Unconscious feelings

A review that inadvertently showed how memory paradigms prevented relevant research

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This 2016 Swiss review of enduring memories demonstrated what happens when scientists’ reputations and paychecks interfered with them recognizing new research and evidence in their area but outside their paradigm: “A framework containing the basic assumptions, ways of thinking, and methodology that are commonly accepted by members of a scientific community.”

A. Most of the cited references were from decades ago that established these paradigms of enduring memories. Fine, but the research these paradigms excluded was also significant.

B. All of the newer references were continuations of established paradigms. For example, a 2014 study led by one of the reviewers found:

“Successful reconsolidation-updating paradigms for recent memories fail to attenuate remote (i.e., month-old) ones.

Recalling remote memories fails to induce histone acetylation-mediated plasticity.”

The researchers elected to pursue a workaround of the memory reconsolidation paradigm when the need for a new paradigm of enduring memories directly confronted them!

C. None of the reviewers’ calls for further investigations challenged existing paradigms. For example, when the reviewers suggested research into epigenetic regulation of enduring memories, they somehow found it best to return to 1984, a time when dedicated epigenetics research had barely begun:

“Whether memories might indeed be ‘coded in particular stretches of chromosomal DNA’ as originally proposed by Crick [in 1984] and if so what the enzymatic machinery behind such changes might be remain unclear. In this regard, cell population-specific studies are highly warranted.”

Two examples of relevant research the review failed to consider:

1. A study that provided evidence for basic principles of Primal Therapy went outside existing paradigms to research state-dependent memories:

“If a traumatic event occurs when these extra-synaptic GABA receptors are activated, the memory of this event cannot be accessed unless these receptors are activated once again.

It’s an entirely different system even at the genetic and molecular level than the one that encodes normal memories.”

What impressed me about that study was the obvious nature of its straightforward experimental methods. Why hadn’t other researchers used the same methods decades ago? Doing so could have resulted in dozens of informative follow-on study variations by now, which is my point in Item A. above.

2. A relevant but ignored 2015 French study What can cause memories that are accessible only when returning to the original brain state? which supported state-dependent memories:

“Posttraining/postreactivation treatments induce an internal state, which becomes encoded with the memory, and should be present at the time of testing to ensure a successful retrieval.”

The review also showed the extent to which historical memory paradigms depend on the subjects’ emotional memories. When it comes to human studies, though, designs almost always avoid studying emotional memories.

It’s clearly past time to Advance science by including emotion in research.

http://www.hindawi.com/journals/np/2016/3425908/ “Structural, Synaptic, and Epigenetic Dynamics of Enduring Memories”

What’s a good substitute for feeling loved?

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A friend of mine sent a link to this TED talk yesterday. The speaker inspired my friend to change their life along the speaker’s guidelines:

“The very act of doing the thing that scared me undid the fear.

That feeling, you can’t help but strive for greatness at any cost.

The more I work to be successful, the more I need to work.”

I wasn’t similarly inspired.

For one thing, a fear memory isn’t undone by behavior that covers it over and tamps it down. Fear extinction is the learned inhibition of retrieval of previously acquired responses provided evidence for what happens with a fear memory.

What I saw expressed in the TED talk was an exhausting pursuit of substitutes for feeling loved.

This February 18, 2016 blog post by Dr Arthur Janov framed the TED talk in the context that I understood the speaker:

“Most of us thought that once we choose a profession and follow it and succeed at it, becoming an expert and well known, that would be fulfilling. We would feel like a success.

Success is not a feeling, loved is.

Fame is other people’s idea of success; it is in a way their feeling…admiration, humbling, important, etc.

And why does the person, even most accomplished, never feel satisfied nor fulfilled?”

What do you feel is the appropriate context of the TED talk?

What do you think are likely outcomes of a person following the speaker’s guidelines?

What’s the underlying question for every brain study to answer?

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Is the underlying question for every brain study to answer:

  • How do our brains internally represent the external world?

Is it:

  • How did we learn what we know?
  • How do we forget or disregard what we’ve learned?
  • What keeps us from acquiring and learning newer or better information?

How about:

  • What affects how we pay attention to our environments?
  • How do our various biochemical states affect our perceptions, learning, experiences, and behavior?
  • How do these factors in turn affect our biology?

