Collaborative Research: Olfactory Navigation: Dynamic Computing in the Natural Environment

合作研究：嗅觉导航：自然环境中的动态计算

• 批准号: 1555643
• 负责人: Lucia Jacobs
• 金额: $ 78.09万
• 依托单位: University of California-Berkeley
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2015
• 资助国家: 美国
• 起止时间: 2015-11-01 至 2021-06-30
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1555643&HistoricalAwards=false
• 关键词: Collaborative; Research; Olfactory; Navigation; Dynamic

This project was developed at an NSF Ideas Lab on "Cracking the Olfactory Code" and is jointly funded by the Physics of Living Systems program in the Physics Division, the Mathematical Biology program in the Division of Mathematical Sciences, the Chemistry of Life Processes program in the Chemistry Division, and the Neural Systems Cluster in the Division of Integrative Organismal Systems. The project is a synergistic combination of laboratory experiments and computer modeling that will lead to better understanding of how animals use the sense of smell to navigate in the real world. Almost universally, from flies to mice to dogs, animals use odors to find critical resources, such as food, shelter, and mates. To date, no engineered device can replicate this function and understanding the code used by the brain will lead to many novel applications. Cracking codes, from neural codes to the Enigma code of WWII, is aided by a deep understanding of the content of messages that are being transmitted and how they will be used by their intended receivers. To crack the olfactory code, the team will focus on how odors move in landscapes, how animals extract spatial and temporal cues from odor landscapes, and how they use movement for enhancing these cues while progressing towards their targets. The proposed work encompasses physical measurement of odor plumes, behavioral measurement of animals' paths through olfactory environments, electrophysiological and optical measurement of neural activity during olfactory navigation, perturbations of the environment via virtual reality and of neuronal hardware via genetics, and multilevel mathematical modeling. The PIs will teach and work with undergraduate, graduate and postdoctoral students and especially recruit students from underrepresented groups in science. The project's results may lead to improved methods for the detection of explosives, new olfactory robots to replace trained animals, and new theoretically-grounded advances in robotic control. The project will inform the development of technologies that interfere with the ability of flying insects (including disease vectors and crop pests) to locate their odor target, thus opening a new door for developing 'green' technologies to solve problems that are of global economic and humanitarian importance. This proposal is a synergistic combination of laboratory experiments and computational modeling that will probe how animals use olfaction to navigate in their environment. Specifically, this effort seeks to solve the difficult problem of olfactory navigation through the following aims: (i) Generate and quantify standardized, naturalistic odor environments that can be used to perform empirical and theoretical tests of navigation strategies; (ii) Determine phenomenological algorithms for odor-guided navigation through behavioral experiments in diverse animal species; (iii) Determine how odor cues for navigation are encoded and used in the nervous system by recording neuronal data and simulating putative neural circuits that implement these processes; (iv) Manipulate olfactory environments and neural circuitry, to evaluate model robustness. In contrast to previous attempts to understand olfactory navigation, the present strategy emphasizes mechanisms that are biologically feasible and explores the wide range of temporal and spatial scales in which animals successfully navigate. The project will generate datasets of immediate use and importance to scientists in theoretical biology and mathematics, engineering (fluid mechanics, electronic olfaction, and robotics) and biology (neuroscience, ecology and evolution).

这个项目是由美国国家科学基金会思想实验室“破解嗅觉密码”开发的，并由物理部的生命系统物理学项目、数学科学部的数学生物学项目、化学部的生命过程化学项目和综合组织系统部的神经系统集群共同资助。该项目是实验室实验和计算机建模的协同结合，将导致更好地理解动物如何利用嗅觉在现实世界中导航。几乎普遍的是，从苍蝇到老鼠再到狗，动物利用气味来寻找关键的资源，如食物、庇护所和配偶。到目前为止，还没有一种工程设备可以复制这种功能，理解大脑使用的代码将导致许多新的应用。破解密码，从神经密码到二战的谜码，都得益于对正在传输的消息的内容以及预期接收者将如何使用这些消息的深入理解。为了破解嗅觉密码，该团队将专注于气味如何在景观中移动，动物如何从气味景观中提取空间和时间线索，以及它们如何在向目标前进的同时利用运动来增强这些线索。这项拟议的工作包括气味羽流的物理测量，动物通过嗅觉环境的行为测量，嗅觉导航期间神经活动的电生理和光学测量，通过虚拟现实对环境的扰动，通过遗传学对神经元硬件的扰动，以及多级数学建模。PI将教授本科生、研究生和博士后，并与他们合作，特别是从理科代表性较低的群体中招收学生。该项目的结果可能会导致爆炸物检测方法的改进，新的嗅觉机器人取代训练有素的动物，以及机器人控制方面的新的理论上的进步。该项目将为干扰飞行昆虫(包括病媒和作物害虫)定位气味目标的技术的开发提供信息，从而为开发解决具有全球经济和人道主义意义的问题的“绿色”技术打开一扇新的大门。这项提议是实验室实验和计算建模的协同结合，将探索动物如何利用嗅觉在环境中导航。具体地说，这项工作试图通过以下目标解决嗅觉导航的难题：(I)产生和量化标准化的、自然的气味环境，可用于对导航策略进行经验和理论测试；(Ii)通过在不同动物物种中的行为实验，确定气味导航的现象学算法；(Iii)通过记录神经元数据并模拟实施这些过程的假定神经回路，确定导航气味提示如何在神经系统中编码和使用；(Iv)操纵嗅觉环境和神经回路，以评估模型的稳健性。与以前试图了解嗅觉导航的尝试不同，本策略强调生物学上可行的机制，并探索动物成功导航的广泛的时间和空间尺度。该项目将产生对理论生物学和数学、工程学(流体力学、电子嗅觉和机器人)和生物学(神经科学、生态学和进化论)的科学家立即使用和重要的数据集。