Fabrication of Ultra-sharp Polymeric Microneedles via Computer Numerical Control (CNC) Micromachining and Micromolding.

Microneedles have recently gained recognition as a promising method in transdermal drug delivery owing to their minimally invasive, painless nature, and they can be flexibly engineered through geometric modifications to meet specific therapeutic requirements. Hence, this study aims to develop microneedle master molds utilizing Computer Numerical Control (CNC) milling technology to create polymeric microneedles with diverse degrees of sharpness to enhance therapeutic efficacy. Previously, our team successfully optimized two critical machining parameters, feed rate, and ramp angle, while analyzing their influence on the obtained needles.

Advances in three-dimensional printing of hydrogel formulations for vascularized tissue and organ regeneration.

Over the last decades, three-dimensional (3D) printing has emerged as one of the most promising alternative tissue and organ regeneration technologies. Recent advances in 3D printing technology, particularly in hydrogel-derived bioink formulations, offer promising solutions for fabricating intricate, biomimetic scaffolds that promote vascularization. In this review, we presented numerous studies that have been conducted to fabricate 3D-printed hydrogel vascularized constructs with significant advancements in printing integumentary systems, cardiovascular systems, vascularized bone tissues, skeletal muscles, livers, and kidneys.

Optimizing CNC milling parameters for manufacturing of ultra-sharp tip microneedle with various tip angles.

Microneedle technology has emerged as an advanced method for transdermal drug delivery, which focuses on diverse fabrication techniques to develop microneedles with various models and geometries. This study explores the application of Computer Numerical Control (CNC) milling technology to create microneedle master molds with extremely sharp tips. We examined the effects of two key machining parameters, feed rate and ramp angle, on the tip sharpness of the microneedles.

Panoramic review on polymeric microneedle arrays for clinical applications.

Transdermal drug delivery (TDD) has significantly advanced medical practice in recent years due to its ability to prevent the degradation of substances in the gastrointestinal tract and avoid hepatic metabolism. Among different available approaches, microneedle arrays (MNAs) technology represents a fascinating delivery tool for enhancing TDD by penetrating the stratum corneum painless and minimally invasive for delivering antibacterial, antifungal, and antiviral medications. Polymeric MNAs are extensively utilized among many available materials due to their biodegradability, biocompatibility, and low toxicity.

Live cell imaging compatible immobilization of Chlamydomonas reinhardtii in microfluidic platform for biodiesel research.

This paper describes a novel surface immobilization method for live-cell imaging of Chlamydomonas reinhardtii for continuous monitoring of lipid droplet accumulation. Microfluidics allows high-throughput manipulation and analysis of single cells in precisely controlled microenvironment. Fluorescence imaging based quantitative measurement of lipid droplet accumulation in microalgae had been difficult due to their intrinsic motile behavior.