Or maybe:

  • Why do we do what we do?
  • How is our behavior affected by our experiences?
  • How did we become attracted and motivated toward what we like?
  • How do we develop expectations?
  • Why do we avoid certain situations?

Not to lose sight of:

  • How do the contexts affect all of the above?
  • What happens over time to affect all of the above?

This 2015 UCLA paper reviewed the above questions from the perspective of Pavlovian conditioning:

“The common definition of Pavlovian conditioning, that via repeated pairings of a neutral stimulus with a stimulus that elicits a reflex the neutral stimulus acquires the ability to elicit that the reflex, is neither accurate nor reflective of the richness of Pavlovian conditioning. Rather, Pavlovian conditioning is the way we learn about dependent relationships between stimuli.

Pavlovian conditioning is one of the few areas in biology in which there is direct experimental evidence of biological fitness.”

The most important question unanswered by the review was:

  • How can its information be used to help humans?

How can Pavlovian conditioning answer: What can a human do about the thoughts, feelings, behavior, epigenetic effects – the person – the phenotype – that they’ve been shaped into?

One example of the unanswered question: the review pointed out in a section about fear extinction that this process doesn’t involve unlearning. Fear extinction instead inhibits the symptoms of fear response. The fear memory is still intact, awaiting some other context to be reactivated and expressed.

How can this information be used to help humans?

  • Is inhibiting the symptoms and leaving the fear memory in place costless with humans?
  • Or does this practice have both potential and realized adverse effects?
  • Where’s the human research on methods that may directly address a painful emotional memory?

One relevant hypothesis of Dr. Arthur Janov’s Primal Therapy is that a person continues to be their conditioned self until they address the sources of their pain. A corollary is that efforts to relieve symptoms seldom address causes.

How could it be otherwise? A problem isn’t cured by ameliorating its effects.

http://cshperspectives.cshlp.org/content/8/1/a021717.full “The Origins and Organization of Vertebrate Pavlovian Conditioning”

The effects of imposing helplessness

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This 2016 New York rodent study found:

“By using unbiased and whole-brain imaging techniques, we uncover a number of cortical and subcortical brain structures that have lower activity in the animals showing helplessness than in those showing resilience following the LH [learned helplessness] procedure. We also identified the LC [locus coeruleus] as the sole subcortical area that had enhanced activity in helpless animals compared with resilient ones.

Some of the brain areas identified in this study – such as areas in the mPFC [medial prefrontal cortex], hippocampus, and amygdala – have been previously implicated in clinical depression or depression-like behavior in animal models. We also identified novel brain regions previously not associated with helplessness. For example, the OT [olfactory tubercle], an area involved in odor processing as well as high cognitive functions including reward processing, and the Edinger–Westphal nucleus containing centrally projecting neurons implicated in stress adaptation.

The brains of helpless animals are locked in a highly stereotypic pathological state.”

Concerning the study’s young adult male subjects:

“To achieve a subsequent detection of neuronal activity related to distinct behavioral responses, we used the c-fosGFP transgenic mice expressing c-FosGFP under the control of a c-fos promoter. The expression of the c-fosGFP transgene has been previously validated to faithfully represent endogenous c-fos expression.

Similar to wild-type mice, approximately 22% (32 of 144) of the c-fosGFP mice showed helplessness.”

The final sentence of the Introduction section:

“Our study..supports the view that defining neuronal circuits underlying stress-induced depression-like behavior in animal models can help identify new targets for the treatment of depression.”

Helplessness is both a learned behavior and a cumulative set of experiences during every human’s early life. Therapeutic approaches to detrimental effects of helplessness can be different with humans than with rodents in that we can address causes.

The researchers categorized activity in brain circuits as causal in the Discussion section:

“Future studies aimed at manipulating these identified neural changes are required for determining whether they are causally related to the expression of helplessness or resilience.”

Studying whether or not activity in brain circuits induces helplessness in rodents may not inform us about causes of helplessness in humans. Our experiences are often the ultimate causes of helplessness effects. Many of our experiential “neural changes” are only effects, as demonstrated by this and other studies’ induced phenotypes such as “Learned Helplessness” and “Prenatally Restraint Stressed.”

