With an increase in the elderly and aging population and also in the number of invasive surgeries, wound healing has become a critical focus area in medicine. The complex bodily processes involved in wound healing make it challenging as well as rewarding to identify newer methods and materials for effective wound healing. Now, in a new study, published in Polymers for Advanced Technologies, led by undergraduate student (yes, you read that right) Ryota Teshima, researchers from Tokyo University of Science, Japan, have developed a groundbreaking novel material with possible applications in wound healing. But exactly why is this new material so exciting?
It is important to create an optimal physiological environment around a wound to promote the growth of new cells. Recent research has revealed that a type of material called "hydrogel" is exceptionally useful for achieving such conditions given its molecular structure. Hydrogels are three-dimensionally cross-linked networks of polymers that can absorb more than 95% of their volume in water. Hydrogels with natural polymers have excellent compatibility with the biological conditions of our skin and tissues (referred to as "biocompatibility"), can absorb fluids from the wound, and continuously provide moisture into the wound, creating a highly suitable environment for the wound to heal.
One such natural polymer that is used in hydrogels for wound dressing is alginate, a carbohydrate derived from seaweed, and therefore, abundantly available. Alginate gels are very easy to prepare, but gelation occurs quickly, making it difficult to control the gelation time. Although methods to achieve this control have previously been reported, ensuring short gelation time while maintaining transparency results in hydrogels with a slightly acidic (4-6) or neutral pH. Slightly acidic conditions were, until recently, believed to be beneficial for wound healing, but newer research has found that a slightly alkaline pH (8-8.5) is better for promoting the growth of "skin healing" cells such as fibroblasts and keratinocytes.
This is the context that shaped the characteristics of the next level alginate hydrogel production method that Mr Teshima and his team developed. He summarizes their breakthrough: "We have succeeded in preparing a novel alkaline alginate hydrogel (pH 8.38-8.57) suitable for wound healing via a method that requires no special equipment and can be carried out at room temperature. This, in addition to the fact that the hydrogel forms in 5 minutes, makes it ideal for potential use in any medical practice anywhere for superior wound healing."
Their method involves mixing calcium carbonate and potassium alginate, and then adding carbonated water to this mixture and letting the "gelation" (gel formation) process take place. In this method, the pH of the gel shifts to alkaline because the carbon dioxide volatilizes after gelation. This also ensures transparency of the gel, which in turn allows the visual assessment of wounds and helps in easily ascertaining the progress of healing. Also, regardless of the amounts of ingredients used, the resultant hydrogels have extremely high water content--up to 99%.
When the team placed their hydrogel in physiological saline solution, it passed the test for another critical requisite for a wound dressing: the potential to absorb exudates from the wound. And while the hydrogel did become structurally weak and could not be lifted with tweezers after a week of immersion, it retained its shape.
Speaking about the motivation behind this exciting study, Mr Teshima says, "I have been experimenting with alginate gels ever since junior high school. There was also increasing interest in regenerative medicine when I was growing up, which compelled me to focus on the creation of useful biocompatible materials that can be used in medical therapy." Well, there's no denying that this novel hydrogel developed by Mr Teshima's team shows immense potential for near-future application to wound healing in medicine.
Hopeful of even more potential applications of their method in medicine beyond wound healing, Mr Teshima says, "In the future, if it is possible to control the sustained release of an effective drug held inside it, this novel hydrogel can be used as a drug carrier as well."
For now, the next step is to assess its viability and effectiveness in living cells and animal models. When that is done, Mr Teshima's Japan, and subsequently, the world, can be made a better place.
###
About the Tokyo University of Science
Tokyo University of Science (TUS) is a well-known and respected university, and the largest science-specialized private research university in Japan, with four campuses in central Tokyo and its suburbs and in Hokkaido. Established in 1881, the university has continually contributed to Japan's development in science through inculcating the love for science in researchers, technicians, and educators.
With a mission of "Creating science and technology for the harmonious development of nature, human beings, and society", TUS has undertaken a wide range of research from basic to applied science. TUS has embraced a multidisciplinary approach to research and undertaken intensive study in some of today's most vital fields. TUS is a meritocracy where the best in science is recognized and nurtured. It is the only private university in Japan that has produced a Nobel Prize winner and the only private university in Asia to produce Nobel Prize winners within the natural sciences field.
Website: https://www.tus.ac.jp/en/mediarelations/
About Ryota Teshima from Tokyo University of Science
Mr Ryota Teshima is a third-year undergraduate student at the Department of Applied Chemistry in Tokyo University of Science, Japan. As a young researcher, he has already published two research papers in the areas of science education and the development of effective hydrogels for wound healing. Mr Teshima's academic journey, although nascent, has been outstanding so far, and this has been acknowledged with several awards. He has also been selected as a fourth-generation member of the prestigious Masason Foundation in Japan (https://masason-foundation.org/en/).
Funding information
The study was funded by the Grant-in-Aid for Extracurricular Activities for the Students in Tokyo University of Science Parents Associations (Kouyoukai). Grant number: 2019-15
Journal
Polymers for Advanced Technologies