Monday, April 29, 2013

Lessons learned from a Chaos and Comlexity seminar.

For ~ 15 years I have participated in the weekly Chaos and Complexity seminar at the Univ. of Wisconsin organized by physics professor Clint Sprott, and have given ~5 lectures to the group during that period.  I want to pass on this link to Sprott's summary comments  presented at the final meeting of the spring term on 5/7/2013. Here I would like to pass on his closing comments:
We have heard many speakers over the years make dire predictions, especially regarding the climate and the ecology, but I am more optimistic than most about our future for five fundamental reasons: 1) Negative feedback is at least as common as positive feedback, and it tends to regulate many processes. 2) Most nonlinearities are beneficial, putting inherent limits on the growth of deleterious effects. 3) Complex dynamical systems self-organize to optimize their fitness. 4) Chaotic systems are sensitive to small changes, making prediction difficult, but facilitating control. 5) Our knowledge and technology will continue to advance, meaning that new solutions to problems will be developed as they are needed or, more likely, soon thereafter in response to the need. Whether it's fusion reactors, geoengineering, vastly improved batteries, halting of the aging process, DNA cloning to restore extinct species, or some other game changer, things may get worse before they get better, but humans are enormously ingenious and adaptable and will rise to the challenge of averting disaster.
This is not a prediction that our problems will vanish or an argument for ignoring them. On the contrary, our choices and actions are the means by which society will reorganize to become even better in the decades to follow, albeit surely not a Utopia.

Friday, April 26, 2013

Teleological reasoning about nature: intentional design or relational perspectives?

Ojalehto et al. offer an interesting analysis of assumptions about our reasoning about natural phenomena. Some slightly edited clips from the abstract and paper:
According to the theory of ‘promiscuous teleology’, humans are naturally biased to (mistakenly) construe natural kinds as if they (like artifacts) were intentionally designed ‘for a purpose’ (i.e. clouds are 'for' raining). However, this theory introduces two paradoxes. First, if infants readily distinguish natural kinds from artifacts, as evidence suggests, why do school-aged children erroneously conflate this distinction? Second, if Western scientific education is required to overcome promiscuous teleological reasoning, how can one account for the ecological expertise of non-Western educated, indigenous people? We develop an alternative ‘relational-deictic’ interpretation, proposing that the teleological stance may not index a deep-rooted belief that nature was designed for a purpose, but instead may reflect an appreciation of the perspectival relations among living things and their environments.
A new relational-deictic framework can take into account a rich set of relations and perspectives among natural entities, permitting one to avoid cultural assumptions about the ‘right way’ to conceptualize nature, and identifying the claim for ‘intuitive theism’ as a culturally-infused stance. Kelemen writes that teleological reasoning is a ‘side-effect’ of people's natural inclination to ‘privilege intentional explanation’ and view ‘nature as an intentionally designed artifact.’ The relational-deictic framework outlined here offers a different interpretation: teleological reasoning reflects a tendency to think through perspectival relationships within (socio-ecological) webs of interdependency. On this view, the origins of teleological thinking are social and relational rather than individual and intentional. This has implications for ongoing debates about the primacy of social and relational theories in human development.
The relational-deictic interpretation opens new avenues for research into how people come to understand the natural world and their place within it. Teleological reasoning may not be immature or misguided. Instead, it may reflect young children's ecological perspective-taking abilities and serve as an entry-point for reasoning about socio-ecological systems of living things, rather than reasoning about isolated, abstracted, and essentialized individual kinds

Thursday, April 25, 2013

Brain activity correlating with future antisocial activity.

From Aharoni et al.:
Identification of factors that predict recurrent antisocial behavior is integral to the social sciences, criminal justice procedures, and the effective treatment of high-risk individuals. Here we show that error-related brain activity elicited during performance of an inhibitory task prospectively predicted subsequent rearrest among adult offenders within 4 y of release (N = 96). The odds that an offender with relatively low anterior cingulate activity would be rearrested were approximately double that of an offender with high activity in this region, holding constant other observed risk factors. These results suggest a potential neurocognitive biomarker for persistent antisocial behavior.
A marker, fine, but as a guide to action?  Suggesting more post-incarceration therapeutic efforts with those having lower anterior cingulate activities?

Wednesday, April 24, 2013

Body posture modulates action perception.

