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Establishment of Precision Medicine Targeting Cancer Stem Cells Using Synthetic Polymer Gels
Development of a method to initialize cancer stem cells using hydrogel
It is important to eradicate cancer stem cells to cure cancer. This method uses Hokkaido University's original biomaterial (synthetic polymeric hydrogel) to induce reprogramming (initialization) of cancer stem cells rapidly and efficiently, making it possible to predict the properties of cancer stem cells and their response to treatment in case of recurrence.
Research
It is essential to eradicate treatment-resistant cancer stem cells to cure cancer. However, their number is small, and it is difficult to isolate and analyze cancer stem cells using conventional methods. With this study, we used a synthetic polymeric hydrogel (Science 344, 161-162, 2014) originally developed by Hokkaido University to induce reprogramming (initialization) of cancer stem cells rapidly, easily, inexpensively, and efficiently, allowing us to analyze the properties of cancer stem cells, evaluate their response to treatment, and predict the properties of cancer cells at the time of recurrence. This technology is expected to make it possible to screen drugs that target cancer stem cells, predict the nature of recurrent tumors that may occur in the future, and administer prophylactic drugs, thereby providing cancer patients with accurate cancer stem cell-targeted precision medicine (preventive preemptive medicine).
Shinya Tanaka Professor -
Flexible and Strong Gel
New materials for the age of welfare
What kind of material should be used in an age when we are required to improve our quality of life? The answer is strong gels such as double network gels. Tough gels will help revolutionize the quality of medical devices, tissue substitutes and biomimetics.
Research
Conventionally, elastomers have widely been used as soft materials, but in situations where they are used as contact points with living organisms or as their substitutes, hydrophobicity is a critically important factor. Since hydrous materials strongly reflect the physical properties of water, they exhibit physical properties that are very similar to biological tissues. For example, heat transfer and electromagnetic wave absorption properties of hydrous materials are similar to those of living tissues, and their surface friction is as low as that of body tissues. Although gel is the most common hydrophilic soft material, its mechanical strength has been low and its application has thus been limited. We have succeeded in developing a highly strong double network (DN) gel that does not break, even when a truck drives over it, despite 90% water content. This has greatly expanded the possibilities of gel applications. While working to examine the toughness of DN gels, we have discovered the “sacrificial bonding principle,” arriving at the concept of strengthening various materials. In recent years, we have been developing various other types of strong gels besides DN gels.
Jian Ping Gong Professor -
Gel that is Stronger Than Steel
Soft and tough composite material
By conjugating glass fiber and self-healing gel, we have achieved a gel that is stronger than carbon fiber-reinforced plastic (CFRP). Since the base material is a gel, it is as flexible as rubber against bending, but tougher than CFRP against tearing, making it difficult to break.
Research
The glass fiber composite gel we have developed exhibits unbreakable, untearable and tear-resistant properties. Generally speaking, CFRP and glass fiber reinforced plastic (GFRP) are widely used as composite materials. Similar to these fiber-reinforced plastics, fiber-reinforced gels are hard and resistant to tension because of the characteristics of the fibers, while being soft and flexible on bending because of the characteristics of the gel. The self-healing polyampholyte (PA) gel used as the base material is also strong as such thanks to its ability to dissipate a large amount of energy against deformation. Since the gel is flexible, when it is combined with fiber, local distortions can be transmitted through the fiber to the distant base material, resulting in large energy dissipation of the entire material, meaning that it is remarkably strong.
Takayuki Kurokawa ProfessorPh. D -
High Strength Gel That Spontaneously Bonds Strongly with Bone Tissue
Development of a safe, high-strength bonding method between wet materials and bone, which has been difficult to achieve so far, by utilizing bone healing in living organisms
In answer to the issue of in vivo fixation by applying the much anticipated high-strength hydrogel as a next-generation artificial cartilage or cartilage tissue regeneration scaffold material, we have developed a simple, non-toxic, high-strength adhesion method using hydroxyapatite, an inorganic component of bone tissue.
Research
The high-strength, high-toughness double-network gel (DN gel) previously developed by our group has excellent properties such as low wear on cartilage and induction of cartilage tissue regeneration in a natural joint, and is being studied for application as an artificial cartilage material and cartilage regeneration induction material. On the other hand, it is difficult to fix and maintain such a gel in a natural joint, which has been a major issue with the practical use of this material. In this study, we developed a fixation method that allows bone tissue regeneration to progress spontaneously into the gel and adhere firmly by compounding hydroxyapatite (HAp), the main inorganic component of bone tissue, to the surface layer of the DN gel. In addition to excellent mechanical properties and cartilage regeneration ability, the realization of non-toxic in vivo adhesion to bone is a great step forward toward the practical application of DN gel for joint treatment.
Takayuki Nonoyama Associate Professor
