3D Cell Cultures Markets, 2030 Dublin, Oct. 11,

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Posted On: 10/11/2017 6:00:22 AM

Posted By: News Desk 2018

3D Cell Cultures Markets, 2030

Dublin, Oct. 11, 2017 (GLOBE NEWSWIRE) -- The "3D Cell Cultures: Products, Technologies and Key Application Areas (2nd Edition), 2017-2030" report has been added to Research and Markets' offering. The 3D Cell Cultures: Products, Technologies and Key Application Areas (2nd Edition), 2017-2030' report features an extensive study on the various scaffold-based and scaffold-free 3D culture systems. We identified over 80 hydrogel / ECM based products, 70 inserts / plates / other cultureware and 50 3D bioreactors that are widely being used for a variety of research applications across the globe. In addition, several kits, assays and tools are also available to carry out cytotoxicity assessments, transfections and cell viability testing.

A number of research efforts in drug discovery are being directed towards the introduction of in vitro testing models that replicate the in vivo microenvironment and provide physiologically relevant insights. Cell culture monolayers or 2D cell cultures are known to harbor differences in morphology, growth rate, function, viability and the overall behavior, as compared to those in natural environment. However, it has been realized that 3D cell cultures facilitate cell interaction with the surrounding media in all the possible dimensions. Cells cultivated using 3D techniques provide an appropriate ecosystem for cells to grow and proliferate and, consequently generate more accurate results of the experiments conducted on them. The 3D cell culture industry is currently characterized by presence of several scaffold-based and scaffold-free products and services, widely being used for the purpose of research across a variety of application areas. Examples of scaffold-based 3D culture products include solid scaffolds, hydrogels, ECM-coated plates and microcarriers. Products, such as hanging drop plates, ultra-low attachment surfaces, micropatterned plates and suspension culture systems (such as 3D bioreactors), are some of the important scaffold-free 3D technologies that are currently available.

It is worth highlighting that despite the advantages that they offer, the adoption of 3D cell cultures is hindered by certain challenges. These cell culture systems are currently limited to small scale production of cells, thereby, restricting their use to research applications only. Moreover, 3D culture techniques still need to be optimized in order to ensure consistency of results generated across different scales of operation. Due to the aforementioned challenges, 2D cultures continue to be preferred over 3D culture systems; however, with increasing awareness of the advantages of 3D cultures, a significant proportion of researchers are anticipated to gradually transition towards 3D culture systems. It is well-known that, of the several drug / therapy candidates undergoing clinical evaluation, very few make it to advanced stages and an even lesser number receive regulatory approval. One of the key reasons for the failure of therapeutic candidates in clinical trials is the use of conventional 2D cell culture systems in early research studies. It is important to reiterate that these 2D systems are severely limited in a number of aspects.

Key Topics Covered:

