Conference Tools for MS&T22: Materials Science & Technology

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About this Symposium
Meeting	MS&T22: Materials Science & Technology
Symposium	3D Printing of Biomaterials and Devices
Sponsorship	ACerS Bioceramic Division
Organizer(s)	Sahar Vahabzadeh, Northern Illinois University Susmita Bose, Washington State University Amit Bandyopadhyay, Washington State University Mukesh Kumar, LincoTek Medical Mangal Roy, Indian Institute of Technology - Kharagpur (IIT-Kgp)
Scope	3D Printing (3DP) or additive manufacturing (AM) provides unique opportunities to process biomaterials and devices that are not achievable by conventional manufacturing technologies. As a result, 3DP/AM is transforming the technology platform, impacting various disciplines, including biomaterials and biomedical devices. In addition, 3DP or AM adds another dimension to this field of research addressing the clinical need for patient-specific devices. This symposium will cover both oral and poster presentations to understand processing-structure-property-application relationships involving 3DP / AM of biomaterials under in vitro, in vivo, and in silico environments. Suggested Topical Areas include, but not limited to: Biomaterials for tissue engineering 3DP of ceramic and metallic biomaterials 3DP of polymers and hydrogels 3DP in bone and dental tissue engineering 3DP in soft tissue engineering 3DP of materials for drug delivery 3DP of nano biomaterials Surface modification of biomedical devices via 3D Printing Bioprinting and biplotting Mechanical properties of 3D Printed biomaterials Modeling and simulation of 3D printed biomaterials and devices Patient-specific devices
Abstracts Due	05/15/2022
Proceedings Plan	Undecided

PRESENTATIONS APPROVED FOR THIS SYMPOSIUM INCLUDE

3-D Printing in Regenerative Engineering

3D Bioprinting with Engineered Living Materials for Advanced Biofabrication

3D Printing Integrated with Controlled Delivery for In Situ Tissue Engineering of Complex and Inhomogeneous Tissues from Endogenous Stem/Progenitor Cells

3D Printing of Nanomaterials-based Biomedical Electronics

3D Printing of Zonal-structured Scaffolds for Complex Tissue Engineering

3D Printing Strategies to Fabricate Complex Scaffolds for Tissue Engineering Applications

Additive Manufacturing Process Simulation of Polyetherimide Porous Scaffolds for Bone Tissue Engineering Applications

Biohybrid Functional Material Design by Engineered Peptides

C-1: Surface Treatment of Titanium by Alkali treatment and Magnesium Deposition for Orthopedic Application

Effect of Printing Parameters on 3D-printed Biodegradable Biopolymer-metal Composite Material

Effect of Sr2+ and Ca2+ ions on 3D printed Beta Tricalcium-Phosphate/Alginate Composite Scaffolds for Bone Tissue Engineering

Implant Optimization Guided by Biomimetic Insight

Interlocked Bone Scaffolds with BMP Induced Osteogenesis with Use of 3D Printed Molds

Laser-Based 3D Printing for Medical Applications

Mechanical and Electrical Properties of 3D Printed Wearable Structures

Periodic Cellular Ceramic Structures by Replication of Additive Manufactured Templates

Selective Artificial Neural Network by Targeted Delivery of Neuronal Cells Using Magnetically Controlled 3D Printed Microrobots

Sheet Lamination Additive Manufacturing (SLAM) – A Viable Approach to Resorbable 3D Constructs for Bone Tissue Engineering

Solvent Cast 3D Printing with Different Molecular Weight Polymers

The Regulatory Roles of the Substrate Microenvironment in Cancer Progression in Tissue Engineering Scaffolds

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