Not today Justin
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Mike Driver
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@hmbird47
That Feeling When Ni Kicks In:
Very accurate.
Each Type In The Loop
ENTP: Ne-Fe
Ne generates tons of potential disasters and Fe cries over them. If this loop is seen amidst depression, bipolar disorder, or anxiety, it can spiral extremely quickly. If depressed, the ENTP will be socially anxious (and may avoid people, which would make their situation even worse after a while,) extremely emotional, impulsive, and unusually negative.Â
INTP: Ti-Si
The INTP in the loop will become extremely socially withdrawn and nostalgic. They will live in their heads and/ or in the past and will completely disregard the feelings of themselves and others.Â
ENTJ: Te-Se
Will become a complete control freak, tear people down, and make impulsive decisions. They may oppress or intimidate people just to get a reaction and may become abusive. May also nitpick every single detail and overlook the big picture until something becomes too messed up to ignore.
INTJ: Ni-Fi
The INTJ will bottle up their feelings and get to the root of every single one. They may develop a mindset of total superiority and become seclusive. They will display little patience when people cannot magically guess their feelings and needs and may become angry.
ENFP: Ne-Te
The ENFP will become immensely stressed and try to clean up their lives here and now. May also attempt to meddle in other peoplesâ lives. Their actions will become sporadic and then anxiety will accumulate due to overuse of undeveloped Te.Â
INFP: Fi-Si
The INFP will make any excuses they can to not socialize and instead live in the past. Their reclusion can give them time alone which may help, but may also launch a bout of depression due to bottled up feelings and a strong tendency to relive better times in their life.
ENFJ: Fe-Se
ENFJs have the best of intentions when caught in the loop, but the end up giving a lot of advice that wasnât asked for and will then become sad, confused, and possibly angry when people try to spend time away from them. If alone they will probably try to blame others for their situation or will pick themselves apart and dwell on each flaw.
INFJ: Ni-Ti
The INFJ in the loop will spend a lot of time jumping to conclusions about how things work and making assumptions without enough evidence. This may be predicting what other people need or how an event will play out but it is not reliable. They may also become extremely cold and seclusive but lonely at the same time. If people do not approach them they may become bitter.
ESTP: Se-Fe
The loop affects the ESTP by making them impulsive, carefree, and needy for affection. They may become manipulative in order to get a rush or obtain something to distract them from their situation. Drug use is a risk if the ESTPâs situation is particularly bad.Â
ISTP: Ti-Ni
The ISTP will go out of their way to break all rules and purposely mess up peopleâs lives. They may become destructive and will also develop a sense of superiority. They will think they are above all emotional sources of stress and thusly neglect their feelings and the feelings of others.Â
ESTJ: Te-Ne
Constantly thinking of things to fix and constantly making plans to fix them, the ESTJ will become a micromanaging control freak that will not stop unless stopped by someone else. They will become overwhelmed by their foresight of all the things that need doing and their overactive Te will stress them out.
ISTJ: Si-Fi
Similar to the INFP, the ISTJ will become reclusive and nostalgic. Their emotions will catch them by surprise and will leave them overanalyzing everything as well as unhealthily dealing with feelings. They will ignore others who reach out to them and may develop a sense of superiority.
