New processing route to porous bioactive glass composites for bone tissue scaffolds

用于骨组织支架的多孔生物活性玻璃复合材料的新加工路线

• 批准号: RGPIN-2019-05379
• 负责人: Nychka, John
• 金额: $ 2.4万
• 依托单位: University of Alberta
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=714994
• 关键词: New; processing; route; porous; bioactive

Bioactive glasses have been used for decades in biomedical applications where the repair and generation of new bone is required (e.g., dental implants; bone defects). A common strategy for using bioactive glasses is as composites--materials made from different materials to produce a more functional component. The most common bioactive bone tissue scaffolds are either particulate ceramics bound together with polymers, or sintered ceramics. Several methods are capable of producing porous scaffolds, however there is no generally accepted method, and the present work is focused on producing composite scaffolds through a simplified methodmixing a powder with a small volume of binding liquid. The major goal of this research is to create a particulate-based bioactive glass composite using a liquid ceramic precursor that cures in air (at room temperature and pressure) to bind bioactive glass particles together so as to form a mechanically stable bone tissue scaffold. The strategy of the proposed technology is to use clinically and commercially successful raw materials (bioactive glass) and water soluble silicate solutions (e.g., sodium silicate, “water glass”; an industrial and food safe adhesive). The innovative nature of this work is a new manufacturing route to produce porous bone tissue scaffolds to enable implementation with minimal impact on existing surgical methods. The scientific challenges to be overcome are determination of the ideal glass and silicate solution in the optimum amounts to be mixed, in an effective manner, so that carbon dioxide in the air will set the solution to bind bioactive glass particles with enough mechanical strength to permit shape retention and permit an in vitro bioactive response. The proposed research challenges traditional thinking within the field of ceramicsto avoid elevated temperature to bind ceramic particles together. The technology will be able to be used in an operating room, on demand, to allow a surgeon to directly repair a bone defect by mixing a powder with a pre-measured amount of liquid and inserting the resultant paste into the wound site whereupon the composite will harden within a few minutes. The resultant composite scaffolds will promote bone in-growth and eventually be resorbed and replaced by new bone. Experimental testing will be performed to determine: optimal glass type, particle shape, size, and distribution; type, amount, and concentrations of silicate solutions; setting time; porosity; strength; density; phases; and time to form hydroxcarbonate apatite in simulated bodily fluid immersion testing (a proxy for in vivo bioactivity). Materials characterization tools will aid in determining relationships between glass and the binder phase through visualization and quantification required for multiple regression analysis. 4 PhD, 1 MSc and 10 BSc HQP will gain highly desirable skills (e.g., communication, critical thinking, complex problem solving, and collaboration) during this grant.

生物活性玻璃已经在需要修复和产生新骨的生物医学应用中使用了几十年（例如，牙科植入物;骨缺损）。使用生物活性玻璃的一个常见策略是作为复合材料--由不同材料制成的材料，以产生更具功能性的组件。最常见的生物活性骨组织支架是与聚合物结合在一起的颗粒陶瓷或烧结陶瓷。制备多孔支架的方法有很多种，但目前还没有公认的方法，本工作主要是通过一种简单的方法--将粉末与少量的结合液混合制备复合支架。本研究的主要目标是使用在空气中（在室温和压力下）固化的液体陶瓷前体来创建基于颗粒的生物活性玻璃复合材料，以将生物活性玻璃颗粒结合在一起，从而形成机械稳定的骨组织支架。所提出的技术的策略是使用临床上和商业上成功的原材料（生物活性玻璃）和水溶性硅酸盐溶液（例如，硅酸钠，“水玻璃”;工业和食品安全粘合剂）。这项工作的创新性质是一种新的制造路线，以生产多孔骨组织支架，使实施对现有手术方法的影响最小。要克服的科学挑战是以有效的方式确定理想的玻璃和硅酸盐溶液的最佳混合量，使得空气中的二氧化碳将使溶液以足够的机械强度结合生物活性玻璃颗粒，以允许形状保持并允许体外生物活性反应。 拟议的研究挑战了陶瓷领域的传统思维，以避免高温将陶瓷颗粒结合在一起。该技术将能够在手术室中根据需要使用，以允许外科医生通过将粉末与预先测量的液体量混合并将所得糊剂插入伤口部位，从而在几分钟内使复合材料硬化来直接修复骨缺损。所得到的复合支架将促进骨向内生长，并最终被吸收并被新骨取代。 将进行实验测试以确定：最佳玻璃类型、颗粒形状、尺寸和分布;硅酸盐溶液的类型、量和浓度;凝固时间;孔隙率;强度;密度;相;以及在模拟体液浸泡测试中形成羟基碳酸盐磷灰石的时间（体内生物活性的代表）。材料表征工具将有助于通过多元回归分析所需的可视化和量化来确定玻璃和粘合剂相之间的关系。 4名博士，1名硕士和10名理学士HQP将获得非常理想的技能（例如，沟通，批判性思维，解决复杂问题和协作）。