Weren’t the researchers satisfied that the study confirmed what was known and made new findings? Why attempt to extend animal models that only treat effects to humans, as implied in the Introduction above and in the final sentence of the Discussion section:

“Future studies aimed at elucidating the specific roles of these regions in the pathophysiology of depression as well as serve as neural circuit-based targets for the development of novel therapeutics.”

http://journal.frontiersin.org/article/10.3389/fncir.2016.00003/full “Whole-Brain Mapping of Neuronal Activity in the Learned Helplessness Model of Depression” (Thanks to A Paper a Day Keeps the Scientist Okay)

Does shame keep you up at night?

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This 2016 Netherlands human study found:

“Restless REM [rapid eye movement] sleep reflects a process that interferes with the overnight resolution of distress. Its accumulation may promote the development of chronic hyperarousal.

We use the term “restless REM sleep” here to refer to REM sleep with a high number of phasic events, including arousals and eye movements.

The present study focused on shame, because it may interfere the most with healthy psychological functioning and was shown to be predictive of developing depression and PTSD symptoms, including hyperarousal. By obstructing effective coping mechanisms, shame often hinders therapeutic progress, to the point that it may even lead to a negative therapeutic outcome.

A dedicated assessment of the subjective duration of distress after a shameful experience was complemented by assessments on nocturnal mentation, insomnia severity, hyperarousal, and major life events, as well as an Internet-implemented structured interview on health.”

From the Limitations section:

  1. “Restless REM sleep was not directly quantified but approximated by means of a validated questionnaire rating of thought-like nocturnal mentation.
  2. Non-REM sleep has also been implicated in the resolution of emotional distress.
  3. A third limitation regards the observational nature of the present study..a more definite conclusion will require studies using experimental manipulation of emotions and sleep.
  4. Whereas there was good reason to focus first on distress induced by shame in our innovative approach to the role of sleep in self-conscious emotions rather than the basic emotions usually studied, our findings should not be interpreted as supporting a unique role for shame or self-conscious emotions. Future studies could address whether the duration of distress elicited by other self-conscious and basic emotions has a similar two-factor structure.”

I applaud the inclusion of emotion in research. I’m not convinced that studying shame will lead to etiologic advances in science, though.

How does shame arise in our lives? Is it a biologic human need on the same level as nourishment, protection, and socialization?

Shame is a symptom along with “nocturnal mentation, insomnia severity, hyperarousal.” If a person’s thoughts, feelings, behavior, and sleep are adversely affected by shame, a resolution should be achieved by addressing the underlying causes, not by tamping down the symptoms.

http://www.pnas.org/content/113/9/2538.full “Slow dissolving of emotional distress contributes to hyperarousal”

Advance science by including emotion in research

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This 2015 analysis of emotion studies found:

“Emotion categories [fear, anger, disgust, sadness, and happiness] are not contained within any one region or system, but are represented as configurations across multiple brain networks.

For example, among other systems, information diagnostic of emotion category was found in both large, multi-functional cortical networks and in the thalamus, a small region composed of functionally dedicated sub-nuclei.

The dataset consists of activation foci from 397 fMRI and PET [positron emission tomography] studies of emotion published between 1990 and 2011.”

From the fascinating Limitations section:

“Our analyses reflect the composition of the studies available in the literature, and are subject to testing and reporting biases on the part of authors. This is particularly true for the amygdala (e.g., the activation intensity for negative emotions may be over-represented in the amygdala given the theoretical focus on fear and related negative states). Other interesting distinctions were encoded in the thalamus and cerebellum, which have not received the theoretical attention that the amygdala has and are likely to be bias-free.

Some regions—particularly the brainstem—are likely to be much more important for understanding and diagnosing emotion than is apparent in our findings, because neuroimaging methods are only now beginning to focus on the brainstem with sufficient spatial resolution and artifact-suppression techniques.

We should not be too quick to dismiss findings in ‘sensory processing’ areas, etc., as methodological artifacts. Emotional responses may be inherently linked to changes in sensory and motor cortical processes that contribute to the emotional response.

The results we present here provide a co-activation based view of emotion representation. Much of the information processing in the brain that creates co-activation may not relate to direct neural connectivity at all, but rather to diffuse modulatory actions (e.g., dopamine and neuropeptide release, much of which is extrasynaptic and results in volume transmission). Thus, the present results do not imply direct neural connectivity, and may be related to diffuse neuromodulatory actions as well as direct neural communication.”