ESFP: Se-Te
Their usual debonair attitude will be conflicted by their overactive yet underdeveloped Te. They will begin to ignore their feelings in pursuit of something that can really get them going.Â
ISFP: Fi-Ni
The ISFP will become over trust their tertiary Ni and develop a sense of superiority and self-improvement that hasnât actually taken place yet. They will use Ni to analyze their emotions as well as the emotions of the people around them and will treat people as if they know less than the ISFP.Â
ESFJ: Fe-Ne
The ESFJ will probably overcommit to events and occasions and then forget about them due to tertiary Ne. They may neglect certain friends in the pursuit of others and wont remember to apologize. They may also become overly emotional and destructive in their will to improve others.Â
ISFJ: Si-Ti
The ISFJ will become nostalgic and analytical of past events. The rationalizing of their emotions can lead to dangerous confidence and they may engage in unhealthy relations. They will bring people close to them and push them away just as quickly.Â
Somewhat prompted by an ask from perceeweasleyÂ
El Profesor (INTJ) - La Casa de Papel
Ni (introverted Intuition)
Te (extroverted Thinking)
Fi (introverted Feeling)
Se (extroverted Sensing)
The Mastermind. El Profesor is always one step ahead. Improvisations terribly bothers him, this way he needs to have everything under control and to predict every single movement. He is a natural planner, having trouble dealing with the present and non-predicted situations.
El Profesor has a logical, strategic mind. He can easily expose and articulate his ideas. He had to find, convince and explain everything to those who would execute his plan. The big project involves dealing with people who has nothing to lose and eventually could die or be severally hurt. He knows the temper of his chosen ones, he manipulates them â like when he conversed with Tokyo, convincing her to trust him doesnât matter what. His social skills arenât well developed, but tries his best.
Introverted feeling is associated with inner values and principles. The plan doesnât involve hurting or killing anyone, and he is also against interpersonal relations. Also, INTJs can be extremely loyal and El Profesor shows such strong loyalty to his fatherâs memory and plan.
An Inferior extroverted Sensing can be dangerous sometimes. Once he perceived that one of his plans had failed, El Profesor is forced to improvise a solution, he entered in a Ni-Fi loop that lead him to attempt against the life of an old woman. His perception of external world isnât the best. He can accidentally hurt himself and he wasnât that great at cleaning fingerprints and dealing with the crazy Russian.
Heavy drinking in teens causes lasting changes in emotional center of brain
Binge drinking in adolescence has been shown to have lasting effects on the wiring of the brain and is associated with increased risk for psychological problems and alcohol use disorder later in life.
Now, researchers at the University of Illinois at Chicago Center for Alcohol Research in Epigenetics have shown that some of these lasting changes are the result of epigenetic changes that alter the expression of a protein crucial for the formation and maintenance of neural connections in the amygdala â the part of the brain involved in emotion, fear and anxiety. Their results, which are based on the analysis of postmortem human brain tissue, are published in the journal Translational Psychiatry.
Epigenetics refers to chemical changes to DNA, RNA or specific proteins associated with chromosomes that change the activity of genes without changing the genes themselves. Epigenetic modifications are involved in the normal development of the brain, but they can be influenced by environmental or even social factors, such as alcohol and stress. These kinds of epigenetic alterations have been linked to changes in behavior and disease.
The researchers looked at postmortem human amygdala tissue obtained from the New South Wales Brain Tissue Resource Center in Sydney, Australia. The amygdala is the part of the brain involved in emotional regulation. The specimens were from the brains of 11 individuals who started drinking heavily before the age of 21 or early-onset drinkers; 11 individuals who started drinking seriously after the age of 21, known as late-onset drinkers; and 22 individuals with no history of alcohol use disorder. The average age of death of the individuals from whom the samples were taken was 58 years old for those without alcohol use disorder; 55 years old for early-onset drinkers; and 59 for late-onset drinkers.
Amygdalae of individuals who were early-onset drinkers had about 30 percent more of a molecule called BDNF-AS, a large non-coding RNA. Usually, RNA is involved in the production of proteins from DNA, but this one is not. BDNF-AS regulates a gene that produces a protein called BDNF. This protein is a growth factor and is crucial for the normal formation and maintenance of synapses throughout the brain. When there is more BDNF-AS, there is less BDNF. The brain tissue of early-onset drinkers had 30 percent to 40 percent less BDNF compared with brain tissue from people with no history of alcohol use disorder. This reduction in BDNF was not seen in brain samples from late-onset drinkers or from people with no alcohol use disorder.