1 PREFACE 1.1. Scope of the Report 1.2. Research Methodology 1.3. Chapter Outlines 2 EXECUTIVE SUMMARY 3 INTRODUCTION 3.1. Chapter Overview 3.2. Classification of Cell Cultures 3.3. Morphology of Cells in Culture 3.4. Transition from 2D to 3D Cell Culture 3.5. The Concept of 3D Cell Culture 3.6. Cell Cultures: Establishment and Maintenance 3.7. The Need for 3D Cell Culture Systems 3.8. Cell Culturing: Basic Requirements 3.9. 3D Cell Culture: Advantages and Limitations 3.10. Future Landscape of 3D Cell Culture 4 CLASSIFICATION OF 3D CELL CULTURE SYSTEMS 4.1 3D Cell Culture Classification: An Overview 4.2. Scaffold Based 3D Cell Cultures 4.3. Scaffold Free 3D Cell Cultures 4.4. Organoids 5 METHODS USED FOR FABRICATION OF 3D MATRICES AND SCAFFOLDS 5.1. Chapter Overview 5.2. Methods for Fabricating Porous Scaffolds 5.3. Methods for Fabricating Fibrous Scaffolds 5.4. Methods for Fabricating Hydrogels 5.5. Methods for Fabricating Custom Scaffolds 5.6. Methods for Fabricating Microspheres 5.7. Methods for Fabricating Native Scaffolds 6 MARKET OVERVIEW 6.1. Chapter Overview 6.2. 3D Cell Culture Products: List of Hydrogels/Extracellular Matrices (ECMs), Cultureware and Bioreactors 6.3. 3D Cell Culture Products: Assay Kits, Reagents and Services 7 3D CELL CULTURE: KEY APPLICATION AREAS 7.1. Chapter Overview 7.2. 3D Cell Culture Systems in Cancer Research 7.3. 3D Cell Culture Systems in Drug Discovery and Toxicity Screening 7.4. 3D Cell Culture Systems in Stem Cell Research 7.5. 3D Cell Culture Systems in Regenerative Medicine and Tissue Engineering 7.6. 3D Cell Culture Systems: Analyses on Key Application Areas 8 EMERGING TRENDS IN 3D CELL CULTURE ON SOCIAL MEDIA 8.1. Chapter Overview 8.2. 3D Cell Culture: Trends on Twitter 9 3D CELL CULTURE PRODUCTS: KEY PLAYERS 9.1. Chapter Overview 9.2. Developers of 3D Cultureware and ECMs/Hydrogels 9.2.1. 3D Biotek 9.2.2. Advanced BioMatrix 9.2.3. Alphabioregen 9.2.4. Corning Life Sciences 9.2.5. ReproCELL 9.3. Developers of Organs-on-Chips 9.3.1. CN Bio Innovations 9.3.2. Emulate 9.3.3. InSphero 9.3.4. MIMETAS 9.3.5. Nortis 9.3.6. TissUse 10 3D CULTURE BIOREACTORS: KEY PLAYERS 10.1. Chapter Overview 10.2.1 Celartia 10.2.2. Cell Culture Company 10.2.3. CESCO BioProducts 10.2.4. China Regenerative Medicine International 10.2.5. EBERS 10.2.6. PBS Biotech 10.2.7. Synthecon 11 MARKET FORECAST 11.1. Chapter Overview 11.2. Key Assumptions and Methodology 11.3. 3D Cell Culture Market Forecast, 2017-2030 12 SURVEY ANALYSIS 12.1. Chapter Overview 12.2. Overview of Respondents 12.3. Focus Area of the Company 12.4. Category of Lead Product(s) 12.5. Nature of Matrices 12.6. Development Status of Lead Product(s) 12.7. Sources of 3D Cultured Cells 12.8. Applications of 3D Cell Culture Products 12.9. Likely Market Size 13 CONCLUSION 13.1. 3D Cell Cultures, With Inherent Advantages over 2D Cell Cultures, are Gradually Gaining Attention in the Research Industry 13.2. Most 3D Cell Cultures Require a Supporting Scaffold for Growth and Propagation; However, Scaffold Free Techniques are Available as Well 13.3. Such Advanced Culture Systems have Found Use in a Myriad of Application Areas 13.4. Despite the Ongoing Innovation, 3D Cell Cultures are Yet to Unveil Potential in Mainstream Therapeutics 13.5. Post Mitigation of Associated Challenges, The Market is Likely to Witness a Higher Adoption 13.6. Overall, the 3D Cell Culture Market is Likely to Emerge as a Multi-Billion Dollar Market in the Long Term 14 INTERVIEW TRANSCRIPTS 14.1. Chapter Overview 14.2. Bill Anderson, President and Chief Executive Officer, Synthecon 14.3. Colin Sanctuary, Co-Founder and Chief Executive Officer, QGel 14.4. Darlene Thieken, Senior Management, Nanofiber Solutions 14.5. Jens Kelm, Chief Scientific Officer, InSphero 14.6. Scott Brush, VP Sales and Marketing, BRTI Life Sciences 14.7. Anonymous, President and Chief Executive Officer, Leading Company in 3D Cell Culture Domain 14.8. Anonymous, VP-Technical, Business Operations & Co-Founder, Leading Company in 3D Cell Culture Domain 15 APPENDIX: TABULATED DATA 16 APPENDIX: LIST OF COMPANIES AND ORGANIZATIONS

