Mind Aglow: Scientists Watch Thoughts Form in the Brain

[anant_s]

New technology shows real-time communication among neurons that promises to reveal brain activity in unprecedented detail

• By Sara Chodosh on August 24, 2016

In a mouse brain, cell-based detectors called CNiFERs change their fluorescence when neurons release dopamine. Credit: Slesinger & Kleinfeld Labs
When a single neuron fires, it is an isolated chemical blip. When many fire together, they form a thought. How the brain bridges the gap between these two tiers of neural activity remains a great mystery, but a new kind of technology is edging us closer to solving it.

The glowing splash of cyan in the photo above comes from a type of biosensor that can detect the release of very small amounts of neurotransmitters, the signaling molecules that brain cells use to communicate. These sensors, called CNiFERs (pronounced “sniffers”), for cell-based neurotransmitter fluorescent engineered reporters, are enabling scientists to examine the brain in action and up close.

This newfound ability, developed as part of the White House BRAIN Initiative, could further our understanding of how brain function arises from the complex interplay of individual neurons, including how complex behaviors like addiction develop. Neuroscientist Paul Slesinger at Icahn School of Medicine at Mount Sinai, one of the senior researchers who spearheaded this research, presented the sensors Monday at the American Chemical Society’s 252nd National Meeting & Exposition.

Current technologies have proved either too broad or too specific to track how tiny amounts of neurotransmitters in and around many cells might contribute to the transmission of a thought. Scientists have used functional magnetic resonance imaging to look at blood flow as a surrogate for brain activity over fairly long periods of time or have employed tracers to follow the release of a particular neurotransmitter from a small set of neurons for a few seconds. But CNiFERs make for a happy medium; they allow researchers to monitor multiple neurotransmitters in many cells over significant periods of time.

When a CNiFER comes in contact with the neurotransmitter it is designed to detect, it fluoresces. Using a tiny sensor implanted in the brain, scientists can then measure how much light the CNiFER emits, and from that infer the amount of neurotransmitter present. Because they comprise several interlocking parts, CNiFERs are highly versatile, forming a “plug-and-play system,” Slesinger says. Different sections of the sensor can be swapped out to detect individual neurotransmitters. Prior technology had trouble distinguishing between similar molecules, such as dopamine and norepinephrine, but CNiFERs do not.

The sensors are being tested in animals to examine particular brain processes. Slesinger and his colleagues have used CNiFERs to look more closely at a classic psychological phenomenon: Pavlovian conditioning. Just as Pavlov trained his dog to salivate at the sound of a dinner bell, Slesinger and his team trained mice to associate an audio cue with a food reward. At the beginning of the experiment, the mice experienced a release of dopamine and norepinephrine when they received a sugar cube. As the animals became conditioned to associate the audio cue with the sugar, however, the neurotransmitter release occurred earlier, eventually coinciding with the audio cue rather than the actual reward.

Mouse studies might be a far cry from the kind of human impact that neuroscience ultimately strives toward—better treatments for Parkinson’s patients or concussion sufferers, for example—but this is where it all begins. Slesinger is especially interested in using CNiFERs to study addiction. A more nuanced understanding of how addiction develops in mouse brains could help identify novel targets to combat addiction in people.

http://www.scientificamerican.com/article/mind-aglow-scientists-watch-thoughts-form-in-the-brain/

@Levina @thesolar65 @Skull and Bones @WAJsal @gslv

 

[Levina]

Cool!
This should provide us with a better understanding of brain circuitry.
Isnt it interesting as to how scientists can now watch a thought / an addiction form inside our head? Though i'm sure scientists would be banging their head if they were to ever perform the same tests on say...ummmm @Arsalan @Roybot @Star Wars . The reason is not hard to guess.

Jokes apart, i think CNiFERs can only show whether the total amount of a molecule such as dopamine is increasing or decreasing, but they do not reveal which neuron is sending or receiving the signal, making it hard to map tangled brain circuits. If ever scientists are successful in finding the position of the neurons which produce these molecules, that will be a breakthrough in de-addiction related researches.
Finally its all about dopamine,which is nothing but neurochemical reward. Something that motivates us to do things again and again. But the problem arises when your neurons are desensitized after you feed your brain with excessive dopamine producing simulator. Then you become an addict.
What scares me is the fact that females get addicted to things more easily than guys, some of it is related to your genes too.
Btw did you know that when these scientists performed those experiments on mice, they cut open a part of their skull and replaced it with a transparent plastic? Yikes! one reason i hate to imagine myself as a lab rat. I'm against animal testing.

 

[Arsalan]

Cool!
This should provide us with a better understanding of brain circuitry.
Isnt it interesting as to how scientists can now watch a thought / an addiction form inside our head? Though i'm sure scientists would be banging their head if they were to ever perform the same tests on say...ummmm @Arsalan @Roybot @Star Wars . The reason is not hard to guess.

I see some smoke coming out of those equipment they have attached ....... hmmmmmmmm Too much to handle

 

[Nilgiri]

I see some smoke coming out of those equipment they have attached ....... hmmmmmmmm Too much to handle

You guys and gals should have this treatment together to see the results for everyone:

 

[Levina]

You guys and gals should have this treatment together to see the results for everyone

Why don't you try it as well?

I see some smoke coming out of those equipment they have attached ....... hmmmmmmmm Too much to handle

Btw did you guyz read the article?

I mean imagine what happens if someone tracks your imagination, can read your thoughts?

 

[Nilgiri]

Why don't you try it as well?

Sure I'll just have the buttons to press and not the thing on my head

I mean imagine what happens if someone tracks your imagination, can read your thoughts?

