The arrest of the good Harvard Dr and part time cyborg scientist, Prof.Charles M. Lieber and his Chinese government operative colleagues, for delivering a bio toxin to a Wuhan Lab is disturbing at best.
Nanowire probes could drive high-resolution brain-machine interfaces
This is the dangerous kind of research of science fiction that apparently has no oversight by the People. It is becoming apparent that People need to seek damages for fraud, theft, public endangerment and other crimes directly connected to the Covid-19 outbreak. What about other enterprises created by a coordinated, financed, global health cartel, in a community of central bank protected, United Nations privilege.
The good Dr. Lieber is not only a hazardous biological study and toxic material enthusiast, he is also into linking your brain to a machine. this paper tell you how it is done. This of course can have very good, I MEAN REALLY GOOD ramifications for people with brain injuries and defects and all kinds of things. Also if you are tired of looking up your password on the proper notepad for that service you use only once a month, the good Doctor has a cure.
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Video report on arrest Fri. Apr., 1, 2020[/caption]
Yes dear friends, the good doctor can help you index and app you brain. Maybe even get you into advanced machine activated mind gaming. And seriously, if I am in control of it all, it could be amazing. However in the hands of a tyrannical regime based on world domination, it ought to raise a couple of your eyebrows. The charge of smuggling a toxic viral substance to a lab in Wuhan China, shortly before the outbreak of Covid-19 is bad enough. But the fact that these connections are financed by the taxpayers of the world and implemented by people who are obviously incapable of protecting anyone's interests but their own is a case in court for liable and damages against the People.
The Cyborg Project, - brain-machine interfaces
The personnel on the project and abstract
Anqi Zhanga, Yunlong Zhaoa,b, Siheng Sean Youa, Charles M. Lieber a,c,d,∗
a Department of Chemistry and Chemical Biology, Harvard University, Cambridge, MA 02138, USA b Advanced Technology Institute, University of Surrey, Guildford, Surrey GU2 7XH, UK c Center for Brain Science, Harvard University, Cambridge, MA 02138, USA d John A. Paulson School of Engineering and Applied Sciences, Harvard University, Cambridge, MA 02138, USA
a r t i c l e i n f o
Article history:
Received 25 October 2019
Accepted 27 November 2019
Available online xxx
Keywords:
Nanowires
Intracellular recording
Brain-machine interface
Bioelectronics
The Nifty Thing About It
It doesn't penetrate it rests against the tender cellular tissue. Pretty cool. I want one. But not as a slave.
[caption id="attachment_8659" align="alignnone" width="975"]
Fig. 1. Nanowire-enabled intracellular recording. a, A comparison between (i) conventional extracellular electrodes, (ii) patch-clamp electrodes, (iii) vertical nanowire arrays, and (iv) ultrasmall U-shaped nanowire probes. Intracellular recording achieved by the ultrasmall U-shaped nanowire transistor probes has demonstrated minimal invasiveness and similar quality to those obtained with the patch-clamp electrodes. b, Nanowire probe arrays could enable network-level parallel recording in vitro or in vivo.[/caption]
a b s t r a c t
A central challenge in the field of electrophysiology is to achieve intracellular recording of the complex
networks of electrogenic cells in tissues. The historical gold-standard of intracellular recording - patchclamp electrodes - do have limitations in terms of their invasiveness and difficulty to use in large-scale
parallel recording. Recent advances in nanowire-based bioelectronics have demonstrated minimallyinvasive intracellular interfaces and highly-scalable parallel recording at the network level. Combined
with in vivo recording platforms, these advances can enable investigations of dynamics in the brain and
drive the development of new brain-machine interfaces with unprecedented resolution and precision.
© 2019 Elsevier Ltd. All rights reserved...... continued in full
Nanowire probes could drive high-resolution brain-machine interfaces
