Learn how to bring optogenetics into undergraduate teaching labs using Drosophila or C. elegens models. You will get ideas from the demonstration video, lists of resources, and first-hand case studies prepared by Heather Rhodes, who works at the undergraduate institution, Denison University. After reviewing the materials in Module 5, you should be able to: - Access readily available C. elegans or Drosophila lines to demonstrate optogenetics in the classroom. - Understand how to assemble simple, low-cost equipment to conduct these experiments. - Use provided resources to run hands-on, inquiry-based student experiments.

Learn some of the common uses of optogenetics in an in vivo setting, as well as basic implementation strategies. After reviewing the materials in Module 4, you should be able to: - Describe several types of in vivo experiments in which optogenetics can be useful. - Describe basic experimental design used for in vivo optogenetic studies, including choice of optimal tools, stimulation parameters, and controls. - Identify some common potential confounds in optogenetic stimulation. - Describe key ways to validate optogenetic tools for in vivo experiments.

Learn the key technical issues that arise in the design and interpretation of optogenetics experiments. After reviewing the materials in Module 7, you should be able to: - Discuss how to select optimal tools and stimulation parameters for an optogenetics experiment. - Identify potential confounds related to stimulus parameters. - Describe key methods to validate optogenetic tools.

Learn about some major confounds, caveats, and limitations of optogenetics approaches. After reviewing the materials in Module 8, you should be able to: - Understand and control for potential confounds of in vivo optogenetic manipulations, including off-target expression of opsins, toxicity, and unintended effects of light delivery. - Describe the surprising and unintended effects of photostimulation on opsin-expressing neurons and downstream neural circuits, and how to use these effects to your advantage. - Understand and minimize potential confounds of synaptic plasticity and complex neurochemistry in the interpretation of in vivo optogenetic studies.

Learn basic approaches for implementing optogenetics methods to investigate brain function, including how to choose optogenetics versus other approaches, parameters for opsin selection, and pros and cons of different delivery methods. After reviewing the materials in Module 2, you should be able to: - Identify the advantages and disadvantages of optogenetic techniques compared to other techniques that explore the neural basis of behavior. - Understand the basic parameters of optogenetic tools. - Understand how to design appropriate light trains for optogenetic stimulation by taking account of the kinetics of optogenetic actuators. - Describe how to obtain and validate expression of optogenetic tools. - Identify factors important to consider when using optogenetic tools in combination with each other or other optical methods. - Describe pros and cons of different opsin delivery methods. - Comprehend the importance of adeno-associated virus (AAV) serotypes in regulating tropism, retrograde versus anterograde transport, and other factors.

Learn basic elements of experimental design that are particularly relevant in optogenetic experiments from co-organizer Alexandra Nelson. After reviewing the materials in Module 6, you should be able to: - Describe some of the common designs of optogenetic behavioral studies, and their advantages and disadvantages. - Identify some of the common pitfalls of optogenetics study design that might lead to challenges in reproducibility. - Describe some of the sources of variability that can be minimized during experimental execution.

Learn the fundamentals of ex vivo applications of optogenetic manipulations, including basic experimental design and required equipment. After reviewing the materials in Module 3, you should be able to: - Define the type of scientific questions that can be addressed using optogenetics in ex vivo preparations, and provide examples. - Understand proper experimental design of ex vivo optogenetic experiments. - Compare optogenetics to alternative ex vivo methodologies. - List key concepts in the design and interpretation of ex vivo optogenetic experiments. - Discuss the basic setup of ex vivo optogenetic experiments.

Katrin Franke’s research seeks to understand how the retinal network disassembles complex visual input. Previous research on this topic conducted by the field often focused on individual types of retinal cells, but Franke sought to record complete populations of neurons to capture the full functional diversity of parallel retinal channels. Through her approach, her findings have increased the understanding of how the mammalian retina processes visual information. For her outstanding work, she was awarded the Nemko Prize in Cellular or Molecular Neuroscience in 2017. What led to your interest in visual processing? Information processing in the visual system first attracted my interest as a master’s student at Tübingen University in a lecture series about the retina as a model system in neuroscience. I found it extremely fascinating that retinal cells perform computations to “decide” what’s important enough to be sent to the brain, determining what we see. I decided to do a PhD in this field because I wanted to better understand how the retina decomposes the incoming visual stream into its relevant components that can then be interpreted by the brain. In the last few years, I developed a strong interest in visual ecology, which aims to understand how different animal species use their visual systems to meet their ecological needs. I think investigating visual processing and comparing findings from different species is exciting and essential to discover universal and general principles of vision.

Zebrafish have gained prominence as a model organism in neuroscience over the past several decades, generating key insight into the development and functioning of the vertebrate brain. However, techniques for whole brain mapping in adult stage zebrafish are lacking. Here, we describe a pipeline built using open-source tools for whole-brain activity mapping in adult zebrafish. Our pipeline combines advances in histology, microscopy, and machine learning to capture cfos activity across the entirety of the brain. Following tissue clearing, whole brain images are captured using light-sheet microscopy and registered to the recently created adult zebrafish brain atlas (AZBA) for automated segmentation. By way of example, we used our pipeline to measure brain activity after zebrafish were subject to the novel tank test, one of the most widely used behaviors in adult zebrafish. Cfos levels peaked 15 minutes following behavior and several regions, including those containing serotoninergic and dopaminergic neurons, ...

Anterior-posterior interactions in the alpha band (8-12 Hz) have been implicated in a variety of functions including perception, attention, and working memory. The underlying neural communication can be flexibly controlled by adjusting phase relations when activities across anterior-posterior regions oscillate at a matched frequency. We thus investigated how alpha oscillation frequencies spontaneously converged along anterior-posterior regions by tracking oscillatory EEG activity while participants rested. As more anterior-posterior regions (scalp sites) frequency-converged, the probability of additional regions joining the frequency convergence increased, and so did oscillatory synchronization at participating regions (measured as oscillatory power), suggesting that anterior-posterior frequency convergences are driven by inter-regional entrainment. Notably, frequency convergences were accompanied by two types of approximately linear phase gradients, one progressively phase-lagged in the anterior direction...