Why did the researchers use only 397 fMRI and PET studies? Why weren’t there tens or hundreds of times more candidate studies from which to select?

The relative paucity of candidate emotion studies demonstrated the prevalence of other researchers’ biases for cortical brain areas. The lead researcher of the current study was a coauthor of the 2016 Empathy, value, pain, control: Psychological functions of the human striatum, whose researchers mentioned that even their analyses of 5,809 human imaging studies was hampered by other imaging-studies researchers’ cortical biases.

Functional MRI signals depend on the changes in blood flow that follow changes in brain activity. Study designers intentionally limit their findings when they scan brain areas and circuits that are possibly activated by human emotions, yet exclude emotional content that may activate these areas and circuits.

Here are a few examples of limited designs that led to limited findings when there was the potential for so much more:

It’s well past time to change these practices now in the current year.

This study provided many methodological tests that should be helpful for research that includes emotion. It showed that there aren’t impenetrable barriers – other than popular memes, beliefs, and ingrained dogmas – to including emotional content in studies.

Including emotional content may often be appropriate and informative, with the resultant findings advancing science. Here are a few recent studies that did so:

http://journals.plos.org/ploscompbiol/article?id=10.1371%2Fjournal.pcbi.1004066 “A Bayesian Model of Category-Specific Emotional Brain Responses”

Outward expressions of inner truth

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“Truth needs no defense except when that truth is more than the system can integrate; then it requires defenses.

Our merciful brain has found back-up ways to protect us. It keeps the truth from us even when we go on searching for the truth.

After patients have deep feelings they come up with many truths about their lives. It is buried and defended along with the pain. Thus no one has to give anyone insights; they are already there just waiting for the exit.”

In the blog post’s Comments section:

“When repression is not effective, the imprint rises for connection. But it is transformed into an act-out before it becomes conscious.

I had to get out each morning to feel free and shake my malaise. I never ever knew the origins of needing to get out. And the act out would never stop until I felt the origins and relived them.

The memory is continuously pushing and forces all kinds of act-out behaviors. The behavior has to be close to the original imprint to make act outs effective.

The brain knows, even when we don’t. And offers up all kinds of reasons for our behavior except the right one.”

http://cigognenews.blogspot.com/2016/01/the-act-out-and-more_29.html “The Act-out and More”

Lifelong effects of stress

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A 2016 commentary A trilogy of glucocorticoid receptor actions that included two 2015 French rodent studies started out:

Glucocorticoids (GCs) belong to a class of endogenous, stress-stimulated steroid hormones. They have wide ranging physiologic effects capable of impacting metabolism, immunity, development, stress, cognition, and arousal.

GCs exert their cellular effects by binding to the GC receptor (GR), one of a 48-member (in humans) nuclear receptor superfamily of ligand-activated transcription factors.”

The French studies were exceedingly technical. The first GR SUMOylation and formation of an SUMO-SMRT/NCoR1-HDAC3 repressing complex is mandatory for GC-induced IR nGRE-mediated transrepression:

“GCs acting through binding to the GR are peripheral effectors of circadian and stress-related homeostatic functions fundamental for survival.

Unveils, at the molecular level, the mechanisms that underlie the GC-induced GR direct transrepression function mediated by the evolutionary conserved inverted repeated negative response element. This knowledge paves the way to the elucidation of the functions of the GR at the submolecular levels and to the future educated design and screening of drugs, which could be devoid of undesirable debilitating effects on prolonged GC therapy.”

The companion study Glucocorticoid-induced tethered transrepression requires SUMOylation of GR and formation of a SUMO-SMRT/NCoR1-HDAC3 repressing complex stated:

“GCs have been widely used to combat inflammatory and allergic disorders. However, multiple severe undesirable side effects associated with long-term GC treatments, as well as induction of glucocorticoid resistance associated with such treatments, limit their therapeutic usefulness.”

Even when researchers study causes, they often justify their efforts in terms of outcomes that address effects. Is an etiologic advancement in science somehow unsatisfactory in and of itself?

Once in a while I get a series of personal revelations while reading scientific publications. Paradoxically, understanding aspects of myself has seldom been sufficient to address historical problems.

Thoughts are only where some of the effects of problems show up, and clarifying my understanding can – at most – tamp down these effects. The causes are elsewhere, and addressing them at the source is what ultimately needs to happen.

