Litcius/Paper detail

A novel portable <i>in situ</i> printer for hydrogel multi-structure molding and cell printing

Huazhen Liu, Yi Zhang, Zhian Jian, Chuang Gao, Chunxiang Lü, Qiqi Dai, Hao Qiao, Yuanyuan Liu

2023APL Bioengineering13 citationsDOIOpen Access PDF

Abstract

Skin lesions not only disrupt appearance and barrier functionality but also lead to severe microbial infections and immune-inflammatory responses, seriously affect physical and mental health. In situ printing involves the direct deposition of bio-ink to create or repair damaged tissues or organs within a clinical setting. In this study, we designed and fabricated a novel portable in situ printer. This handheld instrument exhibits excellent printing performance, allowing hydrogels to be patterned and molded on surfaces according to specific requirements. By utilizing a dual-component hydrogels co-printing approach with high and low viscosities, we achieved in situ cell-laden printing using low-viscosity hydrogel. This demonstrates the advantages of the device in maintaining cell viability and achieving hydrogel structuring. This approach opens up the possibilities for the efficient encapsulation of active components such as drugs, proteins, and cells, enabling controlled macro- and micro-structuring of hydrogels. This breakthrough finding highlights the potential of our technical approach in dermatological treatment and wound repair, by dynamically adapting and regulating microenvironments in conjunction with hydrogel scaffolds and cell reparative impetus.

Topics & Concepts

Self-healing hydrogelsIn situMaterials scienceNanotechnologyCell encapsulation3D printingInkwellMolding (decorative)Hyaluronic acidBiomedical engineeringChemistryComposite materialEngineeringGeneticsOrganic chemistryBiologyPolymer chemistry3D Printing in Biomedical ResearchWound Healing and TreatmentsCellular Mechanics and Interactions
A novel portable <i>in situ</i> printer for hydrogel multi-structure molding and cell printing | Litcius