From Zimmermann et al:
Recent studies have highlighted cognitive and neural similarities between planning and perceiving actions. Given that action planning involves a simulation of potential action plans that depends on the actor's body posture, we reasoned that perceiving actions may also be influenced by one's body posture. Here, we test whether and how this influence occurs by measuring behavioral and cerebral (fMRI) responses in human participants predicting goals of observed actions, while manipulating postural congruency between their own body posture and postures of the observed agents. Behaviorally, predicting action goals is facilitated when the body posture of the observer matches the posture achieved by the observed agent at the end of his action (action's goal posture). Cerebrally, this perceptual postural congruency effect modulates activity in a portion of the left intraparietal sulcus that has previously been shown to be involved in updating neural representations of one's own limb posture during action planning. This intraparietal area showed stronger responses when the goal posture of the observed action did not match the current body posture of the observer. These results add two novel elements to the notion that perceiving actions relies on the same predictive mechanism as planning actions. First, the predictions implemented by this mechanism are based on the current physical configuration of the body. Second, during both action planning and action observation, these predictions pertain to the goal state of the action.

Tuesday, April 23, 2013

Where our brains compute musical reward.

Yet another fascinating chunk from Zatorre and collaborators:
We used functional magnetic resonance imaging to investigate neural processes when music gains reward value the first time it is heard. The degree of activity in the mesolimbic striatal regions, especially the nucleus accumbens, during music listening was the best predictor of the amount listeners were willing to spend on previously unheard music in an auction paradigm. Importantly, the auditory cortices, amygdala, and ventromedial prefrontal regions showed increased activity during listening conditions requiring valuation, but did not predict reward value, which was instead predicted by increasing functional connectivity of these regions with the nucleus accumbens as the reward value increased. Thus, aesthetic rewards arise from the interaction between mesolimbic reward circuitry and cortical networks involved in perceptual analysis and valuation.

Monday, April 22, 2013

Quiet - the world of introverts.

I recently visited my year old grandson in Austin, TX., who turns out to be my opposite on Jerome Kagan's scale of temperamental introversion/extraversion. Like his mother, he is outgoing and gregarious, and wears me out very quickly with his intensity in play activities. Against this background I was struck by reading a book review by Judith Warner of Susan Cain's new book "Quiet", listed by the NY Times as one of the 10 major popular science books of the past year. Some clips from the review:
Too often denigrated and frequently overlooked in a society that’s held in thrall to an “Extrovert Ideal — the omnipresent belief that the ideal self is gregarious, alpha and comfortable in the spotlight,” Cain’s introverts are overwhelmed by the social demands thrust upon them. They’re also underwhelmed by the example set by the voluble, socially successful go-getters in their midst who “speak without thinking,” in the words of a Chinese software engineer whom Cain encounters in Cupertino, Calif.
Many of the self-avowed introverts she meets in the course of this book.. ape extroversion...some fake it well enough to make it, going along to get along in a country that rewards the out­going...Unchecked extroversion — a personality trait Cain ties to ebullience, excitability, dominance, risk-taking, thick skin, boldness and a tendency toward quick thinking and thoughtless action — has actually, she argues, come to pose a real menace of late. The outsize reward-seeking tendencies of the hopelessly ­outer-directed helped bring us the bank meltdown of 2008...she claims....it’s time to establish “a greater balance of power” between those who rush to speak and do and those who sit back and think. Introverts — who, according to Cain, can count among their many virtues the fact that “they’re relatively immune to the lures of wealth and fame” — must learn to “embrace the power of quiet.” And extroverts should learn to sit down and shut up.
Her accounts of introverted kids misunderstood and mishandled by their parents should give pause, for she rightly notes that introversion in children (often incorrectly viewed as shyness) is in some ways threatening to the adults around them. Indeed, in an age when kids are increasingly herded into classroom “pods” for group work, Cain’s insights into the stresses of nonstop socializing for some children are welcome; her advice that parents should choose to view their introverted offspring’s social style with understanding rather than fear is well worth hearing.
A...problem with Cain’s argument is her assumption that most introverts are actually suffering in their self-esteem. This may be true in the sorts of environments — Harvard Business School, corporate boardrooms, executive suites — that she knows best and appears to spend most of her time thinking about. Had she spent more time in other sorts of places, among other types of people — in research laboratories, for example, or among economists rather than businessmen and -women — she would undoubtedly have discovered a world of introverts quite contented with who they are, and who feel that the world has been good to them.

Friday, April 19, 2013

Free Will, continued - Prior unconscious brain activity predicts choices for abstract intentions!