A few glucocorticoid-related items to ponder:

  • How has stress impacted my life? When and where did it start?
  • Why do I feel wonderful after taking prednisone or other anti-inflammatories? What may be the originating causes of such effects?
  • Why have prolonged periods of my life been characterized by muted responses to stress? How did I get that way?
  • Have I really understood why I’ve reflexively put myself into stressful situations? What will break me out of that habit?
  • Why do the feelings I experience while under stressful situations feel familiar? Does my unconsciousness of their origins have something to do with “homeostatic functions fundamental for survival?”
  • Why haven’t I noticed that symptoms of stress keep showing up in my life? There are “physiologic effects capable of impacting metabolism, immunity,” etc. but I don’t do something about it?
  • How else may stress impact my biology? Brain functioning? Ideas and beliefs? Behavior?

What was not, is not, and will never be

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Neuroskeptic’s blog post Genetic Testing for Autism as an Existential Question related the story of “A Sister, a Father and a Son: Autism, Genetic Testing, and Impossible Decisions.”

“I decided to put the question to my sister, Maria. Although she is autistic, she is of high intelligence.

Maria was excited to be an aunt soon, and was willing to do what she could to help my baby – even if what she was helping with was to avoid her own condition.

She is high enough functioning to know some of what she’s missing in life, and has longed her entire life to be “normal.” If she could save her niece or nephew some of the pain and awkwardness her condition had caused her, she was willing to help.”

In the concluding paragraph:

“What struck me about this story is the way in which the prospect of the genetic test confronted Maria with a very personal decision: will you do something that might help prevent someone else becoming like you?

Isn’t this very close to the ultimate existential question: all things considered, would you wish to live your life over again?”

Aren’t the majority of humans also “high enough functioning to know some of what she’s missing in life?”

Aren’t our feelings of what we’re missing one of the impetuses for us to have also “longed her entire life to be normal?”

This feeling was aired in Dr. Arthur Janov’s blog post What a Waste:

“What it was, was the feeling of great loss, something missing that could never again be duplicated.

It was no love where it could have been the opposite if the parent’s gates could have been open. But it could not be because that would have meant terrible pain and suffering for them; and their whole neurologic system militated against any conscious-awareness.”

We long for what was and is impossible:

  • For many of us, the impossibilities of having normal lives started with prenatal epigenetic changes.
  • Our experiences of our postnatal environment prompted us into adapting to its people, places, and contents. These neurological, biological, and behavioral adaptations were sometimes long-lasting deviations from developmental norms.
  • Other genetic factors combined with the above to largely make us who we were and are.

Our longing for an impossible-to-reconstruct life doesn’t go away.

We often may not be aware of our longing for what “could not be” and of its extensive impacts. Such feelings impel us into many hundreds of ideas, hundreds of beliefs, and hundreds of behaviors, a sample of which were referred to above:

  • Behaviors to “do something that might help prevent someone else becoming like you;”
  • Ideas such as existential philosophy; and
  • Beliefs that manifest the “wish to live your life over again.”

Spending our time on these ideas, beliefs, and behaviors won’t ameliorate their motivating causes. Our efforts distance us from our truths, with real consequences: a wasted life.

What keeps us from understanding our reality? I invite readers to investigate Dr. Arthur Janov’s Primal Therapy for effective therapeutic approaches.

A problematic study of testosterone’s influence on behavior and brain measurements

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This 2015 US/Canadian human study of people ages 6 to 22 years found:

“Testosterone-specific associations between amygdala volume and key prefrontal areas involved in emotional regulation and impulse control:

  1. Testosterone-specific modulation of the covariance between the amygdala and medial prefrontal cortex (mPFC);
  2. A significant relationship between amygdala-mPFC covariance and levels of aggression; and
  3. Mediation effects of amygdala-mPFC covariance on the relationship between testosterone and aggression.

These effects were independent of sex, age, pubertal stage, estradiol levels and anxious-depressed symptoms.

For the great majority of individuals in this sample, higher thickness of the mPFC was associated with lower aggression levels at a given amygdala volume. This effect diminished greatly and disappeared at more extreme amygdala values.”

The study provided noncausal associations among the effects (behavioral, hormonal, and brain measurements).