Subhash Pandey, professor of psychiatry and director of the UIC Center for Alcohol Research in Epigenetics, and corresponding author on the paper, believes that epigenetic changes to BDNF-AS are the reason BDNF is lower in the amygdalae from people who started drinking early in life. In the amygdala from people who started drinking after age 21, there were no such changes.
âBDNF is needed for normal development in the brain and for connections to form between neurons,â said Pandey, who is also a senior research career scientist at Jesse Brown VA Medical Center, Chicago. âIf levels are lowered due to alcohol exposure, then the brain will not develop normally, and we see that in these brain samples where there are abnormalities in another synaptic gene, Arc, possibly making abnormal connections between neurons.â
Pandey and his colleagues found that the increase in BDNF-AS in the early-onset drinkers is caused by decreased methylation of BDNF-AS. Methylation is a type of epigenetic change where a molecule containing a methyl group is added to another molecule and results in a change in genetic expression. The decreased methylation of BDNF-AS is believed to be caused by early-onset drinking and appears to be a long-lasting change.
âThe epigenetic changes we saw in the amygdala of early-onset drinkers can alter the normal function of the amygdala, which helps regulate our emotions, and may cause individuals to be more susceptible for things like anxiety, which we have shown in other studies, or the development and maintenance of alcohol use disorder later in life,â Pandey said.
(Image caption: Schematic representation of the formation of gephyrin-artemisinin complex. Credit: Vikram Kasaragod, Rudolf-Virchow-Zentrum)
New Findings About Anti-Malaria Drug
Researchers at the Rudolf Virchow Center of the University of WĂźrzburg have unveiled the molecular effectiveness of artemisinins. The findings could lead to drugs for diseases such as Alzheimerâs, schizophrenia and epilepsy.
Artemisinin is derived from the leaves and flowers of the annual mugwort (Artemisia annua) and has been used in traditional Chinese medicine for centuries. The effectiveness was investigated by the Chinese researcher Tu Youyou. Her research was 2015 rewarded with the Nobel Prize. Artemisinin and its semi-synthetic derivatives â collectively known as artemisinins â are used to treat the tropical infectious disease malaria. In addition, these molecules also influence multiple cellular processes in humans. For example, artemisinins are able to activate the immune system against several types of cancer or to regulate the differentiation of pancreatic Ta cells, which could potentially be useful in the therapy of diabetes.
Molecular Mechanisms so far unknown
âAlthough this clinically-approved drug class is well established and has been used in some extent for centuries, it was unclear which molecular mechanisms underlie the corresponding cellular activities, such as target protein rfhumecognition and modulation,â explains Dr. Vikram Kasaragod. The postdoctoral fellow in the research group of Professor Hermann Schindelin at the Rudolf Virchow Center is the first author of this article and ensures with this research work a significant gain in knowledge. The study was published in the journal Neuron.
Comprehensive model for the regulation of inhibitory neurotransmission developed
The structural biologist was the first to solve the crystal structures of two different artemisinin derivatives â artesunate and artemether â in a complex with gephyrin. By binding to inhibitory glycine and GABAA receptors, gephyrin acts as a central scaffold protein of inhibitory postsynapses in the mammalian central nervous system. Gephyrin has only recently been identified as an artemisinin target protein. The results clearly demonstrate how artemisinins target the universal receptor binding pocket in gephyrin and compete with the inhibitory neurotransmitter receptors for an overlapping binding site. These new findings could thus also serve as an effective tool to understand the physiology of the human brain.
According to Kasaragod, the crystal structures form, together with biochemical, electrophysiological and in vivo data, a comprehensive model of the regulation of inhibitory neurotransmission by artemisinine. According to him, this model clearly describes the interactions between proteins and drugs.
Important step for the development of drugs
âOur data not only provide a solid foundation for understanding how artemisinins are recognized by a target molecule, but will also help researchers to develop and optimize these agents into highly specific modulators of gephyrin. These modulators may play an important role in the treatment of neurological diseases such as Alzheimerâs disease, schizophrenia and epilepsy,â says Schindelin, the lead investigator.
