Stable behavioral and neural responses to thermal stimulation despite large changes in the<i>Hydra vulgaris</i>nervous system

Tzouanas, Constantine N.; S, Kim; Kn, Badhiwala; Bw, Avants; Jt, Robinson

doi:10.1101/787648

Cited by 7 publications

(13 citation statements)

References 42 publications

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“…Although movement of the animal can produce some noise in the ∆F/F signal, the deformable Hydra body makes it difficult to generate adaptive ROIs that move with the animal. Nevertheless, the bright synchronous calcium activity in the Hydra peduncle allows for fixed ROIs to effectively capture calcium dynamics 41,45 .…”

Section: In Vivo Epifluorescence Calcium Imaging Of Whole Animal Withmentioning

confidence: 99%

In vivofluorescence imaging with a flat, lensless microscope

Adams

Boominathan

Gao

et al. 2020

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Fluorescence imaging over large areas of the brain in freely behaving animals would allow researchers to better understand the relationship between brain activity and behavior; however, traditional microscopes capable of high spatial resolution and large fields of view (FOVs) require large and heavy lenses that restrict animal movement. While lensless imaging has the potential to achieve both high spatial resolution and large FOV with a thin lightweight device, lensless imaging has yet to be achieved in vivo due to two principal challenges: (a) biological tissue typically has lower contrast than resolution targets, and (b) illumination and filtering must be integrated into this non-traditional device architecture. Here, we show that in vivo fluorescence imaging is possible with a thin lensless microscope by optimizing the phase mask and computational reconstruction algorithms, and integrating fiber optic illumination and thin-film color filters. The result is a flat, lensless imager that achieves better than 10 μm spatial resolution and a FOV that is 30× larger than other cellular resolution miniature microscopes.

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Section: In Vivo Epifluorescence Calcium Imaging Of Whole Animal Withmentioning

confidence: 99%

In vivofluorescence imaging with a flat, lensless microscope

Adams

Boominathan

Gao

et al. 2020

Preprint

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“…Bioelectronic platforms combined with calcium imaging can also be applied to other transparent, millimeter-sized animals such as Hydra ( Figure 3C) (Badhiwala et al, 2018;Tzouanas et al, 2019). As is the case for C. elegans, studies of Hydra may help researchers to understand how neural circuits distributed throughout the nervous system regulate simple behaviors such as locomotion and feeding ( Figure 3C).…”

Section: Bioelectronic Applicationsmentioning

confidence: 99%

“…However, the unique anatomy of Hydra compared with animals with bilateral symmetry such as C. elegans and zebrafish offer opportunities to study neural circuits in animals with very different neural architectures and body plans. Unlike the nervous systems of C. elegans, Drosophila, and zebrafish that are relatively static and stereotyped, the Hydra nervous system is highly regenerative, variable between animals, and can dynamically change throughout the lifetime of an individual animal (Bode et al, 1973;Gierer et al, 1972;Tzouanas et al, 2019). This characteristic of the nervous system can be used as a powerful tool to understand how the same behavior is regulated when the number of neurons varies by up to an order of magnitude (Tzouanas et al, 2019).…”

Section: Bioelectronic Applicationsmentioning

confidence: 99%

“…Unlike the nervous systems of C. elegans, Drosophila, and zebrafish that are relatively static and stereotyped, the Hydra nervous system is highly regenerative, variable between animals, and can dynamically change throughout the lifetime of an individual animal (Bode et al, 1973;Gierer et al, 1972;Tzouanas et al, 2019). This characteristic of the nervous system can be used as a powerful tool to understand how the same behavior is regulated when the number of neurons varies by up to an order of magnitude (Tzouanas et al, 2019). Similarly, these animals can also be used to study neural regeneration following extensive damage (Gierer et al, 1972;Kü cken et al, 2008;Miljkovic-Licina et al, 2007;Technau et al, 2000).…”

Section: Bioelectronic Applicationsmentioning

confidence: 99%

“…Using these behaviors, researchers can interrogate fundamental properties of neural circuits such as multisensory integration and sensorimotor transformations (Clark et al, 2013;Ghosh et al, 2017;Kaplan et al, 2018). Among the many behaviors in these animals that enable neural circuit dissection are contractions in the cnidarian Hydra (Dupre and Yuste, 2017;Passano and McCullough, 1964;Tzouanas et al, 2019); thermotaxis, behavioral state transitions, and sleep in C. elegans (Butler et al, 2014;Cho and Sternberg, 2014;Clark et al, 2006;Flavell et al, 2013;Gallagher et al, 2013;Garrity et al, 2010;Hawk et al, 2018;Hedgecock and Russell, 1975;Hill et al, 2014;Kaplan et al, 2019;Li et al, 2014;Raizen et al, 2008); circadian rhythms and social behaviors in Drosophila (Anderson, 2016;Artiushin and Sehgal, 2017;Guo et al, 2018;Kayser and Biron, 2016;Lim et al, 2014;Saigusa et al, 2002;Stockinger et al, 2005); and sensorimotor integration and sleep in zebrafish (Ahrens et al, 2012;Chen et al, 2018;Cong et al, 2017;Gandhi et al, 2015;Haesemeyer et al, 2018;Naumann et al, 2016;Oikonomou and Prober, 2017;Severi et al, 2014;Vladimirov et al, 2018;Zhdanova et al, 2001;Zimmerman et al, 2008). Furthermore, many of these behaviors show a surprising resemblance to mammalian behaviors at the molecu...…”

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confidence: 99%

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Bioelectronics for Millimeter-Sized Model Organisms

et al. 2020

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Advances in microfabrication technologies and biomaterials have enabled a growing class of electronic devices that can stimulate and record bioelectronic signals. Many of these devices have been developed for humans or vertebrate animals, where miniaturization allows for implantation within the body. There are, however, another class of bioelectronic interfaces that exploit microfabrication and nanoelectronics to record signals from tiny, millimeter-sized organisms. In these cases, rather than implanting a device inside an animal, animals themselves are loaded in large numbers into bioelectronic devices for neural circuit and behavioral interrogation. These scalable interfaces provide platforms to develop new therapeutics as well as better understand basic principles of bioelectronic communication, neuroscience, and behavior. Here we review recent progress in these bioelectronic technologies and describe how they can complement on-chip optical, mechanical, and chemical interrogation methods to achieve high-throughput, multimodal studies of millimeter-sized small animals. ADVANTAGES OF MILLIMETER-SIZED ORGANISMS Small model organisms such as Caenorhabditis elegans, Drosophila, and zebrafish have been a cornerstone for understanding principles of neurobiology, behavior, genetics, and development (Davis, 2004; Sattelle and Buckingham, 2006; Stewart et al., 2014). Despite their small nervous systems and less anatomical complexity compared with that of mammalian models, there are significant advantages in using millimeter-sized animals to answer fundamental questions in neurobiology (Figure 1).

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