“The differentiation of embryonic stem cells seeded on electrospun nanofibers into neural lineages” ā Biomaterials, 2009. Cited 524 times. This study investigates stem cell differentiation on nanofiber scaffolds, advancing neural tissue engineering techniques.
“Approaches to neural tissue engineering using scaffolds for drug delivery” ā Advanced Drug Delivery Reviews, 2007. Cited 476 times. This review outlines scaffold-based drug delivery methods, influencing therapeutic strategies for neural regeneration.
“Emerging biofabrication strategies for engineering complex tissue constructs” ā Advanced Materials, 2017. Cited 401 times. This paper discusses biofabrication innovations for creating intricate tissue models, contributing to advanced biomaterials research.
“Conductive coreāsheath nanofibers and their potential application in neural tissue engineering” ā Advanced Functional Materials, 2009. Cited 363 times. This research on conductive nanofibers highlights their role in enhancing neural tissue repair.
“Optimization of fibrin scaffolds for differentiation of murine embryonic stem cells into neural lineage cells” ā Biomaterials, 2006. Cited 344 times. This study optimizes fibrin scaffolds for effective stem cell differentiation, aiding neural tissue formation.
“Metal additive manufacturing: Technology, metallurgy and modelling” ā Journal of Manufacturing Processes, 2020. Cited 285 times. This paper examines metal additive manufacturing and its potential in bioengineering applications.
“Combining stem cells and biomaterial scaffolds for constructing tissues and cell delivery” ā Harvard Stem Cell Institute, 2008. Cited 265 times. This foundational work explores the integration of stem cells with biomaterials for tissue engineering.
“Cell therapy for spinal cord regeneration” ā Advanced Drug Delivery Reviews, 2008. Cited 190 times. This article discusses cell therapy approaches for spinal cord repair, influencing regenerative medicine.
“The effects of soluble growth factors on embryonic stem cell differentiation inside of fibrin scaffolds” ā Stem Cells, 2007. Cited 166 times. This paper focuses on controlled growth factor delivery to promote stem cell differentiation.
“Natural Biomaterials and Their Use as Bioinks for Printing Tissues” ā Bioengineering, 2021. Cited 152 times. Highlights the use of natural biomaterials as bioinks in 3D bioprinting for tissue engineering applications.
“3D printing of neural tissues derived from human induced pluripotent stem cells using a fibrin-based bioink” ā ACS Biomaterials Science & Engineering, 2018. Cited 151 times. Describes bioprinting neural tissues with fibrin-based bioinks, pushing the boundaries of regenerative bioprinting.
“Extrusion and Microfluidic-Based Bioprinting to Fabricate Biomimetic Tissues and Organs” ā Advanced Materials Technologies, 2020. Cited 143 times. This paper presents novel bioprinting methods for replicating complex tissue structures.