TY - JOUR

T1 - 3D printing in biotechnology

T2 - An insight into miniaturized and microfluidic systems for applications from cell culture to bioanalytics

AU - Heuer, Christopher

AU - Preuß, John Alexander

AU - Habib, Taieb

AU - Enders, Anton

AU - Bahnemann, Janina

N1 - Funding information: The authors acknowledge the financial support through the Emmy Noether Programme (346772917).

PY - 2022/12/8

Y1 - 2022/12/8

N2 - Since its invention in the 1980s, 3D printing has evolved into a versatile technique for the additive manufacturing of diverse objects and tools, using various materials. The relative flexibility, straightforwardness, and ability to enable rapid prototyping are tremendous advantages offered by this technique compared to conventional methods for miniaturized and microfluidic systems fabrication (such as soft lithography). The development of 3D printers exhibiting high printer resolution has enabled the fabrication of accurate miniaturized and microfluidic systems—which have, in turn, substantially reduced both device sizes and required sample volumes. Moreover, the continuing development of translucent, heat resistant, and biocompatible materials will make 3D printing more and more useful for applications in biotechnology in the coming years. Today, a wide variety of 3D-printed objects in biotechnology—ranging from miniaturized cultivation chambers to microfluidic lab-on-a-chip devices for diagnostics—are already being deployed in labs across the world. This review explains the 3D printing technologies that are currently used to fabricate such miniaturized microfluidic devices, and also seeks to offer some insight into recent developments demonstrating the use of these tools for biotechnological applications such as cell culture, separation techniques, and biosensors.

AB - Since its invention in the 1980s, 3D printing has evolved into a versatile technique for the additive manufacturing of diverse objects and tools, using various materials. The relative flexibility, straightforwardness, and ability to enable rapid prototyping are tremendous advantages offered by this technique compared to conventional methods for miniaturized and microfluidic systems fabrication (such as soft lithography). The development of 3D printers exhibiting high printer resolution has enabled the fabrication of accurate miniaturized and microfluidic systems—which have, in turn, substantially reduced both device sizes and required sample volumes. Moreover, the continuing development of translucent, heat resistant, and biocompatible materials will make 3D printing more and more useful for applications in biotechnology in the coming years. Today, a wide variety of 3D-printed objects in biotechnology—ranging from miniaturized cultivation chambers to microfluidic lab-on-a-chip devices for diagnostics—are already being deployed in labs across the world. This review explains the 3D printing technologies that are currently used to fabricate such miniaturized microfluidic devices, and also seeks to offer some insight into recent developments demonstrating the use of these tools for biotechnological applications such as cell culture, separation techniques, and biosensors.

KW - 3D printing

KW - biosensors

KW - cell culture

KW - microfluidics

KW - miniaturization

UR - http://www.scopus.com/inward/record.url?scp=85118533010&partnerID=8YFLogxK

U2 - 10.1002/elsc.202100081

DO - 10.1002/elsc.202100081

M3 - Review article

AN - SCOPUS:85118533010

VL - 22

SP - 744

EP - 759

JO - Engineering in life sciences

JF - Engineering in life sciences

SN - 1618-0240

IS - 12

ER -