stop fuckin body shaming

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Kiana Khansmith

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@5-hydroxytryptamin-blog
stop fuckin body shaming
This is for all of you who are disabled/mentally ill who can’t work or are currently taking a break from education
- you deserve a break sometime and shouldn’t feel bad about it
- you’re not a failure
- you’re not weak or pathetic
- you don’t have to meet neurotypical standards
- your worth is not based on your productivity
- not working or being in education does NOT make you lazy
- you’re valuable and have worth
True dat
Have you ever been in love? Horrible isn’t it? It makes you so vulnerable. It opens your chest and it opens up your heart and it means that someone can get inside you and mess you up.
Neil Gaiman, The Kindly Ones (via thelovejournals)
hell yeah
Don’t forget to submit your entry for our Neuroscience Junior Investigator Award before January 31st. Winners will receive up to $1000 in free-of-charge reagents. Enter here: https://www.surveymonkey.com/r/X2VC9H3
BEAUTY
Do you even lift (heavy emotions)? .
Neurons
Unipolar neuron: only one protoplasmic process (neurite) extends from the cell body
Bipolar neuron: neuron with two extensions (one axon and one dendrite)
Bipolar cells are specialized sensory neurons for the transmission of special senses
Sensory systems: smell, sight, taste, hearing and vestibular functions
Multipolar neuron: a single axon and many dendrites (and dendritic branches), allowing for the integration of a great deal of information from other neuron
Common in the central nervous system
Pyramidal neuron: type of multipolar neuron
Found in areas of the brain including the cerebral cortex, the hippocampus, and the amygdala
beauty
Please help to stop this and sign. Link in bio. #rodentslifematter #helpanimals #animalshelp #savetheanimals #allanimalsareequal https://www.instagram.com/p/BsxxJl3HYz7/?utm_source=ig_tumblr_share&igshid=1lyeodluqxm2a
Slutshaming
A guy can have sex with hundreds of girls and get praised. But if a girl have sex with hundreds of guys she gets called slut and whore. There’s nothing wrong with having sex, if you want to have it then go ahead.
I don’t believe in slutshaming, fuck whoever you want, whenever you want and how many you want. If you want to save yourself until you’re married then do it, if you want to do it with someone you love then do it, if you just want to have sex without emotions then do it.
It’s your body do whatever you want.
People generally seem to understand that improving physical fitness requires difficult, consistent work. But with mental health, as a society, we’re still desperately searching for instant quick fixes and any way possible to avoid the emotions we need to learn how to handle. You would never tell somebody that exercise doesn’t work because you tried it and it made you sore but I hear comments like that all of the time when I mention mental health skills to people. The brain is part of your body, it changes in the same way any other part of your body changes. https://www.instagram.com/p/BnOPLKNgkvw/?utm_source=ig_tumblr_share&igshid=ymdaf76grvzf
by @eventyrhesten (Instagram)
I Love Horses
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Find them here :)
Stunning
Mood
(Image caption: A “brainbow” of cerebral cortex neurons labeled with different colors. Credit: Lichtman Lab/Harvard University)
Nature, Meet Nurture
Nature and nurture is a convenient jingle of words, for it separates under two distinct heads the innumerable elements of which personality is composed. Nature is all that a man brings with himself into the world; nurture is every influence from without that affects him after his birth.” – Francis Galton, cousin of Charles Darwin, 1874.
Is it nature or nurture that ultimately shapes a human? Are actions and behaviors a result of genes or environment?
Variations of these questions have been explored by countless philosophers and scientists across millennia.
Yet, as biologists continue to better understand the mechanisms that underlie brain function, it is increasingly apparent that this long-debated dichotomy may be no dichotomy at all.
In a study published in Nature Neuroscience on Jan. 21, neuroscientists and systems biologists from Harvard Medical School reveal just how inexorably interwoven nature and nurture are.
Using novel technologies developed at HMS, the team looked at how a single sensory experience affects gene expression in the brain by analyzing more than 114,000 individual cells in the mouse visual cortex before and after exposure to light.