From the Limitations section:

“No umbilical cord or amniotic measurements were available in this study and we therefore cannot control for testosterone levels in utero, a period during which significant testosterone-related changes in brain structure are thought to occur.”

There’s evidence that too much testosterone for a female fetus and too little testosterone for a male fetus both have lifelong adverse effects. The researchers dismissed this etiologic line of inquiry with a “supporting the notion” referral to noncausal studies.

The researchers were keen to establish:

“A very specific, aggression-related structural brain phenotype.”

This putative phenotype hinged on:

  • Older subjects’ behavioral self-reports, and
  • Parental assessments of younger subjects’ behavior

exhibited during the previous six months, and within six months of their fMRI scan.

These self-reports and interested-party observations were the entire bases for the “aggressive behavior” and “anxious–depressed” associations! The researchers disingenuously provided multiple references and models for the reliability of these assessments.

Experimental behavioral measurements – such as those done to measure performance in decision studies – may have been more accurate and informative than what the older subjects chose to self-report about their own behavior over the previous six months.

People of all ages have an imperative to NOT be completely honest about their own behavior. One motivation for this condition is that some of our historical realities are too painful to enter our conscious awareness and inform us about our own behavior. As a result, our feelings, thoughts, and behavior are sometimes driven by our histories without us being aware of it.

For example, would a teenager/young adult subject self-report an impulsive act, even if they didn’t fully understand why they acted that way? Maybe they would if the act could be viewed as prosocial, but what if it was antisocial?

What are the chances that the lives of these teenager/young adult subjects were NOT filled with impulsive actions during the six months before their fMRI scans? Could complete and accurate self-reports of such behaviors be expected?

Experimental behavioral measurements may have also been more accurate and informative than second-hand, interested-party observations of the younger subjects. Could a parent who provided half of the genes and who was responsible for many of their child’s epigenetic changes make anything other than subjective observations of their handiwork’s behavior?

Epigenetic studies have shown that adaptations to environments are among the long-lasting causes for effects that include behavior, hormones, and brain measurements. Why, in 2015, did researchers spend public funds developing what they knew or should have known would be noncausal associations, while not investigating possible causes for these effects?

Why weren’t the researchers interested enough to gather and assess etiologic genetic and epigenetic evidence? Was it that difficult to get blood samples at the same time the subjects gave saliva samples, and perform selected genetic and DNA methylation analyses?

What did the study contribute towards advancing science? Who did the study really help?

My judgment: less than nothing; and nobody. The researchers only wasted public funds advancing a meme, giving it an imprimatur of science.

http://www.psyneuen-journal.com/article/S0306-4530%2815%2900924-5/fulltext “A testosterone-related structural brain phenotype predicts aggressive behavior from childhood to adulthood”

The cerebellum’s role in human behavior and emotions

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This 2016 Italian human review considered the lower brain’s contributions to an individual’s behavior and temperament:

“In evidencing associations between personality factors and neurobiological measures, it seems evident that the cerebellum has not been up to now thought as having a key role in personality.

Cerebellar volumes correlate positively with novelty seeking scores and negatively with harm avoidance scores. Subjects who search for new situations as a novelty seeker does (and a harm avoiding does not do) show a different engagement of their cerebellar circuitries in order to rapidly adapt to changing environments.

Cerebellar abilities in planning, controlling, and putting into action the behavior are associated to normal or abnormal personality constructs. In this framework, it is worth reporting that increased cerebellar volumes are even associated with high scores in alexithymia, construct of personality characterized by impairment in cognitive, emotional, and affective processing.”

The full paper wasn’t freely available, but a list of the 173 references was. 17 references were of alexithymia, also mentioned in the title.

One freely available reference was The embodied emotion in cerebellum: a neuroimaging study of alexithymia, a 2014 study performed by these same authors, which found:

“Alexithymia scores were linked directly with cerebellar areas and inversely with limbic and para-limbic system, proposing a possible functional modality for the cerebellar involvement in emotional processing.

The increased volumes in Crus 1 of subjects with high alexithymic traits may be related to an altered embodiment process leading to not-cognitively interpreted emotions.”

