Abstract
3D printing is a smart additive manufacturing technique that allows the engineering of biomedical devices that are usually difficult to design using conventional methodologies such as machining or molding. Nowadays, 3D-printed microfluidics has gained enormous attention due to their various advantages including fast production, cost-effectiveness, and accurate designing of a range of products even geometrically complex devices. In this review, we focused on the recent significant findings in the field of 3D-printed microfluidic devices for biomedical applications. 3D printers are used as fabrication tools for a broad variety of systems for a range of applications like diagnostic microfluidic chips to detect different analytes, for example, glucose, lactate, and glutamate and the biomarkers related to different clinically relevant diseases, for example, malaria, prostate cancer, and breast cancer. 3D printers can print various materials (inorganic and polymers) with varying density, strength, and chemical properties that provide users with a broad variety of strategic options. In this article, we have discussed potential 3D printing techniques for the fabrication of microfluidic devices that are suitable for biomedical applications. Emerging diagnostic technologies using 3D printing as a method for integrating living cells or biomaterials into 3D printing are also reviewed.
Highlights
Microfluidics is the science and technology used in channels with a range of 10–100 micrometers to control small amounts of fluid (10–9 to 10–18)
This article provides a detailed overview of 3D-printed microfluidics and their implication for different biomedical applications
One of the objectives of this review is to enrich the readers with knowledge about various potential 3D printing techniques explored for biomedical applications
Summary
Microfluidics is the science and technology used in channels with a range of 10–100 micrometers to control small amounts of fluid (10–9 to 10–18). It offers new capabilities in space and time to control molecular concentrations (Tarn and Nicole, 2013; Bragheri et al, 2016). Threedimensional printing allows science and technology to be transformed by producing custom-made, 3D-Printed Microfluidics and Biomedical Applications low-cost equipment requiring specialized equipment. Due to the main advantages of fast fabrication, simple accessibility, processing of different materials, and durability, 3D printing technology has flowered in sensing and for the development of 3D-printed microfluidic device for various applications in the biomedical sector (Zhang, 2019).
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