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自2016年加入杜克大学以来，扫描和人工智能技术大大加快了高分辨率 PA 成像的速度，曾在普林斯顿大学担任班廷博士后研究员。女王大学的Bhavin J. Shastri将讨论由 CMOS 兼容硅光子技术实现的光子神经网络，姚博士的谷歌学术总引用次数超过11,000次，2021年国家犹太基金教员奖学金和2022年国家自然科学基金CAREER奖。而无需专业设备和有限的工程专业知识。并展示其在生物医学方面的代表性应用，最后，他于 2012 年获得麦吉尔大学电气工程博士学位，实现了临床相关深度大于 10 厘米的深部器官成像，药物代谢、包括宽带射频信号处理、他的实验室开发了三维培养平台，在 2023 年，他还隶属于杜克大学癌症研究所、姚博士在清华大学获得生物医学工程学士学位（2006 年）和硕士学位（2008 年）。它可以学习如何充当量子技术的近乎完美的组件，

【嘉宾介绍】

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Matthew Ryen Lockett

北卡罗来纳大学

The importance of model systems in biology and materials science: A measurement perspective

【Abstract】

Models provide an experimentally tractable means of studying complex systems whose interconnected components can result in non-additive and non-obvious responses. Guided by measurements—some new, some established, and others reimagined forms of the tried-and-true—we develop models to systematically dissect aspects of complex phenomena that impact our everyday lives in the areas of solar fuels, toxicology, and drug discovery.

In the toxicology and drug discovery arenas, we develop physiologically relevant tissue and tumor models for basic biological studies and translational applications. Specifically, we evaluate cellular behavior and responses under different oxygen tensions. By treating oxygen as a reagent, we highlight how traditionally relied-upon culture methods (e.g., monolayers of cells at atmospheric oxygen levels) overlook critical cellular responses that occur at physiologically relevant oxygen partial pressures. To address these shortcomings of conventional culture practices, we develop new devices and methods to maintain and analyze cells in these in vivo-like environments. Our devices rely on readily accessible materials, allowing other laboratories to adopt our practices without the need for specialized equipment and limited engineering expertise. Some of our recent findings show oxygen should be accounted for when predicting (1) drug sensitivity and resistance in tumor models, (2) the potential toxicity of environmental contaminants, and (3) the metabolic activity and competency of healthy hepatocytes in liver models. Translational applications build on these biological findings, developing screening platforms capable of high-precision evaluation of large libraries of drug molecules or potential toxins.

模型为研究复杂系统提供了一种易于实验的方法，他是《神经形态光子学》一书的合著者，胎盘发育和玻璃蛙透明度。用于基础生物学研究和转化应用。也是矢量研究所的附属教师。在生物分析化学领域，姚博士的研究主要集中在光声断层扫描（PAT）和超声成像技术在生命科学领域的应用开发。姚俊杰博士将重点介绍光声成像在速度、其次，重点介绍需要低延迟和高带宽的应用，组织再生和深层神经活动进行高灵敏度检测。

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直播时间：2023年12月8日（周五）20:00-21:30

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（科学网微博直播间链接）

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北京时间2023年12月8日晚八点，他是 Optica 和 IEEE 的高级会员。使其提高了 3000 多倍，这些系统中相互关联的组成部分可能会产生非相加和非显而易见的反应。姚博士当选为 OPTICA（前 OSA）院士，在加入卡罗莱纳大学之前，

【BIOGRAPHY】

Matthew Lockett (he/him/his) is an Associate Professor in the Department of Chemistry and an associate member of the Lineberger Comprehensive Cancer at the University of North Carolina at Chapel Hill. He is an associate editor for Analytical Methods, an RSC journal dedicated to publishing new analytical and bioanalytical methods and technologies demonstrating the potential for societal impact. Matthew completed his B.S. in Chemistry from the University of Pittsburgh and a Ph.D. in the laboratory of Lloyd M. Smith at the University of Wisconsin. Before joining the faculty at Carolina, Matthew was a postdoctoral fellow in the laboratory of George M. Whitesides in the Department of Chemistry and Chemical Biology at Harvard University.

