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How can flesh and blood brains give rise to pains and pleasures, dreams and desires, sights and sounds? Some believe this ‘hard problem’ of consciousness can never be solved. Can we expect any breakthroughs as the science of the mind progresses?

Our annual debate this year considers whether the problem of consciousness really is intractable. Our illustrious panel is neuroscientist Anil Seth and philosophers Louise Antony, Maja Spener and Philip Goff, with the BBC’s Ritula Shah chairing.

Speakers.
Anil Seth is Professor of Cognitive and Computational Neuroscience at the University of Sussex.
Louise Antony is Professor Emerita at the University of Massachusetts, Amherst.
Maja Spener is Associate Professor in Philosophy at the University of Birmingham.
Philip Goff is Associate Professor in the Department of Philosophy at Durham University.

Chair.
Ritula Shah is a journalist and presenter of The World Tonight on BBC Radio 4.

Synaptic plasticity is a critical process that regulates neuronal activity by allowing neurons to adjust their synaptic strength in response to changes in activity. Despite the high proximity of excitatory glutamatergic and inhibitory GABAergic postsynaptic zones and their functional integration within dendritic regions, concurrent plasticity has historically been underassessed. Growing evidence for pathological disruptions in the excitation and inhibition (E/I) balance in neurological and neurodevelopmental disorders indicates the need for an improved, more “holistic” understanding of synaptic interplay. There continues to be a long-standing focus on the persistent strengthening of excitation (excitatory long-term potentiation; eLTP) and its role in learning and memory, although the importance of inhibitory long-term potentiation (iLTP) and depression (iLTD) has become increasingly apparent. Emerging evidence further points to a dynamic dialogue between excitatory and inhibitory synapses, but much remains to be understood regarding the mechanisms and extent of this exchange. In this mini-review, we explore the role calcium signaling and synaptic crosstalk play in regulating postsynaptic plasticity and neuronal excitability. We examine current knowledge on GABAergic and glutamatergic synapse responses to perturbances in activity, with a focus on postsynaptic plasticity induced by short-term pharmacological treatments which act to either enhance or reduce neuronal excitability via ionotropic receptor regulation in neuronal culture. To delve deeper into potential mechanisms of synaptic crosstalk, we discuss the influence of synaptic activity on key regulatory proteins, including kinases, phosphatases, and synaptic structural/scaffolding proteins. Finally, we briefly suggest avenues for future research to better understand the crosstalk between glutamatergic and GABAergic synapses.

Ligand-gated ion channel GABA type A receptors (GABAARs) mediate the majority of fast inhibition in the central nervous system, while glutamatergic AMPA receptors (AMPARs) and NMDA receptors (NMDARs) collectively mediate fast excitatory neurotransmission. NMDARs particularly play a unique role in synaptic plasticity due to high calcium permeability and voltage-dependent Mg2+ block typically relieved by AMPAR-mediated depolarization. Slow inhibition and excitation are generated by G protein-coupled, GABA type B (GABABRs) and metabotropic glutamate receptors (mGluRs), respectively. The concerted action of these receptors balances neuronal excitability. A close and coordinated spatial relationship between glutamatergic and GABAergic synapses on dendrites (Megías et al., 2001; Bleckert et al., 2013; Iascone et al., 2020), sometimes as near as on the same spine (Chen et al., 2012), facilitates synaptic input integration, dynamic calcium regulation, synaptic crosstalk, and coregulation.

Synaptic plasticity describes the ability of synapses to adapt their relative strength based on the overall level of activity or specific activity patterns, often by dynamic regulation of receptor-synaptic scaffold interactions or through trafficking. During development, it is heavily involved in dendritic growth, synaptogenesis, and the formation of neural circuits (reviewed in Akgül and McBain, 2016; Ismail et al., 2017; Jenks et al., 2021). In mature neurons, synaptic plasticity is responsible for synapse remodeling during experience. Genetic mutations or pathology leading to altered excitatory or inhibitory neurotransmission or impaired synaptogenesis typically result in deficits in synaptic plasticity, a common feature in neurodevelopmental and neurological disorders (Rudolph and Möhler, 2014; Mele et al., 2019), including autism (Hansel, 2019; Sohal and Rubenstein, 2019), down syndrome (Galdzicki et al., 2001; Schulz et al.

