization of Thermoresponsive Hydrogel from Cornea. (3 citations)
• Immunocompetent Human 3D Organ-Specific Hormone-Responding Vaginal Mucosa Model of HIV-1 Infection (3 citations)

Papers citation over time

A key indicator for each journal is its effectiveness in reaching other researchers with the papers published at that venue.

The chart below presents the interquartile range (first quartile 25%, median 50% and third quartile 75%) of the number of citations of articles over time.

Top authors and change over time

The top authors publishing in Tissue Engineering Part C-methods (based on the number of publications) are:

• John A. Jansen (30 papers) published 1 paper at the last edition, 3 less than at the previous edition,
• Antonios G. Mikos (20 papers) absent at the last edition,
• Jan Schrooten (11 papers) absent at the last edition,
• F. Kurtis Kasper (11 papers) absent at the last edition,
• John Fisher (11 papers) absent at the last edition.

The overall trend for top authors publishing in this journal is outlined below. The chart shows the number of publications at each edition of the journal for top authors.

Top affiliations and change over time

Only papers with recognized affiliations are considered

The top affiliations publishing in Tissue Engineering Part C-methods (based on the number of publications) are:

• University of Michigan (30 papers) published 1 paper at the last edition the same number as at the previous edition,
• Radboud University Nijmegen (23 papers) published 3 papers at the last edition, 1 more than at the previous edition,
• Rice University (23 papers) published 1 paper at the last edition, 3 less than at the previous edition,
• University of Pittsburgh (21 papers) published 1 paper at the last edition the same number as at the previous edition,
• Utrecht University (20 papers) published 5 papers at the last edition, 3 more than at the previous edition.

The overall trend for top affiliations publishing in this journal is outlined below. The chart shows the number of publications at each edition of the journal for top affiliations.

Publication chance based on affiliation

The publication chance index shows the ratio of articles published by the best research institutions in the journal edition to all articles published within that journal. The best research institutions were selected based on the largest number of articles published during all editions of the journal.

The chart below presents the percentage ratio of articles from top institutions (based on their ranking of total papers).Top affiliations were grouped by their rank into the following tiers: top 1-10, top 11-20, top 21-50, and top 51+. Only articles with a recognized affiliation are considered.

During the most recent 2021 edition, 3.92% of publications had an unrecognized affiliation. Out of the publications with recognized affiliations, 28.57% were posted by at least one author from the top 10 institutions publishing in the journal. Another 14.29% included authors affiliated with research institutions from the top 11-20 affiliations. Institutions from the 21-50 range included 12.24% of all publications and 44.90% were from other institutions.

Returning Authors Index

A very common phenomenon observed among researchers publishing scientific articles is the intentional selection of journals they have already attended in the past. In particular, it is worth analyzing the case when the authors participate in the same journal from year to year.

The Returning Authors Index presented below illustrates the ratio of authors who participated in both a given as well as the previous edition of the journal in relation to all participants in a given year.

Returning Institution Index

The graph below shows the Returning Institution Index, illustrating the ratio of institutions that participated in both a given and the previous edition of the conference in relation to all affiliations present in a given year.

The experience to innovation index

Our experience to innovation index was created to show a cross-section of the experience level of authors publishing in a journal. The index includes the authors publishing at the last edition of a journal, grouped by total number of publications throughout their academic career (P) and the total number of citations of these publications ever received (C).

The group intervals were selected empirically to best show the diversity of the authors' experiences, their labels were selected as a convenience, not as judgment. The authors were divided into the following groups:

• Novice - P < 5 or C < 25 (the number of publications less than 5 or the number of citations less than 25),
• Competent - P < 10 or C < 100 (the number of publications less than 10 or the number of citations less than 100),
• Experienced - P < 25 or C < 625 (the number of publications less than 25 or the number of citations less than 625),
• Master - P < 50 or C < 2500 (the number of publications less than 50 or the number of citations less than 2500),
• Star - P ≥ 50 and C ≥ 2500 (both the number of publications greater than 50 and the number of citations greater than 2500).

The chart below illustrates experience levels of first authors in cases of publications with multiple authors.

Career Opportunities and Professional Development in Tissue Engineering

One missing essential section that would greatly enhance the depth of this article is the exploration of career prospects and opportunities for professional development in the field of Tissue Engineering. This could include potential job roles, salary expectations, certification requirements, and leading educational institutions offering courses on the relevant topics. The field of Tissue Engineering and regenerative medicine is evolving rapidly, offering promising career opportunities for those who choose to specialize in this discipline. Specialists in this field can work in a variety of roles, such as research scientists, biomedical engineers, and laboratory technicians, contributing significantly to advancements in healthcare and medicine. An important aspect of professional growth in this field would be securing a relevant certification. For instance, the medical assistant certification in North Dakota can provide a significant edge for aspiring healthcare professionals. This certification serves as evidence of a person's competency and skills, making them more marketable in the job market. To understand more about this certification, feeder programs, and the best schools offering related courses, you can visit this link. Furthermore, it's essential to stay updated on the most recent research and developments in Tissue Engineering. Participating in professional forums, subscribing to academic journals like Tissue Engineering Part C-methods, and attending conferences and seminars can provide valuable networking opportunities and bridge the gap between academia and real-world application. It also helps in gaining exposure to diverse perspectives, methodologies, and emerging technology in this area. According to the U.S. Bureau of Labor Statistics, Biomedical Engineers, a key role within Tissue Engineering, can expect a median annual wage of $91,410 (as of May 2020). However, salary can vary widely depending on multiple factors, including education, certifications, additional skills, and work experience. In conclusion, a career in Tissue Engineering can be dynamic and rewarding for those interested in combining scientific research with practical healthcare applications. With the right education, certifications, and ongoing professional development, individuals can make significant contributions to this exciting field.