How does helping people affect your brain? Study shows neurobiological effects of providing support to others
Providing âtargetedâ social support to other people in need activates regions of the brain involved in parental care- which may help researchers understand the positive health effects of social ties, reports a study in Psychosomatic Medicine: Journal of Biobehavioral Medicine, the official journal of the American Psychosomatic Society. The journal is published in the Lippincott Portfolio by Wolters Kluwer.
By comparison, providing âuntargetedâ support such as giving to charity does not have the same neurobiological effects, according to the new research by Tristen K. Inagaki, PhD, and Lauren P. Ross, BA, of University of Pittsburgh. âOur results highlight the unique benefits of giving targeted support and elucidate neural pathways by which giving support may lead to health,â the researchers write.
Study May Show âNeural Pathwayâ By Which Providing Support Improves Health
The researchers performed a pair of experiments to evaluate brain responses to providing different kinds of social support. In the first study, 45 volunteers performed a âgiving supportâ task where they had a chance to win rewards for someone close to them who needed money (targeted support), for charity (untargeted support), or for themselves. As predicted, participants felt more socially connected, and felt that their support was more effective, when giving targeted social support.
The subjects then underwent an emotional ratings task including functional MRI scanning to assess activation of specific brain areas when giving social support. Providing support, regardless of who received the support, was linked to increased activation of the ventral striatum (VS) and septal area (SA) - regions previously linked to parental care behaviors in animals. However, only higher activation of the SA when people gave targeted support was associated with lower activity in a brain structure called the amygdala - sometimes linked to fear and stress responses. Â
In the second study, 382 participants provided information on their behavior in giving support (prosocial behavior) and underwent a different emotional ratings task with functional MRI scanning. Once again, those who reported giving more targeted support to others also showed reduced activity in the amygdala. In both studies, giving untargeted support (such as giving to charity) was unrelated to amygdala activity.
âHumans thrive off social connections and benefit when they act in the service of othersâ well-being,â according to the authors. A previous study by Dr. Inagaki, also published in Psychosomatic Medicine, found that giving social support has positive effects on brain areas involved in stress and reward responses. That study suggested that providing support - not just receiving it - may be an important contributor to the physical and mental health benefits of social support.
The new study adds further evidence that giving targeted support may be uniquely beneficial. Both targeted and untargeted support are linked to increased SA activity, supporting the âwarm glowâ theory of providing support: we help others, directly or indirectly, simply because it âfeels good.â Â
But the link between increased SA activation and decreased amygdala activity âsuggests a neural pathway by which giving support ultimately influence health that is specific to targeted forms of support-giving, such as giving to specific people we know are in need,â Dr. Inagaki and Ms. Ross write. The authors note that their study cannot show a cause-and-effect of providing support on activation of the SA or amygdala. They also point out that providing targeted social support does not always lead to improved health - for example, prolonged caregiving for an ill family member can be detrimental to health. Â
The study adds to previous evidence that providing social support to others âmay be an overlooked contributor to the well-known link between social ties and health,â Dr. Inagaki and Ms. Ross write. They conclude: âGiving targeted support to an identifiable individual in need is uniquely associated with reduced amygdala activity thereby contributing to understanding of how and when giving support may lead to health.â
Scientists find fear, courage switches in brain
Researchers at the Stanford University School of Medicine have identified two adjacent clusters of nerve cells in the brains of mice whose activity level upon sighting a visual threat spells the difference between a timid response and a bold or even fierce one.
Located smack-dab in the middle of the brain, these clusters, or nuclei, each send signals to a different area of the brain, igniting opposite behaviors in the face of a visual threat. By selectively altering the activation levels of the two nuclei, the investigators could dispose the mice to freeze or duck into a hiding space, or to aggressively stand their ground, when approached by a simulated predator.
