Unlocking the capability of optical microcavity analysis to measure nanoparticle refractive index

释放光学微腔分析测量纳米颗粒折射率的能力

• 批准号: 105983
• 金额: $ 5.78万
• 依托单位: OXFORD HIGHQ LTD
• 依托单位国家: 英国
• 项目类别: Collaborative R&D
• 财政年份: 2020
• 资助国家: 英国
• 起止时间: 2020 至 无数据
• 项目状态: 已结题
• 来源: https://gtr.ukri.org/projects?ref=105983
• 关键词: Unlocking; capability; optical; microcavity; analysis

The last three decades have seen the widespread adoption and industrialisation of nanoparticles serving applications in many technology sectors, including healthcare, energy production, manufacturing industry and agriculture. In the pharmaceutical sector, at the heart of this progress is the ability to fill otherwise inert particle materials with highly toxic anti-cancer drugs or genetic materials and/or functionalise the surface to both mask their presence from the human immune response and to better target the release of the "payload" at a particular organ, tumour or cellular component. These developments have led to a series of scientific breakthroughs in the field of advanced therapeutics by using nanocarriers to deliver drugs where it is needed in the body and reducing therapeutic index, i.e. toxicity to healthy organ and tissues.However, manufacturing of such "advanced therapies" is challenging as it requires fine tools to scrutinise nanoparticles 1000 times smaller than the width of a human hair. Oxford HighQ has developed a new technique providing the ability to characterise the composition of nanoparticles through their optical properties, i.e. more specifically their refractive indices. One could use this parameter to measure on a particle-by-particle basis the amount of therapeutic molecules loaded within/on a nanoparticle carrier. The limited footprint, ease-of-use and potential for this technique to be built in-line within a manufacturing process makes it particularly attractive to the pharmaceutical industry. This project will employ the expertise of the UK's National Physical Laboratory to design and manufacture highly engineered materials that can be used to fully characterise the capabilities of this new technology, and provide facilities to rigorously validate this new measurement against orthogonal analytical methods. The latter tends to be bulky, time consuming and expensive methods, which highlight the need for a more agile technological platform for rapid screening of materials and quality assurance purposes. The joint team will focus its efforts in developing a series of demonstrations to unlock the true potential of Oxford HighQ's technology. For example, the project will output an application note directly relevant to advanced therapeutics that will help promoting out new technology in the pharmaceutical sector.

在过去的三十年里，纳米颗粒在许多技术领域得到了广泛的采用和工业化，包括医疗保健、能源生产、制造业和农业。在制药领域，这一进展的核心是能够用高毒性抗癌药物或遗传物质填充惰性颗粒材料和/或功能化表面，以掩盖它们的存在，使其免受人体免疫反应的影响，并更好地将“有效载荷”释放到特定器官，肿瘤或细胞成分。这些发展导致了先进治疗领域的一系列科学突破，通过使用纳米载体将药物输送到体内需要的地方，并降低治疗指数，即对健康器官和组织的毒性。然而，制造这种“先进疗法”是具有挑战性的，因为它需要精细的工具来仔细检查比人类头发宽度小1000倍的纳米颗粒。Oxford HighQ开发了一种新技术，能够通过纳米颗粒的光学特性（即更具体地说，折射率）来分析纳米颗粒的组成。可以使用该参数来在逐颗粒的基础上测量负载在纳米颗粒载体内/上的治疗分子的量。有限的占地面积，易于使用和潜在的这种技术建立在生产过程中，使其特别有吸引力的制药行业。该项目将利用英国国家物理实验室的专业知识，设计和制造高度工程化的材料，这些材料可用于充分验证这项新技术的能力，并提供设施，以严格验证这种新的测量方法对正交分析方法。后者往往是庞大、耗时和昂贵的方法，这突出表明需要一个更灵活的技术平台来快速筛选材料和保证质量。联合团队将集中精力开发一系列演示，以释放Oxford HighQ技术的真正潜力。例如，该项目将输出与先进疗法直接相关的应用说明，这将有助于在制药行业推广新技术。