Companies Mentioned

101Bio
3D Biomatrix
3D Biotek
4titude
AbbVie
Accellta
ACEA Biosciences
Advanced BioMatrix
AIM Biotech
AK Biomedical
Akron Biotech
Alnylam Pharmaceuticals
Alphabioregen
AMS Biotechnology
Antleron
Applikon Biotechnology
ARL Designs
AstraZeneca
AUCTEQ Biosystems
AvantiCell Science
AxoSim
Bangalore Integrated System Solutions Tissue Growth Technologies (BiSS TGT)
BASF
BD Biosciences
BellBrook Labs
Benitec Biopharma
Bio-Byblos Biomedical
BioCellChallenge
BioConnect
Biogelx
Biomaterials
BioMedical Tissues
Biomerix
Biomimiq
Biopta
Biotronix
Boston Institute of Biotechnology
Bristol-Myers Squibb
BRTI Life Sciences
Celartia
Celenys
Cell Culture Company
Cellec Biotek
Cellendes
Cellevate
CellSpring
CellSystems
CelVivo
CESCO BioProducts
Cherry Biotech
China Regenerative Medicine International
China Stem Cell Clinical Applications Centre
CN Bio Innovations
Corning Life Sciences
Cosmo Bio
Covance
Cyprotex
CYTOO
Dunn Labortechnik
Durham University
East River BioSolutions
EBERS
Ectica Technologies
EMD Millipore
Emulate
EPISKIN
Epithelix
Eppendorf
ESI BIO
ETH Zurich
Fennik Life Sciences
FiberCell Systems
Fraunhofer IGB
Fraunhofer IWS
FUJIFILM
GE Healthcare
GeneON
GlaxoSmithKline
Global Cell Solutions
Greiner Bio-One
HREL Corporation
Hamilton Company
HK International Regenerative Centre
Hokkaido Soda
Humeltis
Imperial College London
InSphero
Instron
InvitroCue
InvivoSciences
Iris Biosciences
Japan Vilene
Johnson & Johnson
J-TEC
KU Leuven
Kirkstall
KIYATEC
Koken
Kollodis BioSciences
Kuraray
LAMBDA Laboratory Instruments
Leibniz Research Centre for Working Environment and Human Factors
Lena Biosciences
LFB Biomanufacturing
Life Technologies
Lifecore Biomedical
Linari Engineering
Locate Therapeutics
Lonza
LuoLabs
Massachusetts Institute of Technology
MatTek
MBL International
MD Biosciences
Menicon Life Science
Merck
MicroTissues
MIMETAS
Mirus Bio
MRC Centre for Drug Safety Science
Nano3D Biosciences
Nanofiber Solutions
Nanogaia
National Cancer Institute
NC3Rs
Neuromics
Nortis
Novadip
ORGANOGENIX
Organovo
PBS Biotech
PELOBiotech
PepGel
Percell Biolytica
Pfizer
Pishon Biomedical
Pluristem Therapeutics
ProBioGen
Promega
ProSys
Protista
QGel Bio
Quinxell Technologies
Radboudumc
RealBio Technology
RegeneMed
Reinnervate
ReproCELL
Roche
Sanofi
Sarstedt
Sartorius Stedim Biotech
SCIVAX Life Sciences
Seres Therapeutics
Sigma-Aldrich
SKE Research Equipment
SkinAxis
SoloHill Engineering
SpheriTech
StemCell Systems
STEMCELL Technologies
Stemmatters
Stratatech
StratiCELL
Sumitomo Bakelite
SUN Bioscience
Synthecon
SynVivo
TAP Biosystems
TARA Biosystems
The Well Bioscience
Thermo Fisher Scientific
Tianjin Weikai Bioeng
TissueClick
TissUse
Trevigen
TU Berlin
TU Dortmund
UB-Care
Univalor
University College London
University of Liverpool
University of Oxford
University of Pittsburgh
University of Zaragoza
University of Zurich
University of Wrzburg
UPM Biochemicals
Utrecht University
Viscofan BioEngineering
Vivo Biosciences
Wyss Institute at Harvard University

For more information about this report visit https://www.researchandmarkets.com/research/w...l_cultures

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