“Alexithymia scores” referred to one of the methods used to characterize alexithymia symptoms, self-reported answers to questionnaires such as this one. Sample questions from the questionnaire used by the referenced study are:

  • “I am often confused about what emotion I am feeling
  • It is difficult for me to reveal my innermost feelings, even to close friends”

The questionnaire mainly engages a person’s cerebrum. The person may recall emotions, and form ideas as framed by each question. Then they’ll describe these ideas in terms of a scaled answer.

Cerebral answers may provide historical contexts for feelings. However, the person’s cerebellum and other brain areas aren’t necessarily engaged by the diagnostic questionnaire.

Without this engagement, the person may not experience feelings when providing answers about feelings. The answers may be more along the lines of “This is what I think I should be feeling” or “This is what I think I should tell the researchers about what I think I should feel.”

  • Can a questionnaire accurately determine associations among engaged and unengaged brain areas?
  • What can be done regarding “impairment in cognitive, emotional, and affective processing?”
  • What’s the lower brain’s “involvement in emotional processing?”
  • How does the lower brain shape a person’s behavior and traits?
  • When and where in an individual’s lifespan does their cerebellum develop?

http://link.springer.com/article/10.1007/s12311-015-0754-9 “Viewing the Personality Traits Through a Cerebellar Lens: a Focus on the Constructs of Novelty Seeking, Harm Avoidance, and Alexithymia”

It is known: Are a study’s agendas more important than its evidence?

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This 2015 Swiss human study’s Abstract began:

“It is known that increased circulating glucocorticoids in the wake of excessive, chronic, repetitive stress increases anxiety and impairs Brain-Derived Neurotrophic Factor (BDNF) signaling.”

The study had several statements that were unconvincingly supported by the study’s findings. One such statement in the Conclusions section was:

“This study supports the view that early-life adversity may induce long-lasting epigenetic changes in stress-related genes, thus offering clues as to how intergenerational transmission of anxiety and trauma could occur.”

However, the study’s evidence for “intergenerational transmission of anxiety and trauma” as summarized in the Limitations section was:

“This study did not directly associate child behavior or biology to maternal behavior and biology.”

In another example, the Discussion section began with:

“The severity of maternal anxiety was significantly correlated with mean overall methylation of 4 CpG sites located in exon IV of the BDNF promoter region as measured from DNA extracted from mothers’ saliva.

In addition, methylation at CpG3 was also significantly associated with maternal exposure to domestic violence during childhood, suggesting that BDNF gene methylation levels are modulated by early adverse experiences.”

The researchers assessed five DNA methylation values (four individual sites and the overall average). The CpG3 site was “significantly associated with maternal exposure to domestic violence during childhood” and the three other CpG sites’ methylation values were not.

IAW, the researchers found only one of four sites’ methylation values significantly associated to only one of many studied early adverse experiences. This finding didn’t provide sufficient evidence to support the overarching statement:

“BDNF gene methylation levels are modulated by early adverse experiences.”

To make such a generally applicable statement – more than one BDNF gene’s methylation levels could be directly altered by more than one early adverse experience – the researchers would, AT A MINIMUM, need to provide evidence that:

  1. The one category of significantly associated early adverse experience directly altered the one significantly associated CpG site’s DNA methylation level
  2. Other categories of early adverse experiences were fairly represented by the one significantly associated experience category
  3. Other categories of early adverse experiences could directly alter other BDNF genes’ DNA methylation levels
  4. The significantly associated DNA methylation level of only one out of four CpG sites was fairly represented by the overall average of the four sites
  5. Other BDNF gene’s methylation levels were fairly represented by the overall average of the four sites

If researchers and sponsors must have agendas, a worthwhile, evidence-supported one would be to investigate prenatal and perinatal epigenetic causes for later-life adverse effects.

As Grokking an Adverse Childhood Experiences (ACE) score pointed out, environmental factors that disrupt neurodevelopment may be the largest originators of epigenetic changes that are sustained throughout an individual’s entire lifespan.

What’s the downside of conducting studies that may “directly associate child behavior or biology to maternal behavior and biology” during time periods when a child’s environment has the greatest impact on their development?

When prenatal and perinatal periods aren’t addressed, researchers and sponsors neglect the times during which many harmful epigenetic consequences may be prevented. It is known.

http://journals.plos.org/plosone/article?id=10.1371/journal.pone.0143427 “BDNF Methylation and Maternal Brain Activity in a Violence-Related Sample”

Emotional memories create long-term epigenetic changes

gettingwell4 2-3 stars Required further work, Anterior cingulate cortex, Brain development, Epigenetics, Hippocampus, Limbic system, Memory, Stress , , , , , ,

This 2015 German rodent study found:

Histone modifications predominantly changed during memory acquisition and correlated surprisingly little with changes in gene expression.

