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プロフィール詳細
プロジェクトを作成
★★★★★
☆☆☆☆☆
Alireza S.に依頼
United Arab Emirates

Scientist & Founder | Tissue Engineering, Cell Therapy, FDA Regulatory & Product Development | PhD

プロフィール概要
専門分野
サービス
Writing Technical Writing, Creative Writing
Research Market Research, Feasibility Study, Technology Scouting, Fact Checking, Gap Analysis, Scientific and Technical Research, Systematic Literature Review
Consulting Business Strategy Consulting, Go-to-Market Strategy Consulting, Scientific and Technical Consulting, Regulatory Consulting, Manufacturing Consulting
Data & AI Predictive Modeling, Image Processing, Image Analysis, Algorithm Design-ML, Data Visualization, Big Data Analytics
Product Development Formulation, Recipe Development, Stability/Shelf Life Testing, Product Evaluation, Manufacturing, Product Compliance , Concept Development, Prototyping, Reverse Engineering, Device Fabrication
職務経験

CEO

Evolved Bio

9月 2021 - 現在

Postdoctoral Fellow

McMaster University

9月 2020 - 8月 2021

学歴

PhD (school of biomedical engineering)

McMaster University

5月 2017 - 現在

MSc of Tissue Engineering (Department of Biomedical Engineering)

Amirkabir University of Technology

10月 2014 - 9月 2016

BSc of Biomaterials (Department of Biomedical Engineering)

Amirkabir University of Technology

1月 2011 - 9月 2014

BSc of Biomechanics (Department of Biomedical Engineering)

