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PRODID:IEEE vTools.Events//EN
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TZID:America/Phoenix
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DTSTART:19671029T010000
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TZOFFSETTO:-0700
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BEGIN:VEVENT
DTSTAMP:20260630T164128Z
UID:089B1E91-2E77-4F33-8311-7180BB1AFBB6
DTSTART;TZID=America/Phoenix:20260915T110000
DTEND;TZID=America/Phoenix:20260915T120000
DESCRIPTION:What if medical electronics could become virtually invisible 
 – not only conforming seamlessly to the human body but also sensing\, co
 mmunicating\, and even interacting with living tissues? Recent advances in
  graphene and other two-dimensional materials are making this vision possi
 ble by enabling a new generation of wearable\, implantable\, and intellige
 nt bioelectronic systems. Their unique combination of atomic thickness\, f
 lexibility\, transparency\, electrical conductivity\, and biocompatibility
  is fundamentally changing how electronics interface with biology.\n\nIn t
 his talk\, I will explore how these materials are enabling technologies th
 at were previously impossible. I will introduce graphene electronic tattoo
 s that laminate onto the skin like temporary tattoos to provide long-term\
 , high-fidelity monitoring of electrophysiological\, mechanical\, and bioc
 hemical signals. Applications will include continuous cuffless blood press
 ure monitoring using bioimpedance\, multimodal physiological sensing\, and
  wearable biosensors capable of tracking biomarkers directly from sweat. B
 eyond the skin\, I will discuss the translation of these ultrathin biointe
 rfaces into implantable devices\, including transparent graphene arrays fo
 r recording and stimulating the heart. These tissue-conformable interfaces
  enable simultaneous electrical sensing\, optical imaging\, and optogeneti
 c modulation while opening new opportunities for minimally invasive therap
 ies and next-generation bioelectronic medicine. Finally\, I will present o
 ur recent work on graphene-based neuromorphic devices that emulate the ada
 ptive behavior of biological synapses with energy efficiencies approaching
  those of neurons. These systems represent an important step toward intell
 igent bioelectronics capable of learning from physiological signals\, enab
 ling adaptive biosensing\, closed-loop therapeutics\, and future human–m
 achine interfaces. Together\, these examples illustrate how atomically thi
 n materials are driving the shift from rigid electronic devices to bioelec
 tronic systems that integrate naturally with living tissues.\n\nSpeaker(s)
 : Dmitry\, \n\nVirtual: https://events.vtools.ieee.org/m/565804
LOCATION:Virtual: https://events.vtools.ieee.org/m/565804
ORGANIZER:daphnechen@asu.edu
SEQUENCE:6
SUMMARY:Engineering Invisible Electronics: How Graphene is Changing the Way
  We Measure Human Health
URL;VALUE=URI:https://events.vtools.ieee.org/m/565804
X-ALT-DESC:Description: &lt;br /&gt;&lt;p class=&quot;MsoNormal&quot; style=&quot;text-align: justi
 fy\; text-justify: inter-ideograph\; text-indent: .5in\;&quot;&gt;&lt;span style=&quot;fon
 t-family: &#39;Times New Roman&#39;\,serif\; mso-fareast-font-family: &#39;Times New R
 oman&#39;\;&quot;&gt;What if medical electronics could become virtually invisible &amp;nda
 sh\; not only conforming seamlessly to the human body but also sensing\, c
 ommunicating\, and even interacting with living tissues? Recent advances i
 n graphene and other two-dimensional materials are making this vision poss
 ible by enabling a new generation of wearable\, implantable\, and intellig
 ent bioelectronic systems. Their unique combination of atomic thickness\, 
 flexibility\, transparency\, electrical conductivity\, and biocompatibilit
 y is fundamentally changing how electronics interface with biology.&lt;/span&gt;
 &lt;/p&gt;\n&lt;p class=&quot;MsoNormal&quot; style=&quot;text-align: justify\; text-justify: inte
 r-ideograph\; text-indent: .5in\;&quot;&gt;&lt;span style=&quot;font-family: &#39;Times New Ro
 man&#39;\,serif\; mso-fareast-font-family: &#39;Times New Roman&#39;\;&quot;&gt;In this talk\,
  I will explore how these materials are enabling technologies that were pr
 eviously impossible. I will introduce graphene electronic tattoos that lam
 inate onto the skin like temporary tattoos to provide long-term\, high-fid
 elity monitoring of electrophysiological\, mechanical\, and biochemical si
 gnals. Applications will include continuous cuffless blood pressure monito
 ring using bioimpedance\, multimodal physiological sensing\, and wearable 
 biosensors capable of tracking biomarkers directly from sweat. Beyond the 
 skin\, I will discuss the translation of these ultrathin biointerfaces int
 o implantable devices\, including transparent graphene arrays for recordin
 g and stimulating the heart. These tissue-conformable interfaces enable si
 multaneous electrical sensing\, optical imaging\, and optogenetic modulati
 on while opening new opportunities for minimally invasive therapies and ne
 xt-generation bioelectronic medicine. Finally\, I will present our recent 
 work on graphene-based neuromorphic devices that emulate the adaptive beha
 vior of biological synapses with energy efficiencies approaching those of 
 neurons. These systems represent an important step toward intelligent bioe
 lectronics capable of learning from physiological signals\, enabling adapt
 ive biosensing\, closed-loop therapeutics\, and future human&amp;ndash\;machin
 e interfaces. Together\, these examples illustrate how atomically thin mat
 erials are driving the shift from rigid electronic devices to bioelectroni
 c systems that integrate naturally with living tissues.&lt;/span&gt;&lt;/p&gt;
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