Integrated photonic biosensors for time domain measurements

用于时域测量的集成光子生物传感器

• 批准号: RGPIN-2015-06607
• 负责人: Kirk, Andrew
• 金额: $ 3.42万
• 依托单位: McGill University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2019
• 资助国家: 加拿大
• 起止时间: 2019-01-01 至 2020-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=689505
• 关键词: Integrated; photonic; biosensors; time; domain

The ability of light to act as a non-contact and high precision probe of its environment provides optical sensors with many attractive capabilities. Whilst various optical sensing technologies are already widely used for many different applications in the biomedical, environmental and industrial sector, this technology has not yet achieved its full potential. Optical micro-resonators represent the most sensitive class of optical sensors known. They are typically spheres or toroids made from a very low loss material. Light propagates around the inside of these devices in the form of `whispering gallery' modes. Any change to the surface properties will influence the resonant frequency, which can be measured. By coating the surface with a chemistry that will bind specifically to the molecules that we are seeking to detect we can form a sensor.****The challenge of current whispering gallery mode sensors is that they need to be interrogated by using either tunable lasers or optical spectrum analysers to measure the change of resonant frequency. This adds to cost and complexity and represent a significant barrier to use. Our objective is to develop very sensitive and integrated multi-channel optical sensors that require only low cost and broadband light sources and photodetectors.****In 2012 we demonstrated the application of a time-domain technique, namely phase shift cavity ring down spectroscopy (PSCRDS) to biodetection in silica microtoroids. This approach makes use of the fact that a surface binding event will also change the length of time that a photon remains in the cavity. This can be measured by detecting the phase shift when sinusoidally modulated light is injected into the cavity, requiring just a modest (<100 MHz) modulation rate and simple photodetector. The PSCRDS approach also has the advantage of much greater noise immunity than wavelength sensing approaches. While the above demonstration used a tunable laser, we will now extend this to white light PSCRDS. We will use a broadband optical light source which will emit a spectrum spanning one or more resonant peaks of the cavity's frequency response. We will implement this in an integrated photonic waveguide platform which will allow us to integrate an input and output waveguide with each resonator. The output waveguide will pick up only the light that couples into the resonator (no optical tuning required).****In order to achieve this we must overcome significant challenges in terms of device design, modeling fabrication, signal processing and packaging. We will validate our sensors by testing for the detection of the legionella-causing bacteria in water (in collaboration with an industrial partner) and implement them as a sensor array for the investigation of liver and prostate cancers (in collaboration with medical researchers). The program will provide high quality and multidisciplinary training to 18 graduate and undergraduate students.******

光作为环境的非接触式和高精度探头的能力为光学传感器提供了许多诱人的能力。虽然各种光学传感技术已经在生物医学、环境和工业领域的许多不同应用中得到了广泛的应用，但这项技术还没有充分发挥其潜力。光学微谐振器代表了已知的最灵敏的光学传感器类别。它们通常是由非常低损耗的材料制成的球体或环体。光以“回音廊”模式的形式在这些装置的内部传播。表面性质的任何变化都会影响共振频率，这是可以测量的。通过在表面涂上一种化学物质，这种化学物质将专门结合到我们正在寻求检测的分子上，我们可以形成一个传感器。*当前耳语画廊模式传感器的挑战是，它们需要使用可调激光或光谱分析仪进行检测，以测量共振频率的变化。这增加了成本和复杂性，并对使用构成了很大的障碍。我们的目标是开发非常灵敏和集成的多通道光学传感器，只需要低成本和宽带光源和光电探测器。*2012年，我们展示了一种时域技术，即相移腔衰荡光谱(PSCRDS)在二氧化硅微环生物检测中的应用。这种方法利用了这样一个事实，即表面结合事件也将改变光子在腔中停留的时间长度。这可以通过检测正弦调制光注入腔中时的相移来测量，只需要适度的调制速率(&lt；100 MHz)和简单的光电探测器。PSCRDS方法还具有比波长传感方法更强的抗噪性的优势。虽然上面的演示使用了可调谐激光器，但我们现在将其扩展到白光PSCRDS。我们将使用宽带光学光源，它将发射跨越腔体频率响应的一个或多个共振峰的光谱。我们将在一个集成的光子波导平台中实现这一点，该平台将允许我们在每个谐振器中集成一个输入和输出波导。输出波导将只接收耦合到谐振器的光(不需要光学调谐)。*为了实现这一点，我们必须克服器件设计、建模制造、信号处理和封装方面的重大挑战。我们将通过测试检测水中引起军团菌的细菌来验证我们的传感器(与工业合作伙伴合作)，并将其实施为用于肝癌和前列腺癌调查的传感器阵列(与医学研究人员合作)。该计划将为18名研究生和本科生提供高质量的多学科培训。