Korean Doctors find rainbow trout in vaccine?
That's a real gud story. Ano decided to look at Charles Lieber's research group at Harvard (and Wuhan U) to see if the were putting, bats, gold fish, trout, or floaty toys in Covid 19 vaccine.
No. But they have been focused intently on machine mind interfaces that would allow centralized control of all human activities.
What were Lieber's chief interests in his research with China?
Here's a recent paper of which Lieber was lead author.
>…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 - patch clamp 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 minimally invasive 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.
http://cml.harvard.edu/assets/Nanowire-probes-could-drive-high-resolution-brain-machine-interfaces.pdf
>Today, research focused at the interface between the nervous system and electronics is not only leading to advances in fundamental neuroscience, but also unlocking the potential of implants capable of cellular-level therapeutic targeting. Ultimately, these personalized electronic therapies will provide new treatment modalities for neurodegenerative and neuropsychiatric illness; powerful control of prosthetics for restorative function in degenerative diseases, trauma and amputation; and even augmentation of human cognition. Overall, we believe that emerging advances in tissue-like electronics will enable minimally invasive devices capable of establishing a stable long-term cellular neural interface and providing long-term treatment for chronic neurological condition…
http://cml.harvard.edu/assets/5Sep19_Precision-electronic-medicine-in-the-brain.pdf
> ..syringe-injectable mesh electronics, have shown substantial promise for chronic studies of neural circuitry in the brains of live animals. A central challenge for exploiting these highly flexible materials for in vivo studies has centered on the development of
efficient input/output (I/O) connections to an external interface with high yield, low bonding resistance, and long-term stability. Here we report a new paradigm applied to the challenging case of injectable mesh electronics that exploits the high flexibility of nanoscale thickness two-sided metal I/O pad
http://cml.harvard.edu/assets/Nanoenabled-Direct-Contact-Interfacing-of-Syringe-Injectable-Mesh-Electronics.pdf