During the last two decades, 3D printing technology has emerged as a valid alternative for
producing microfluidic devices. 3D printing introduces new strategies to obtain high …

Abstract The 'one-size-fits-all'approach followed by conventional drug delivery platforms
often restricts its application in pharmaceutical industry, due to the incapability of adapting to …

Organs-on-a-chip, or OoCs, are microfluidic tissue culture devices with micro-scaled
architectures that repeatedly achieve biomimicry of biological phenomena. They are well …

Traditional 3D printing based on Digital Light Processing Stereolithography (DLP-SL) is
unnecessarily limiting as applied to microfluidic device fabrication, especially for high …

The fabrication of microfluidic devices has progressed from cleanroom manufacturing to
replica molding in polymers, and more recently to direct manufacturing by subtractive (eg …

Treating bone defects is highly challenging because they do not heal on their own inside the
patients, so implants are needed to assist in the reconstruction of the bone. Bioceramic …

While vat photopolymerization has many advantages over soft lithography in fabricating
microfluidic devices, including efficiency and shape complexity, it has difficulty achieving …

Methods to make microfluidic chips using 3D printers have attracted much attention because
these simple procedures allow rapid fabrication of ready-to-use products from digital 3D …

The present review aims at identifying the key progress points that have been made on the
use of 3D printing to manufacture microneedles in the past 3 years. The advances in the …

Underwater recording remains a critical challenge in bioelectronics because traditional
flexible electrodes can not fulfill essential requirements such as stability and steady …