For that more reference has to be done....right now its like a caveman looking at the night sky.....what are those pretty things up there? what do they mean? etc...

 

[Levina]

Sure I'll just have the buttons to press and not the thing on my head

I will ensure you get tested before me.

For that more reference has to be done....right now its like a caveman looking at the night sky.....what are those pretty things up there? what do they mean? etc

Obviously!
But say 30years down the lane, when we are still alive and our brains functional, scientists must have actually stumbled upon something which helps them read one's thoughts.
If I ever come under their scanner, scientists will be shocked at the amount of violence inside my head.

This comes close >>> http://www.livescience.com/53535-computer-reads-thoughts-instantaneously.html

 

[Nilgiri]

If I ever come under their scanner, scientists will be shocked at the amount of violence inside my head.

Must have been all the tom and jerry cartoons.

 

[Levina]

Must have been all the tom and jerry cartoons.

Hehe

I was a terminator fan too.

 

[Arsalan]

Why don't you try it as well?


Btw did you guyz read the article?

I mean imagine what happens if someone tracks your imagination, can read your thoughts?

Yeah i did read the article. As for reading those thoughts, i would call that intrusion and a violation of basic human rights but i wonder if I can read those of others..... now this is getting interesting AND there are quite a few people who came to my mind when i wrote these words!

But seriously, just like anything and everything, this too will be put to good use in good hands and will be a maniac in bad hands. To imagine this actually happening is interesting as well as frightening at the same time.

 

[WAJsal]

New technology shows real-time communication among neurons that promises to reveal brain activity in unprecedented detail

• By Sara Chodosh on August 24, 2016

In a mouse brain, cell-based detectors called CNiFERs change their fluorescence when neurons release dopamine. Credit: Slesinger & Kleinfeld Labs
When a single neuron fires, it is an isolated chemical blip. When many fire together, they form a thought. How the brain bridges the gap between these two tiers of neural activity remains a great mystery, but a new kind of technology is edging us closer to solving it.

The glowing splash of cyan in the photo above comes from a type of biosensor that can detect the release of very small amounts of neurotransmitters, the signaling molecules that brain cells use to communicate. These sensors, called CNiFERs (pronounced “sniffers”), for cell-based neurotransmitter fluorescent engineered reporters, are enabling scientists to examine the brain in action and up close.

This newfound ability, developed as part of the White House BRAIN Initiative, could further our understanding of how brain function arises from the complex interplay of individual neurons, including how complex behaviors like addiction develop. Neuroscientist Paul Slesinger at Icahn School of Medicine at Mount Sinai, one of the senior researchers who spearheaded this research, presented the sensors Monday at the American Chemical Society’s 252nd National Meeting & Exposition.

Current technologies have proved either too broad or too specific to track how tiny amounts of neurotransmitters in and around many cells might contribute to the transmission of a thought. Scientists have used functional magnetic resonance imaging to look at blood flow as a surrogate for brain activity over fairly long periods of time or have employed tracers to follow the release of a particular neurotransmitter from a small set of neurons for a few seconds. But CNiFERs make for a happy medium; they allow researchers to monitor multiple neurotransmitters in many cells over significant periods of time.

When a CNiFER comes in contact with the neurotransmitter it is designed to detect, it fluoresces. Using a tiny sensor implanted in the brain, scientists can then measure how much light the CNiFER emits, and from that infer the amount of neurotransmitter present. Because they comprise several interlocking parts, CNiFERs are highly versatile, forming a “plug-and-play system,” Slesinger says. Different sections of the sensor can be swapped out to detect individual neurotransmitters. Prior technology had trouble distinguishing between similar molecules, such as dopamine and norepinephrine, but CNiFERs do not.

The sensors are being tested in animals to examine particular brain processes. Slesinger and his colleagues have used CNiFERs to look more closely at a classic psychological phenomenon: Pavlovian conditioning. Just as Pavlov trained his dog to salivate at the sound of a dinner bell, Slesinger and his team trained mice to associate an audio cue with a food reward. At the beginning of the experiment, the mice experienced a release of dopamine and norepinephrine when they received a sugar cube. As the animals became conditioned to associate the audio cue with the sugar, however, the neurotransmitter release occurred earlier, eventually coinciding with the audio cue rather than the actual reward.

Mouse studies might be a far cry from the kind of human impact that neuroscience ultimately strives toward—better treatments for Parkinson’s patients or concussion sufferers, for example—but this is where it all begins. Slesinger is especially interested in using CNiFERs to study addiction. A more nuanced understanding of how addiction develops in mouse brains could help identify novel targets to combat addiction in people.

http://www.scientificamerican.com/article/mind-aglow-scientists-watch-thoughts-form-in-the-brain/

@Levina @thesolar65 @Skull and Bones @WAJsal @gslv

Whats next, creating thoughts?

 

[Arsalan]

Why don't you try it as well?


Btw did you guyz read the article?

I mean imagine what happens if someone tracks your imagination, can read your thoughts?

Yeah i did read the article. As for reading those thoughts, i would call that intrusion and a violation of basic human rights but i wonder if I can read those of others..... now this is getting interesting AND there are quite a few people who came to my mind when i wrote these words!

But seriously, just like anything and everything, this too will be put to good use in good hands and will be a maniac in bad hands. To imagine this actually happening is interesting as well as frightening at the same time.

Whats next, creating thoughts?

Good point!!
I mean, if you can electronically track and read them sure one can write them as well electronically!! Ok seriously, this is getting interesting

 

[thesolar65]

This.......is Dangerous....very very Dangerous!!