Amirkabir University of Technology

9月 2009 - 9月 2014

認定資格
  • Machine Learning

    Vector Institute

    10月 2023 - 現在

出版物
JOURNAL ARTICLE
Crystal O. Mahadeo, Alireza Shahin-Shamsabadi, Maedeh Khodamoradi, Margaret Fahnestock, Ponnambalam Ravi Selvaganapathy (2025). The Effects of Electrical Stimulation on a 3D Osteoblast Cell Model . Cells.
Crystal O. Mahadeo, Alireza Shahin-Shamsabadi, Maedeh Khodamoradi, Margaret Fahnestock, Ponnambalam Ravi Selvaganapathy (2025). The Effects of Electrical Stimulation on a 3D Osteoblast Cell Model . Cells.
Mahadeo, C.O., Shahin-Shamsabadi, A., Khodamoradi, M., Fahnestock, M., Selvaganapathy, P.R.(2025). The Effects of Electrical Stimulation on a 3D Osteoblast Cell Model . Cells. 14. (6).
Shahin-Shamsabadi, A., Cappuccitti, J.(2025). Muscle-specific acellular ECM fibers made with anchored cell sheet engineering support regeneration in rat models of volumetric muscle loss . Acta Biomaterialia. 200. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 416-431.
Alireza Shahin‐Shamsabadi, John Cappuccitti (2024). Anchored Cell Sheet Engineering: A Novel Scaffold‐Free Platform for in vitro Modeling (Adv. Funct. Mater. 13/2024) . Advanced Functional Materials.
Alireza Shahin‐Shamsabadi, John Cappuccitti (2024). Anchored Cell Sheet Engineering: A Novel Scaffold‐Free Platform for in vitro Modeling . Advanced Functional Materials.
Shahin-Shamsabadi, A., Cappuccitti, J.(2024). Anchored Cell Sheet Engineering: A Novel Scaffold-Free Platform for in vitro Modeling . Advanced Functional Materials. 34. (13).
Shahin-Shamsabadi, A., Selvaganapathy, P.R.(2022). Engineering Murine Adipocytes and Skeletal Muscle Cells in Meat-like Constructs Using Self-Assembled Layer-by-Layer Biofabrication: A Platform for Development of Cultivated Meat . Cells Tissues Organs. 211. (3). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 304-312.
Li, F.-C., Shahin-Shamsabadi, A., Selvaganapathy, P.R., Kishen, A.(2022). Engineering a Novel Stem Cells from Apical Papilla-Macrophages Organoid for Regenerative Endodontics . Journal of Endodontics. 48. (6). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 741-748.
Alireza Shahin-Shamsabadi, P. Ravi Selvaganapathy (2020). π-SACS: pH Induced Self-Assembled Cell Sheets Without the Need for Modified Surfaces . ACS Biomaterials Science & Engineering.
Dabaghi, M., Rochow, N., Saraei, N., Fusch, G., Monkman, S., Da, K., Shahin-Shamsabadi, A., Brash, J.L., Predescu, D., Delaney, K., et al.(2020). A Pumpless Microfluidic Neonatal Lung Assist Device for Support of Preterm Neonates in Respiratory Distress . Advanced Science. 7. (21).
Shahin-Shamsabadi, A., Selvaganapathy, P.R.(2020). π-SACS: PH Induced Self-Assembled Cell Sheets without the Need for Modified Surfaces . ACS Biomaterials Science and Engineering. 6. (9). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 5346-5356.
Bryan E. J. Lee, Alireza Shahin‐Shamsabadi, Michael K. Wong, Sandeep Raha, Ponnambalam Ravi Selvaganapathy, Kathryn Grandfield (2019). A Bioprinted In Vitro Model for Osteoblast to Osteocyte Transformation by Changing Mechanical Properties of the ECM . Advanced Biosystems.
Alireza Shahin-Shamsabadi, P Ravi Selvaganapathy (2019). ExCeL: combining extrusion printing on cellulose scaffolds with lamination to createin vitrobiological models . Biofabrication.
Shahin-Shamsabadi, A., Selvaganapathy, P.R.(2019). ExCeL: Combining extrusion printing on cellulose scaffolds with lamination to create in vitro biological models . Biofabrication. 11. (3).
Shahin-Shamsabadi, A., Selvaganapathy, P.R.(2019). A rapid biofabrication technique for self-assembled collagen-based multicellular and heterogeneous 3D tissue constructs . Acta Biomaterialia. 92. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 172-183.
Lee, B.E.J., Shahin-Shamsabadi, A., Wong, M.K., Raha, S., Selvaganapathy, P.R., Grandfield, K.(2019). A Bioprinted In Vitro Model for Osteoblast to Osteocyte Transformation by Changing Mechanical Properties of the ECM . Advanced Biosystems. 3. (10).
Alireza Shahin-Shamsabadi, Ata Hashemi, Mohammadreza Tahriri, Farshid Bastami, Majid Salehi, Fatemeh Mashhadi Abbas (2018). Mechanical, material, and biological study of a PCL/bioactive glass bone scaffold: Importance of viscoelasticity . Materials Science and Engineering: C.
Eslami, H., Azimi Lisar, H., Jafarzadeh Kashi, T.S., Tahriri, M., Ansari, M., Rafiei, T., Bastami, F., Shahin-Shamsabadi, A., Mashhadi Abbas, F., Tayebi, L.(2018). Poly(lactic-co-glycolic acid)(PLGA)/TiO2 nanotube bioactive composite as a novel scaffold for bone tissue engineering: In vitro and in vivo studies . Biologicals. 53. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 51-62.
Shahin-Shamsabadi, A., Hashemi, A., Tahriri, M.(2018). A Viscoelastic Study of Poly(ε-Caprolactone) Microsphere Sintered Bone Tissue Engineering Scaffold . Journal of Medical and Biological Engineering. 38. (3). Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 359-369.
Shahin-Shamsabadi, A., Hashemi, A., Tahriri, M., Bastami, F., Salehi, M., Mashhadi Abbas, F.(2018). Mechanical, material, and biological study of a PCL/bioactive glass bone scaffold: Importance of viscoelasticity . Materials Science and Engineering C. 90. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 280-288.