Their findings revealed a dramatic and diverse landscape of gene expression changes across all cell types, involving 611 different genes, many linked to neural connectivity and the brain’s ability to rewire itself to learn and adapt.
The results offer insights into how bursts of neuronal activity that last only milliseconds trigger lasting changes in the brain, and open new fields of exploration for efforts to understand how the brain works.
“What we found is, in a sense, amazing. In response to visual stimulation, virtually every cell in the visual cortex is responding in a different way,” said co-senior author Michael Greenberg, the Nathan Marsh Pusey Professor of Neurobiology and chair of the Department of Neurobiology at HMS.
“This in essence addresses the long-asked question about nature and nurture: Is it genes or environment? It’s both, and this is how they come together,” he said.
One out of many
Neuroscientists have known that stimuli—sensory experiences such as touch or sound, metabolic changes, injury and other environmental experiences—can trigger the activation of genetic programs within the brain.
Composed of a vast array of different cells, the brain depends on a complex orchestra of cellular functions to carry out its tasks. Scientists have long sought to understand how individual cells respond to various stimuli. However, due to technological limitations, previous genetic studies largely focused on mixed populations of cells, obscuring critical nuances in cellular behavior.
To build a more comprehensive picture, Greenberg teamed with co-corresponding author Bernardo Sabatini, the Alice and Rodman W. Moorhead III Professor of Neurobiology at HMS, and Allon Klein, assistant professor of systems biology at HMS.
Spearheaded by co-lead authors Sinisa Hrvatin, a postdoctoral fellow in the Greenberg lab, Daniel Hochbaum, a postdoctoral fellow in the Sabatini lab and M. Aurel Nagy, an MD-PhD student in the Greenberg lab, the researchers first housed mice in complete darkness to quiet the visual cortex, the area of the brain that controls vision.
They then exposed the mice to light and studied how it affected genes within the brain. Using technology developed by the Klein lab known as inDrops, they tracked which genes got turned on or off in tens of thousands of individual cells before and after light exposure.
The team found significant changes in gene expression after light exposure in all cell types in the visual cortex—both neurons and, unexpectedly, non-neuronal cells such as astrocytes, macrophages and muscle cells that line blood vessels in the brain.
Roughly 50 to 70 percent of excitatory neurons, for example, exhibited changes regardless of their location or function. Remarkably, the authors said, a large proportion of non-neuronal cells—almost half of all astrocytes, for example—also exhibited changes.
The team identified thousands of genes with altered expression patterns after light exposure, and 611 genes that had at least two-fold increases or decreases.
Many of these genes have been previously linked to structural remodeling in the brain, suggesting that virtually the entire visual cortex, including the vasculature and muscle cell types, may undergo genetically controlled rewiring in response to a sensory experience.
There has been some controversy among neuroscientists over whether gene expression could functionally control plasticity or connectivity between neurons.
“I think our study strongly suggests that this is the case, and that each cell has a unique genetic program that’s tailored to the function of a given cell within a neural circuit,” Greenberg said.
Goldmine of questions
These findings open a wide range of avenues for further study, the authors said. For example, how genetic programs affect the function of specific cell types, how they vary early or later in life and how dysfunction in these programs might contribute to disease, all of which could help scientists learn more about the fundamental workings of the brain.
“Experience and environmental stimuli appear to almost constantly affect gene expression and function throughout the brain. This may help us to understand how processes such as learning and memory formation, which require long-term changes in the brain, arise from the short bursts of electrical activity through which neurons signal to each other,” Greenberg said.
One especially interesting area of inquiry, according to Greenberg, includes the regulatory elements that control the expression of genes in response to sensory experience. In a paper published earlier this year in Molecular Cell, he and his team explored the activity of the FOS/JUN protein complex, which is expressed across many different cell types in the brain but appears to regulate unique programs in each different cell type.
Identifying the regulatory elements that control gene expression is critical because they may account for differences in brain function from one human to another, and may also underlie disorders such as autism, schizophrenia and bipolar disease, the researchers said.
“We’re sitting on a goldmine of questions that can help us better understand how the brain works,” Greenberg said. “And there is a whole field of exploration waiting to be tapped.”
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