Peopleâs brains probably possess equivalent circuitry, said Andrew Huberman, PhD, associate professor of neurobiology and of ophthalmology. So, finding ways to noninvasively shift the balance between the signaling strengths of the two nuclei in advance of, or in the midst of, situations that people perceive as threatening may help people with excessive anxiety, phobias or post-traumatic stress disorder lead more normal lives.
âThis opens the door to future work on how to shift us from paralysis and fear to being able to confront challenges in ways that make our lives better,â said Huberman, the senior author of a paper describing the experimental results. It was published online May 2 in Nature. Graduate student Lindsey Salay is the lead author.
Perilous life of a mouse
There are plenty of real threats in a mouseâs world, and the rodents have evolved to deal with those threats as best they can. For example, theyâre innately afraid of aerial predators, such as a hawk or owl swooping down on them. When a mouse in an open field perceives a raptor overhead, it must make a split-second decision to either freeze, making it harder for the predator to detect; duck into a shelter, if one is available; or run for its life.
To learn how brain activity changes in the face of such a visual threat, Salay simulated a looming predatorâs approach using a scenario devised some years ago by neurobiologist Melis Yilmaz Balban, PhD, now a postdoctoral scholar in Hubermanâs lab. It involves a chamber about the size of a 20-gallon fish tank, with a video screen covering most of its ceiling. This overhead screen can display an expanding black disc simulating a bird-of-preyâs aerial approach.
Looking for brain regions that were more active in mice exposed to this âlooming predatorâ than in unexposed mice, Salay pinpointed a structure called the ventral midline thalamus, or vMT.
Salay mapped the inputs and outputs of the vMT and found that it receives sensory signals and inputs from regions of the brain that register internal brain states, such as arousal levels. But in contrast to the broad inputs the vMT receives, its output destination points were remarkably selective. The scientists traced these outputs to two main destinations: the basolateral amygdala and the medial prefrontal cortex. Previous work has tied the amygdala to the processing of threat detection and fear, and the medial prefrontal cortex is associated with high-level executive functions and anxiety.
Further inquiry revealed that the nerve tract leading to the basolateral amygdala emanates from a nerve-cell cluster in the vMT called the xiphoid nucleus. The tract that leads to the medial prefrontal cortex, the investigators learned, comes from a cluster called the nucleus reuniens, which snugly envelopes the xiphoid nucleus.
Next, the investigators selectively modified specific sets of nerve cells in miceâs brains so they could stimulate or inhibit signaling in these two nerve tracts. Exclusively stimulating xiphoid activity markedly increased miceâs propensity to freeze in place in the presence of a perceived aerial predator. Exclusively boosting activity in the tract running from the nucleus reuniens to the medial prefrontal cortex in mice exposed to the looming-predator stimulus radically increased a response seldom seen under similar conditions in the wild or in previous open-field experiments: The mice stood their ground, right out in the open, and rattled their tails, an action ordinarily associated with aggression in the species.
Thumping tails
This âcourageousâ behavior was unmistakable, and loud, Huberman said. âYou could hear their tails thumping against the side of the chamber. Itâs the mouse equivalent of slapping and beating your chest and saying, âOK, letâs fight!ââ The mice in which the nucleus reuniens was stimulated also ran around more in the chamberâs open area, as opposed to simply running toward hiding places. But it wasnât because nucleus reuniens stimulation put ants in their pants; in the absence of a simulated looming predator, the same mice just chilled out.
In another experiment, the researchers showed that stimulating miceâs nucleus reuniens for 30 seconds before displaying the âlooming predatorâ induced the same increase in tail rattling and running around in the unprotected part of the chamber as did vMT stimulation executed concurrently with the display. This suggests, Huberman said, that stimulating nerve cells leading from the nucleus reunions to the prefrontal cortex induces a shift in the brainâs internal state, predisposing mice to act more boldly.
