A breakthrough in microneedle patches
Rethinking how drugs are administered:
Scientists develop promising fabrication process for microneedle arrays capable of administering protein-based drugs subcutaneously without damaging the skin.
The painful feeling of receiving an injection through a hypodermic needle or with the unpleasant sensation of swallowing a large pill is a globally familiar sensation. But what if a revolutionary and gentler way of administering drugs was in the works? For over two decades, researchers have been investigating various types of microneedles as a minimally invasive method for transdermal drug delivery. Arrays of microneedles can be designed to be loaded with a drug or chemical, which they then release over time onto the blood stream after piercing slightly beyond the skin layers.
Microneedles offer several advantages compared to other types of drug delivery. First, they are painless and cause virtually no damage to the skin nor bleeding. Second, they can be self-administered. Third, unlike traditional needles, the disposal of microneedles is much easier as they don’t leave behind hazardous waste. Unfortunately, there are still a few challenges that need to be addressed before microneedles become the next big thing in healthcare. One is their fabrication cost, which generally involves expensive molds, materials, and machinery. Another issue is the aggregation and degradation of proteins when microneedles are pre-loaded with a protein-based medicine, as these molecules are quite sensitive to external conditions such as temperature, acidity and salt concentration.
In a recent study published in Biomacromolecules, two research teams from Japan and Thailand collaborated to address the main limitations of existing microneedles. On the one side, Prof. Kazuaki Matsumura from the Japan Advanced Institute of Science and Technology (JAIST) and Ph.D. student Harit Pitakjakpipop from JAIST-SIIT developed and applied a functional polymer that effectively suppresses protein aggregation. On the other side, Dr. Paisan Khanchaitit and his team at the National Science and Technology Development Agency (NANOTEC), Thailand, perfected a microneedle fabrication method suitable for the industrial scale based on photolithography. By combining these two efforts, the teams managed to produce microneedles patches with several attractive properties and potential scalability to clinical settings.
The microneedles themselves are made of a non-degradable, biocompatible hydrogel that also contains zwitterionic poly-sulfobetaine (poly-SPB). As reported in previous studies by the same authors, this polymer suppresses protein aggregation. Thus, the researchers incorporated it during the fabrication process and showed that the proteins pre-loaded in the microneedles were stable even when subjected to various external stresses.
Additionally, the scientists developed a straightforward and cost-effective way to fabricate microneedle arrays made from the abovementioned materials. They resorted to photolithography, a process in which a photomask is used to selectively block UV light from reaching a target surface to control chemical reactions locally, as Dr. Khanchaitit explains: “UV light passing through the photomask generates free radicals in the polymer resin during the fabrication process, resulting in photopolymerization and the subsequent formation of 3D microneedle structure patterns on a clear and flexible substrate.” This fabrication procedure requires inexpensive equipment only and takes about five minutes, yet produces four-point star-shaped microneedles with remarkable mechanical strength.
To test the performance of these microneedle arrays for drug delivery, the researchers loaded them with 50 microliters of drug solutions containing rhodamine B as a dye alongside lysozyme and insulin as example proteins (see Figure 1). Through various experiments on porcine skin, the teams verified that their microneedle patches offered both high drug-loading capacity and high drug-release rate. Moreover, they confirmed that the microneedles could both load and preserve various water-soluble drugs and proteins simultaneously, eliminating the need for refrigeration.
Overall, the proposed microneedle arrays seem to be a remarkably promising platform for administering therapeutic drugs and vaccines, as Prof. Matsumura concludes: “The superior characteristics of our microneedles may change the way drugs are administered and could enable the development and delivery of advanced protein-based drugs for the treatment of various disorders.” Who knows what other revolutionary innovations in medicine wait for us in the future?
Reference
Title of original paper: | Facile Photolithographic Fabrication of Zwitterionic Polymer Microneedle with Protein Aggregation Inhibition for Transdermal Drug Delivery |
Journal: | Biomacromolecules |
DOI: | 10.1021/acs.biomac.1c01325 |
About Japan Advanced Institute of Science and Technology, Japan
Founded in 1990 in Ishikawa prefecture, the Japan Advanced Institute of Science and Technology (JAIST) was the first independent national graduate school in Japan. Now, after 30 years of steady progress, JAIST has become one of Japan’s top-ranking universities. JAIST counts with multiple satellite campuses and strives to foster capable leaders with a state-of-the-art education system where diversity is key; about 40% of its alumni are international students. The university has a unique style of graduate education based on a carefully designed coursework-oriented curriculum to ensure that its students have a solid foundation on which to carry out cutting-edge research. JAIST also works closely both with local and overseas communities by promoting industry–academia collaborative research.
About Professor Kazuaki Matsumura from Japan Advanced Institute of Science and Technology, Japan
Kazuaki Matsumura is a Professor at the Japan Advanced Institute of Science and Technology (JAIST). He received a Ph.D. from Kyoto University in 2004. From 2006 to 2011, he worked as an Assistant Professor at the Institute for Frontier Medical Sciences, Kyoto University. In 2011, he became an Associate Professor at the School of Materials Science of JAIST and became a full Professor in 2020. Now, he a board member for the Japanese Society for Biomaterials. He has published over 120 papers in the fields of polymer science, biomaterials, and regenerative medicine, among others.
Funding information
This work was supported in part by research grant Grant-in-Aid, KAKENHI (20K20197), for scientific research from the Japan Society for the Promotion of Science and National Nanotechnology Center, National Science and Technology Development Agency, Thailand (P1951763).
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