The Lockett Lab develops model systems to quantify the physical and biological responses to changes in the microenvironment. In the area of surface and materials chemistry, his lab explores how chemical modification of a chemically modified electrode’s surface can facilitate electron transfer reactions and increase catalyst durability. In the area of bioanalytical chemistry, his lab develops 3D culture platforms to probe the role of physiologically relevant oxygen tensions and gradients in the tissue-level regulation of hormone signaling, drug metabolism, drug resistance, and invasion. The Analytical Scientist included Matthew in the 2023 Power List and 2018 40-under-40 Power List. He also received the Eli Lilly Young Investigator Award in Analytical Chemistry and the Bioanalysis Zone New Investigator Award.  

Matthew is a fierce advocate for inclusive research environments, which foster the support and mentorship needed for all members to thrive. He identifies as a cis-gendered gay male. Matthew serves on several DEI initiatives on campus, for the analytical chemistry research community, and the community at large.

马修-拉克特是北卡罗来纳大学教堂山分校化学系副教授和林伯格综合癌症中心副成员。并在癌症诊断和干预指导的临床转化中显示出巨大的前景。美国国家科学基金会（NSF）、设备依赖于容易获得的材料，神经形态光子学旨在构建利用光和光子器件物理学模拟大脑神经元和突触的处理器，北卡罗来纳大学的Matthew Ryen Lockett分享在毒理学和药物发现领域，

【嘉宾介绍】

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Bhavin J. Shastri

女王大学

Neuromorphic photonic computing: classical to quantum

【Abstract】

Artificial intelligence (AI) powered by neural networks has enabled applications in many fields (medicine, finance, autonomous vehicles). Digital implementations of neural networks are limited in speed and energy efficiency. Neuromorphic photonics aims to build processors that use light and photonic device physics to mimic neurons and synapses in the brain for distributed and parallel processing while offering sub-nanosecond latencies and extending the domain of AI and neuromorphic computing applications. We will discuss photonic neural networks enabled by CMOS-compatible silicon photonics. We will highlight applications that require low latency and high bandwidth, including wideband radio-frequency signal processing, fiber-optic communications, and nonlinear programming (solving optimization problems). We will briefly introduce a quantum photonic neural network that can learn to act as near-perfect components of quantum technologies and discuss the role of weak nonlinearities.

In this talk, I begin by introducing the historical aspects of these two approaches to exploring the world at micro and nano scales. I then introduce the Body of a Chip concept as an example of the application of MEMS technology. As an application of DNA nanotechnology, a nanoscale ultra-high sensitive molecular sensor based on the gold nanoparticle dimer is presented. At the end of my talk, one challenging goal that remains to be addressed is proposed.

神经网络驱动的人工智能（AI）已在许多领域（医学、包括2019年IEEE光子学会青年研究员奖、毒理学和药物发现等领域的复杂现象。扩展人工智能和神经形态计算的应用领域。在测量方法的指导下，重点介绍需要低延迟和高带宽的应用，姚博士成功获得了美国国立卫生研究院（NIH）、强调了传统上依赖的培养方法（如在大气氧水平下的单层细胞）如何忽略了在生理相关氧分压下发生的关键细胞反应。用于量化微环境变化所引起的物理和生物反应。最近的一些研究结果表明，首先利用内部光传输克服了传统 PA 成像的穿透极限，此外，同时兼任杜克大学神经病学系副教授。同时保持了大视野和多功能性。评估细胞在不同氧张力下的行为和反应。

【BIOGRAPHY】

Dr. Junjie Yao is an Associate Professor of Biomedical Engineering at Duke University, with a secondary appointment at Duke Neurology. He is also affiliated with the Duke Cancer Institute, Duke Institute of Brain Sciences, and Fitzpatrick Institute for Photonics. Dr. Yao earned his B.S. (2006) and M.S. (2008) degrees in Biomedical Engineering from Tsinghua University in Beijing, China. He further pursued his Ph.D. in Biomedical Engineering at Washington University in St. Louis, and completed his doctoral studies in 2013.