Another experiment pinpointed the likely nature of that internal-state shift: arousal of the autonomic nervous system, which kick-starts the fight, flight or freeze response. Stimulating either the vMT as a whole or just the nucleus reuniens increased the miceâs pupil diameter â a good proxy of autonomic arousal.
On repeated exposures to the looming-predator mockup, the mice became habituated. Their spontaneous vMT firing diminished, as did their behavioral responses. This correlates with lowered autonomic arousal levels.
Human brains harbor a structure equivalent to the vMT, Huberman said. He speculated that in people with phobias, constant anxiety or PTSD, malfunctioning circuitry or traumatic episodes may prevent vMT signaling from dropping off with repeated exposure to a stress-inducing situation. In other experiments, his group is now exploring the efficacy of techniques, such as deep breathing and relaxation of visual fixation, in adjusting the arousal states of people suffering from these problems. The thinking is that reducing vMT signaling in such individuals, or altering the balance of signaling strength from their human equivalents of the xiphoid nucleus and nucleus reuniens may increase their flexibility in coping with stress.
A neurobiological link between PTSD and addiction
Recalling traumatic memories enhances the rewarding effects of morphine in male rats, finds new research published in JNeurosci. These findings may help to explain the co-occurrence of post-traumatic stress disorder (PTSD) and addiction.
More than half of PTSD patients also struggle with substance abuse, yet the underlying neural mechanisms of their addiction are not clear. Dopamine receptors in the prefrontal cortex may play a role, as they are involved in the processing of both fear- and reward-related memories.
Steven Laviolette and colleagues examined the involvement of two dopamine receptors in the recall of a traumatic experience â a footshock â and subsequent preference for morphine. Rats that were reminded of the troubling experience by an associated scent showed a greater freezing fear response and spent more time in an environment where they previously received a dose of morphine that ordinarily does not produce a preference for a morphine-paired environment. This effect was blocked by activation of the dopamine receptor D1R. A different dopamine receptor, D4R, increased freezing behavior and reward sensitivity after the recall of a minor footshock that does not produce a traumatic memory under normal conditions. The results suggest that abnormal dopamine signals in the prefrontal cortex may underlie the ability of traumatic memories to predispose individuals to addiction by increasing their sensitivity to the rewarding effects of drugs such as opioids.
âYou know that kind of jobs that consume your day up and force you to find another time to do what you like? Well, I have this job. My job starts just before the sunset and occupies the majority of night. When I return to my home, I either go to bed or live the night. If I go to the bed, I have nothing important to do in the morning except waiting for my work time! Therefore, I often choose to live the night. Its darkness and calmness give me too much pleasure and peace I rarely find in the morning when all people are awake! I spend the whole time listening to music, watching movies, and thinking about a lot of different things. Overthinking is a terrible devastating disease. I discovered this later. Donât think too much! Stay superficial! Or you gonna use CNS depressants to shut down the whole system when you gotta sleep. Itâs your choice. When the dawn is over and the sun begins to rise, I feel exactly what the vampire does when he gets out of his coffin to find himself under the light of sun! Trust me, itâs a hideous and painful feeling. You donât know how much power is required to overcome the sound of people walking just outside your house, that of cars racing in the streets, or the voice of some neighbors fighting about the apocalypse! I wished once if they were hallucinations, at least you can make them vanish by certain drugs! Theyâre real disturbing things unfortunately. Over many nights Iâve turned to a nyctophilic creature which added to being introvert too. When I walk down the streets between people heading to a certain destination, Iâm almost having some sort of phobia. To what exactly this phobia is toward? I guess not to the wide open places but instead to these movable pawns of misery!â #30DaysOfNight #NocturnalCreature (at Alexandria, Egypt) https://www.instagram.com/p/Bpk5vNIF693z1tKL3APvb9GlaTmk-8VVAJ-XGM0/?utm_source=ig_tumblr_share&igshid=rjbtbsdgmo81