Although long-lasting changes were almost exclusive to neurons, learning-related histone modification and DNA methylation changes also occurred in non-neuronal cell types, suggesting a functional role for non-neuronal cells in epigenetic learning.”

Chromatin modifications in two limbic system brain areas were studied – the hippocampus (CA1 region) for short-term memories and the anterior cingulate cortex for short-and long-term memory formation and maintenance. The memories were induced by context (C) and context shock (CS) exposure:

“Overall, the data provides very strong and robust evidence for the establishment of long-term memory upon CS exposure, whereas C exposure alone did not induce the formation of long-term memory.”

So, without long-term shock/emotional memories, there would be no positive long-term findings for the researchers to report. There would be no lasting:

  • “Histone modifications
  • DNA methylation changes
  • Changes in gene expression”

The subjects were young adults at age 3 months. The CA1 and ACC studied brain areas are fully developed before this age.

It seemed feasible that if the study were performed with younger subjects, the results may have been different. For example:

“Context exposure alone did not induce the formation of long-term memory”

may not have been the finding for early learning situations.

The researchers qualified their results several times with the phrase “changes are limited to actively expressed genes.” A similar qualifier in A study of DNA methylation and age was a reminder that unexpressed genes may have also been important:

The textbook case of DNA methylation regulating gene expression (the methylation of a promoter and silencing of a gene) remains undetected in many cases because in an array analysis, an unexpressed gene shows no signal that can be distinguished from background and is therefore typically omitted from the analysis.”

This general qualifier may not have necessarily applied to the current study, though, because the study’s design included an unexposed control group.

http://www.nature.com/neuro/journal/vaop/ncurrent/full/nn.4194.html “DNA methylation changes in plasticity genes accompany the formation and maintenance of memory”

Trapped, suffocating, unable to move – a Primal imprint

gettingwell4 5+ stars Premium, Brain development, Brainstem, Epigenetics, Limbic system, Lower brain, Memory, Neurochemicals, Primal Therapy, Serotonin , , , , , , ,

“The malady of needing to move constantly: organizing trips, making reasons to go here and there, and in general, keeping on the move..below all that movement is a giant, silent scream.

The price we pay is never knowing our feelings or where they come from.

We have the mechanism for our own liberation inside of us, if we only knew it.

When we see constant motion we understand, but we never see the agony. Why no agony? Because it is busy being acted-out to relieve the agony before it is fully felt.”

http://cigognenews.blogspot.com/2015/11/epigenetics-and-primal-therapy-cure-for_30.html “The Miracle of Memory – Epigenetics and Primal Therapy: The Cure for Neurosis (Part 13/20)”

The emotional power of environmental sounds affects our sensory experiences

gettingwell4 5+ stars Premium, Amygdala, Hypothalamus, Limbic system, Neurochemicals

This 2015 Chinese/Australian study found:

“Human emotions systematically track changes in the acoustic environment, affecting not only how we experience those sounds but also how we perceive facial expressions in other people.

Three changes in acoustic attributes known to signal emotional states in speech and music [frequency spectrum, intensity, and rate] were imposed upon 24 environmental sounds.

Evolution promotes development in the direction toward selective advantage. Thus, it is reasonable to suggest that the capacity to track changes in the acoustic environment evolved before the development of a vocalization system for emotional communication.

Regardless of the evolutionary implications of the effect, the findings illustrate the emotional power of environmental sounds on both our experience of sounds and our evaluations of accompanying visual stimuli.”

Here are the sounds used in the study:

“Human actions (breathing, chatting, chewing, clapping, stepping, typing), animal sounds (bird, cat, cricket, horse, mosquito, rooster), machine noise (car engine, electrical drill, helicopter, jet plane, screeching tires, train), and sounds in nature (dripping water, rain, river, thunder, waves, wind)”

Does this emotional communication’s frequency spectrum, intensity, and rate affect your perception of her face?

http://www.pnas.org/content/112/47/14563.full “Human emotions track changes in the acoustic environment”