Improving Thermosensitive Bioink Scaffold Fabrication with a Temperature-Regulated Printhead in Robot-Assisted Bioprinting System

Overview

Journal ACS Omega

Publisher American Chemical Society

Specialty Chemistry

Date 2024 Oct 7

PMID 39371970

Authors

Zitong Wang

Li Lin

Xiangyu Li

Quan Zhang

Xuelian Mi

Bide Xu

Yuanjing Xu

Tongyou Liu

Yuling Shen

Zan Wang

Neng Xie

Jinwu Wang

Affiliations

Soon will be listed here.

Abstract

bioprinting enables precise 3D printing inside the human body using modified bioprinters with thermosensitive bioinks such as gelatin methacrylate (GelMA). However, these devices lack refined temperature-regulated mechanisms essential for ensuring bioink viscosity, as compared to traditional bio-3D printers. Addressing this challenge, this study presents a temperature-regulated printhead designed to improve the fabrication of thermosensitive bioink scaffolds in bioprinting, integrated into a UR5 robotic arm. Featuring a closed-loop system, it achieves a temperature steady error of 1 °C and a response time of approximately 1 min. The effectiveness of the printer was validated by bioprinting multilayer lattice 3D bioscaffolds. Comparisons were made with or without temperature control using different concentrations of GelMA + LAP. The deformation of the bioscaffolds under both conditions was analyzed, and cell culture tests were conducted to verify viability. Additionally, the rheology and mechanical properties of GelMA were tested. A final preliminary bioprinting experiment was conducted on a model of a damaged femur to demonstrate practical application. The fabrication of this printhead is entirely open source, facilitating easy modifications to accommodate various robotic arms. We encourage readers to advance this prototype for application in increasingly complex bioprinting situations, especially those utilizing thermosensitive bioinks.

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