The human brain, with its intricate networks of neurons, has long been a subject of fascination and mystery. Concurrently, the cosmos, with its vastness and complexity, has intrigued scientists and philosophers for centuries.

Recent research has begun to explore the possibility that the brain and the cosmos might be connected on a quantum scale. This article will delve into the research paper titled “Quantum transport in fractal networks” and discuss its implications for our understanding of the relationship between the brain and the cosmos.

My latest Opinion piece:


I possibly cheated on my wife once. Alone in a room, a young woman reached out her hands and seductively groped mine, inviting me to engage and embrace her. I went with it.

Twenty seconds later, I pulled back and ripped off my virtual reality gear. Around me, dozens of tech conference goers were waiting in line to try the same computer program an exhibitor was hosting. I warned colleagues in line this was no game. It created real emotions and challenged norms of partnership and sexuality. But does it really? And who benefits from this?

Around the world, a minor sexual revolution is occurring. It’s not so much about people stepping outside their moral boundaries as much as it is about new technology. Virtual reality haptic suits, sexbots, and even implanted sexual devices—some controlled from around the world by strangers—are increasingly becoming used. Often called digisexuality, some people—especially those who find it awkward to fit into traditional sexual roles—are finding newfound relationships and more meaningful sex.

As with much new technology, problems abound. Psychologists warns that technology—especially interactive tech—is making humans more distant to the real world. Naysayers of the burgeoning techno-sex industry say this type of intimacy is not the real thing, and that it’s little different than a Pavlovian trick. But studies show the brain barely knows the difference from arousal via pornography versus being sexually active with a real person. If we take that one step further and engage with people in immersive virtual reality, our brain appears to know even less of the difference.

Can we connect human brains together? What are the limits of what we can do with our brain? Is BrainNet our future?
In science fiction movies, scientists’ brains are downloaded into computers and criminal brains are connected to the Internet. Interesting, but how does it work in real life?
Original title: The greedy brain.
Scientific journalist Rob van Hattum wondered what information we can truly get from our brain and came across an extraordinary scientific experience.
An experiment where the brains of two rats were directly connected: one rat was in the United States and the other rat was in Brazil. They could influence the brain of the other directly. Miguel Nicolelis is the Brazilian neurologist who conducted this experiment. In his book ‘Beyond Boundaries’ he describes his special experiences in detail and predicts that it should be possible to create a kind of BrainNet.
For Backlight, Rob van Hattum went to Sao Paulo and also visited all Dutch neuroscientists, looking for what the future holds for our brain. He connected his own brain to computers and let it completely be scanned, searching for the limits of reading out the brain.
Originally broadcasted by VPRO in 2014.
© VPRO Backlight July 2014

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Credits:
Director: Rob van Hattum.
English, French and Spanish subtitles: Ericsson.
French and Spanish subtitles are co-funded by European Union.

More than 60 scientists work to convert research into practical applications too.

The government of China has provided funding to set up a leading laboratory to study brain-machine interfaces, much like Elon Musk’s Neuralink has been working on. The recently inaugurated Sixth Haihe Laboratory in the northeast port city of Tianjin to “drive innovation and create new areas for economic growth”, the South China Morning Post.


Chinese lab to work on brain-machine interfaces

Apart from Neuralink, research institutes in the U.S., such as the University of California, Berkeley, and the Massachusetts Institute of Technology, have led the development of technology in brain-machine interface for many years.

As it has done, with technologies such as hypersonic missiles, China is looking to break U.S. dominance by building a solid research foundation for developing intellectual capability in the area of brain-machine interface as well.

Researchers in New York developed a virtual reality maze for mice in an attempt to demystify a question that’s been plaguing neuroscientists for decades: How are long-term memories stored?

What they found surprised them. After forming in the hippocampus, a curved structure that lies deep within the brain, the mice’s memories were actually rooted through what’s called the anterior thalamus, an area of the brain that scientists haven’t typically associated with memory processing at all.

“The thalamus being a clear winner here was very interesting for us, and unexpected,” said Priya Rajasethupathy, an associate professor at Rockefeller University and one of the coauthors of a peer-reviewed study published in the journal Cell this week. The thalamus “has often been thought of as a sensory relay, not very cognitive, not very important in memory.”