Hai Lab, UW-Madison BME
@AviadHai
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Neuroengineer & Neuroscientist, Associate Professor of Biomedical Engineering, UW-Madison
Wisconsin, USA
Joined October 2018
Check us out, Hai lab @UWMadison_BME @UWMadEngr @wi_tne at devil's lake, WI 2022: https://t.co/utu51cmvDR an outdoors breather for a great summer everyone!
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Congratulations to @AdamVareberg @UWMadison_BME for a well deserved award!
Congrats to Adam Vareberg, a @UWMadison_BME PhD student in the lab of @AviadHai, on landing a 2025-26 Grainger Wisconsin Distinguished Graduate Fellowship. https://t.co/LxmQIpZF03
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Thank you to my incredible students in BME / NTP "Nanotechnology in Neuroscience" at @UWMadison_BME this spring, and to Xiaoxuan Ren for being such a fantastic TA, @AdamVareberg for demonstrating new MRI methods in neuroscience. Looking forward to continuing this class next year!
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Excellent work!
Fresh off the press, our paper linking #TravelingWaves #Cortex #Dendrites #inhibition is online @ScienceAdvances. Brilliant effort by @dgonzales1990 @Hammad_FKhan @HayagreevKeri and others. A big thanks to @_mullerlab @LabPluta & @NIH_CommonFund @AFOSR
https://t.co/C7BUnfi5m9
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Thank you @PurdueBME and @KrishnaJayant for a great visit and seminar! Special thanks to @Om_Kolhe for an early morning tour at @BNCPurdue !
Join us for the Weldon School Distinguished Research Seminar featuring Aviad Hai, Assistant Professor at the University of Wisconsin-Madison. He will present "Bioelectromagnetic Brain Agents: New Routes for Tapping into the Nervous System Communication Grid."
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Join us for the Weldon School Distinguished Research Seminar featuring Aviad Hai, Assistant Professor at the University of Wisconsin-Madison. He will present "Bioelectromagnetic Brain Agents: New Routes for Tapping into the Nervous System Communication Grid."
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Congratulations to the Undergraduate Winner of the 2024 Collegiate Inventors Competition® The Nerve Ninja! @UWMadison We’re inspired by your creativity and dedication, and we can’t wait to see how you continue to impact the world.
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After a great lunch we’re hearing from a panel of BME faculty about solving fundamental problems in medicine through cutting-edge research in biomedical engineering. @Filiz_Yesilkoy @UWMadisonLOCI @AviadHai @melissa_skala
#UWBME25
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Kicking things off with a wonderful welcome from Peter Tong Chair Paul Campagnola and an overview of the department history from @BillMurphyUW. #UWBME25
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New early stage funding from @NSF is supporting research by @UWMadison_BME’s @AviadHai into new types of minimally invasive sensors for brain imaging. https://t.co/0Fpyb73wni
engineering.wisc.edu
Aviad Hai, a Vilas Early Career assistant professor of biomedical engineering at the University of Wisconsin-Madison, has received an Early-Concept Grant for Exploratory Research (EAGER) from the...
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Neural engineers in @UWMadison_BME led by @AviadHai have developed a diamond-embedded, nanofabricated coil that expands their growing toolkit of noninvasive devices and methods for better monitoring and stimulating the brain. https://t.co/XWsfDPPmV8
engineering.wisc.edu
Neural engineers at the University of Wisconsin-Madison have developed a unique diamond-embedded, nanofabricated coil that expands their growing toolkit of noninvasive devices and methods for better...
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Congratulations again to @ilhan_bok and collaborators on pioneering nitrogen vacancy diamond embedded nanocoils for magnetometery! @UWMadisonECE @UWMadison_BME
ECE PhD student Ilhan Bok is lead author on a paper in the journal 𝘔𝘪𝘤𝘳𝘰𝘴𝘺𝘴𝘵𝘦𝘮𝘴 𝘢𝘯𝘥 𝘕𝘢𝘯𝘰𝘦𝘯𝘨𝘪𝘯𝘦𝘦𝘳𝘪𝘯𝘨, published by Springer Nature. "Nanofabricated high turn-density spiral coils for on-chip electromagneto-optical conversion" https://t.co/DVNMNclKtm
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ECE PhD student Ilhan Bok is lead author on a paper in the journal 𝘔𝘪𝘤𝘳𝘰𝘴𝘺𝘴𝘵𝘦𝘮𝘴 𝘢𝘯𝘥 𝘕𝘢𝘯𝘰𝘦𝘯𝘨𝘪𝘯𝘦𝘦𝘳𝘪𝘯𝘨, published by Springer Nature. "Nanofabricated high turn-density spiral coils for on-chip electromagneto-optical conversion" https://t.co/DVNMNclKtm
engineering.wisc.edu
Neural engineers at the University of Wisconsin-Madison have developed a unique diamond-embedded, nanofabricated coil that expands their growing toolkit of noninvasive devices and methods for better...
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To better understand connections in the brain, @UWMadison neuroengineers have developed and tested a method that reverse engineers networks of neural connectivity while leveraging data that lacks the brain's actual level of granularity in timescale.
engineering.wisc.edu
By better understanding the connections among different parts of the brain—from individual neurons all the way up to whole regions—neuroscientists could glean insights about how the brain works and...
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Can sensing of magnetic fields move towards real time detection of single neuron amplitudes (nT)? It might! See our recent work on Nitrogen vacancy (NV) diamond embedded nanocoils for enhanced magnetometry, published today: https://t.co/qLwccBGpfg
@UWMadEngr @bme
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Congratulations to @AdamVareberg and collaborators!
Better understanding connections among different parts of the brain could transform our knowledge of neural function and disease. @UWMadison_BME’s @AviadHai devised a method to reverse engineer networks of neural connectivity using suboptimal data. https://t.co/vxVIqWUKlS
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Better understanding connections among different parts of the brain could transform our knowledge of neural function and disease. @UWMadison_BME’s @AviadHai devised a method to reverse engineer networks of neural connectivity using suboptimal data. https://t.co/vxVIqWUKlS
engineering.wisc.edu
By better understanding the connections among different parts of the brain—from individual neurons all the way up to whole regions—neuroscientists could glean insights about how the brain works and...
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Can we decipher neuronal connections from data much slower than single action potentials? See our work published today and congratulations to @AdamVareberg and collaborators @ilhan_bok Jenna Eizadi and Xiaoxuan Ren:
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Can we decipher neuronal connections from data much slower than single action potentials? See our work published today and congratulations to @AdamVareberg and collaborators @ilhan_bok Jenna Eizadi and Xiaoxuan Ren:
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