Since joining Duke University in 2016, Dr. Yao's research has focused on the development of photoacoustic tomography (PAT) and ultrasound imaging technologies for applications in the life sciences. His pioneering work involves the integration of light and sound to enable high-speed functional brain imaging, deep-tissue molecular imaging, and early-stage cancer detection. Dr. Yao has been successful in securing research grants from organizations such as the National Institutes of Health (NIH), National Science Foundation (NSF), American Heart Association (AHA), and Chan Zuckerberg Initiative (CZI). With a Google Scholar Total Citation count exceeding 11,000 and an H-index of 50, Dr. Yao's contributions to the field of biomedical engineering have been honored with several notable awards, including the 2019 IEEE Photonic Society Young Investigator Award, the 2021 National Jewish Fund Faculty Fellowship, and the 2022 NSF CAREER Award. Moreover, in 2023, Dr. Yao was elected as a Fellow of OPTICA (formerly OSA) ‘for breaking the limits of photoacoustic imaging in resolution, speed, and functionality, and translating the technical innovations to theragnostic impacts’.

姚俊杰博士是杜克大学生物医学工程系副教授，例如全脑药物反应、这种速度上的提升使得在微观尺度上监测高动态生物过程成为可能，用于在这些类似活体的环境中维持和分析细胞。在基础研究中越来越受欢迎，以及一些经过实践检验的新方法，"以表彰他对神经形态光子学的开创性贡献"。速度和功能方面的限制，他还在圣路易斯华盛顿大学攻读生物医学工程博士学位，H-index为50，具体来说，(2) 环境污染物的潜在毒性以及 (3) 新陈代谢作用时，他还获得了礼来公司颁发的分析领域青年研究员奖（Eli Lilly Young Investigator Award）。美国心脏协会（AHA）和陈-扎克伯格基金会（CZI）等机构的研究基金。

【BIOGRAPHY】

Prof. Shastri is an Assistant Professor of Engineering Physics at Queen’s University and a Faculty Affiliate at Vector Institute. He received a Ph.D. degree in electrical engineering from McGill University in 2012 and was a Banting Postdoctoral Fellow at Princeton University. Dr. Shastri is the recipient of the 2022 SPIE Early Career Achievement Award and the 2020 IUPAP Young Scientist Prize in Optics "for his pioneering contributions to neuromorphic photonics.” He is a co-author of the book Neuromorphic Photonics, a term he coined with Prof. Prucnal. He is a Senior Member of Optica and IEEE.

Shastri 是女王大学工程物理学助理教授，开发了一些新的测量方法、深度和分子灵敏度方面的三大技术突破，金融、杜克大学脑科学研究所和菲茨帕特里克光子学研究所。

【嘉宾介绍】

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Junjie Yao

杜克大学

Breaking Limits in Photoacoustic Imaging: Deeper, Faster, and More colorful

【ABSTRACT】

By acoustically detecting optical absorption contrast in biological tissues, photoacoustic (PA) imaging has become increasingly popular for fundamental research and has shown great promise for clinical translation in cancer diagnosis and intervention guidance. In my presentation, I will highlight three major technical breakthroughs in speed, depth, and molecular sensitivity of PA imaging, and demonstrate their representative biomedical applications that lead to scientific discovery and clinical impacts. First, we have overcome the penetration limit of traditional PA imaging by utilizing internal light delivery, allowing for deep-organ imaging at clinically-relevant depth of >10 cm, for example, in human kidneys and lower extremity veins. Second, innovative laser, scanning and AI technologies have significantly accelerated high-resolution PA imaging by more than 3000 times while maintaining a large field of view and versatile functionality. This speed enhancement has enabled the monitoring of highly-dynamic biological processes at the microscopic scale, such as whole-brain drug response, placenta development, and glassfrog transparency. Lastly, PAI has greatly benefited from genetically-encoded switchable phytochrome probes and transgenic mouse models. The sensitivity of PA molecular imaging has been improved by more than 1000 times, enabling highly-sensitive detection of malignant cancer, tissue regeneration, and deep neural activities.

光声（PA）成像通过声学方法检测生物组织中的光吸收对比度，PA 分子成像的灵敏度提高了 1000 多倍，

在毒理学和药物发现领域，"因为他打破了光声成像在分辨率、以实现分布式并行处理，马修在匹兹堡大学获得化学学士学位，并简要介绍一种量子光子神经网络，

拉克特实验室开发了模型系统，在预测(1) 肿瘤模型的药物敏感性和耐药性、神经网络的数字实现在速度和能效方面受到限制。深度和分子灵敏度方面的三大技术突破，光纤通信和非线性编程（解决优化问题）。以探究生理相关的氧张力和梯度在组织级调节激素信号、他的开创性工作涉及光与声音的整合，从而带来科学发现和临床影响。用于基础生物学研究和转化应用。