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DESCRIPTION:The modern electronic components are rigid\, solid\, and stiff 
 – a terrible match for soft\, squishy\, and deformable tissue such as hu
 man skin or inner organs such as the brain. The material mismatch results 
 in the conceptual incompatibility of modern electronics with biological ti
 ssue. Nanoscale materials\, such as graphene and other 2D materials\, on t
 he other hand\, are unique constructs: in addition to their apparent unobt
 rusive atomic thickness\, they are flexible\, transparent\, and biocompati
 ble\, matching perfectly with biological tissue.\n\nUsing atomically thin 
 and electrically conductive graphene electronic tattoos (GETs)\, we develo
 ped imperceptible monitoring technologies for measuring blood pressure wit
 h an unprecedented accuracy. Unlike other wearables\, GETs are lightweight
  and skin-conformable\, eliminating discomfort during long-term monitoring
 . Recently\, we also translated this technology into implantable sensors\,
  demonstrating the sensing and stimulation of the mammalian heart\, includ
 ing treatment of arrhythmia with graphene pacemakers. The arrays show supe
 rior electrochemical properties\, while the transparency of the graphene s
 tructures allows for simultaneous optical mapping of cardiac action potent
 ials and optogenetic stimulation. Additionally\, we advanced in creating t
 issue-integratable bioelectronic systems resembling biological neurons usi
 ng soft\, flexible\, and biocompatible artificial synaptic neuromorphic tr
 ansistors based on graphene and Nafion\, boosting superior energy efficien
 cy.\n\nTaken together\, these breakthroughs on wearable\, implantable\, an
 d neuromorphic frontiers open up new possibilities for wearable and implan
 table graphene (and other 2D Materials like MoS2\, PtSe2\, PtTe2\, and oth
 ers) bioelectronics to transform healthcare.\n\nSpeaker(s): Prof.  Dmitry 
 Kireev\n\nAgenda: \n6:30 pm Introduction of speaker\n\n6:35 pm Technical p
 resentation\n\nVirtual: https://events.vtools.ieee.org/m/409274
LOCATION:Virtual: https://events.vtools.ieee.org/m/409274
ORGANIZER:fsemendy@ieee.org
SEQUENCE:18
SUMMARY:2D Materials for Bioelectronics
URL;VALUE=URI:https://events.vtools.ieee.org/m/409274
X-ALT-DESC:Description: <br /><p>The modern electronic components are rigid
 \, solid\, and stiff &ndash\; a terrible match for soft\, squishy\, and de
 formable tissue such as human skin or inner organs such as the brain. The 
 material mismatch results in the conceptual incompatibility of modern elec
 tronics with biological tissue. Nanoscale materials\, such as graphene and
  other 2D materials\, on the other hand\, are unique constructs: in additi
 on to their apparent unobtrusive atomic thickness\, they are flexible\, tr
 ansparent\, and biocompatible\, matching perfectly with biological tissue.
 </p>\n<p>Using atomically thin and electrically conductive graphene electr
 onic tattoos (GETs)\, we developed imperceptible monitoring technologies f
 or measuring blood pressure with an unprecedented accuracy. Unlike other w
 earables\, GETs are lightweight and skin-conformable\, eliminating discomf
 ort during long-term monitoring. Recently\, we also translated this techno
 logy into implantable sensors\, demonstrating the sensing and stimulation 
 of the mammalian heart\, including treatment of arrhythmia with graphene p
 acemakers. The arrays show superior electrochemical properties\, while the
  transparency of the graphene structures allows for simultaneous optical m
 apping of cardiac action potentials and optogenetic stimulation. Additiona
 lly\, we advanced in creating tissue-integratable bioelectronic systems re
 sembling biological neurons using soft\, flexible\, and biocompatible arti
 ficial synaptic neuromorphic transistors based on graphene and Nafion\, bo
 osting superior energy efficiency.</p>\n<p>Taken together\, these breakthr
 oughs on wearable\, implantable\, and neuromorphic frontiers open up new p
 ossibilities for wearable and implantable graphene (and other 2D Materials
  like MoS<sub>2</sub>\, PtSe<sub>2</sub>\, PtTe<sub>2</sub>\, and others) 
 bioelectronics to transform healthcare.</p><br /><br />Agenda: <br /><p>6:
 30 pm Introduction of speaker</p>\n<p>6:35 pm Technical presentation</p>
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