I've been running a thread on free will and neuroscience in this blog, recently noting comments by Nahmias:
...As long as people understand that discoveries about how our brains work do not mean that what we think or try to do makes no difference to what happens, then their belief in free will is preserved. What matters to people is that we have the capacities for conscious deliberation and self-control that I’ve suggested we identify with free will.
...None of the evidence marshaled by neuroscientists and psychologists suggests that those neural processes involved in the conscious aspects of such complex, temporally extended decision-making are in fact causal dead ends. It would be almost unbelievable if such evidence turned up.
Almost unbelievable appears to have happened, with this from Soon et al.. Interestingly, they identified a partial spatial and temporal overlap of choice-predictive signals with activity in the default mode network I reviewed in this past Monday's post. The abstract:
Unconscious neural activity has been repeatedly shown to precede and potentially even influence subsequent free decisions. However, to date, such findings have been mostly restricted to simple motor choices, and despite considerable debate, there is no evidence that the outcome of more complex free decisions can be predicted from prior brain signals. Here, we show that the outcome of a free decision to either add or subtract numbers can already be decoded from neural activity in medial prefrontal and parietal cortex 4 s before the participant reports they are consciously making their choice. These choice-predictive signals co-occurred with the so-called default mode brain activity pattern that was still dominant at the time when the choice-predictive signals occurred. Our results suggest that unconscious preparation of free choices is not restricted to motor preparation. Instead, decisions at multiple scales of abstraction evolve from the dynamics of preceding brain activity.
And, a chunk from their discussion:
It is interesting that mental calculation, the more complex task, had less predictive lead time than a simple binary motor choice in our previous study. This could tentatively reflect a general limitation of unconscious processing in the sense that unconscious processes might be restricted in their ability to develop or stabilize complex representations such as abstract intentions. It is also worth noting that both studies showed the same dissociation between cortical regions that were predictive of the content versus the timing of the decision. This implies that the formation of an intention to act depends on interactions between the choice-predictive and time-predictive regions. The temporal profile of this interaction is likely to determine when the earliest choice-predictive information is available and might differ between tasks.
There was a partial spatial overlap between the choice-predictive brain regions and the DMN. Interestingly, the state of the DMN (default mode network) during the early preparatory phase still resembled that during off-task or “resting” periods. This lends further credit to the notion that the preparatory signals were not a result of conscious engagement with the task. Furthermore, the spatial and temporal overlap hints at a potential involvement of the DMN in unconscious choice preparation.
To summarize, we directly investigated the formation of spontaneous abstract intentions and showed that the brain may already start preparing for a voluntary action up to a few seconds before the decision enters into conscious awareness. Importantly, these results cannot be explained by motor preparation or general attentional mechanisms. We found that frontopolar and precuneus/posterior cingulate encoded the content of the upcoming decision, but not the timing. In contrast, the pre-SMA predicted the timing of the decision, but not the content.

Thursday, April 18, 2013

Showing where moral intent is determined in our brains.

Interesting work from Koster-Hale et al:
Intentional harms are typically judged to be morally worse than accidental harms. Distinguishing between intentional harms and accidents depends on the capacity for mental state reasoning (i.e., reasoning about beliefs and intentions), which is supported by a group of brain regions including the right temporo-parietal junction (RTPJ). Prior research has found that interfering with activity in RTPJ can impair mental state reasoning for moral judgment and that high-functioning individuals with autism spectrum disorders make moral judgments based less on intent information than neurotypical participants. Three experiments, using multivoxel pattern analysis, find that (i) in neurotypical adults, the RTPJ shows reliable and distinct spatial patterns of responses across voxels for intentional vs. accidental harms, and (ii) individual differences in this neural pattern predict differences in participants’ moral judgments. These effects are specific to RTPJ. By contrast, (iii) this distinction was absent in adults with autism spectrum disorders. We conclude that multivoxel pattern analysis can detect features of mental state representations (e.g., intent), and that the corresponding neural patterns are behaviorally and clinically relevant.

Wednesday, April 17, 2013

Brain training games don't actually make you smarter.

Wow...after having done several posts uncritically passing on studies by Jaeggi and others claiming that games to improve working memory, such as the n-Back game, increase cognitive skills in other areas, a number of studies have failed to replicate these phenomena. Gareth Cook has done an interesting article on this in The New Yorker, suggesting that claims made by commercial software sites like Cogmen, Lumosity, and CogniFit are bogus.
Over the last year, however, the idea that working-memory training has broad benefits has crumbled. One group of psychologists, lead by a team at Georgia Tech, set out to replicate the Jaeggi findings, but with more careful controls and seventeen different cognitive-skills tests. Their subjects showed no evidence whatsoever for improvement in intelligence. They also identified a pattern of methodological problems with experiments showing positive results, like poor controls and a reliance on a single measure of cognitive improvement. This failed replication was recently published in one of psychology’s top journals, and another, by a group at Case Western Reserve University, has been published since.
The recent meta-analysis, led by Monica Melby-LervÃ¥g, of the University of Oslo, and also published in a top journal, is even more damning. Some studies are more convincing than others, because they include more subjects and show a larger effect. Melby-LervÃ¥g’s paper laboriously accounts for this, incorporating what Jaeggi, Klingberg, and everyone else had reported. The meta-analysis found that the training isn’t doing anyone much good. If anything, the scientific literature tends to overstate effects, because teams that find nothing tend not to publish their papers. (This is known as the “filedrawer” effect.) A null result from meta-analysis, published in a top journal, sends a shudder through the spine of all but the truest of believers. In the meantime, a separate paper by some of the Georgia Tech scientists looked specifically at Cogmed’s training, which has been subjected to more scientific scrutiny than any other program. “The claims made by Cogmed,” they wrote, “are largely unsubstantiated.”

Tuesday, April 16, 2013

Older brains - just as much nerve firing, but scrambled connections?

A group of colleagues at Imperial College London and Tsinghua University in Beijing have fitted glass windows on the skulls of old and young mice. Contrary to expectation they observe that older mice have more firing points than younger ones, but they are more erratic in their activity than in younger mice, with high turnover rates and wavering firing strengths. The older mice also performed less well on a memory test. The suggestion then is that the mental decline seen in aging may be due more do disorderly wiring than to loss of nerve cells. Their abstract:
Aging is a major risk factor for many neurological diseases and is associated with mild cognitive decline. Previous studies suggest that aging is accompanied by reduced synapse number and synaptic plasticity in specific brain regions. However, most studies, to date, used either postmortem or ex vivo preparations and lacked key in vivo evidence. Thus, whether neuronal arbors and synaptic structures remain dynamic in the intact aged brain and whether specific synaptic deficits arise during aging remains unknown. Here we used in vivo two-photon imaging and a unique analysis method to rigorously measure and track the size and location of axonal boutons in aged mice. Unexpectedly, the aged cortex shows circuit-specific increased rates of axonal bouton formation, elimination, and destabilization. Compared with the young adult brain, large (i.e., strong) boutons show 10-fold higher rates of destabilization and 20-fold higher turnover in the aged cortex. Size fluctuations of persistent boutons, believed to encode long-term memories, also are larger in the aged brain, whereas bouton size and density are not affected. Our data uncover a striking and unexpected increase in axonal bouton dynamics in the aged cortex. The increased turnover and destabilization rates of large boutons indicate that learning and memory deficits in the aged brain arise not through an inability to form new synapses but rather through decreased synaptic tenacity. Overall our study suggests that increased synaptic structural dynamics in specific cortical circuits may be a mechanism for agerelated cognitive decline.

Monday, April 15, 2013

A review - Mindfulness meditation and our brain's default versus attentional networks.

I've been doing some homework on potential topics to work up into a lecture, one of them being brain correlates of various meditative, attentional, or default mode states. The vocabulary used is sometimes contradictory between papers, but two categories emerge. One uses terms for thought like default, narrative focus, phenomenal, social reasoning, theory of mind, baseline setting, self referential, introspective, and stimulus independent. The contrasting descriptors are attentional, direct experience, experiential focus, task positive network, physical cause/effect reasoning.

This cooks down roughly to distinguishing between brain networks whose primary activity occurs during internal narrative focus versus those activated during direct attentional experience.

In reviewing previous mindblog posts on the default network I come up with a partial bibliography of reviews and experiments, and thought some readers might find it useful, a list in no particular order, with brief notes:

Reciprocal repression (mutual inhibition) between networks - nice graphics  - some muddying of definitions

Relationship of this mutual inhibition to mindfulness meditation , which notes Farb et al., 2007

Review (NYTimes) on power of concentration - mindfulness training causing increased connectivity in attentional and default networks. 

Review with graphics of MRI of default network activated by autobiographical memory, envisioning future, theory of mind, moral decision making. 

Tierney - virtues of a wandering mind.  (context, larger agenda, creativity)

Review of varieties of resting state activity

Change between operating systems during eyeblink.

Different components of default mode active in different kinds of memory.

Mental time travel and default network.

Synchronization of both modes between individuals.

Default network can be realized by multiple architectures (split brain patients).

Default network as underpinning of cerebral ‘connectome‘  - good graphic.

Development of human default network from being sparsely functionally connected at 7-9  years.







Default mode in Chimps and Monkeys

Association of default network with midline structures.

Friday, April 12, 2013

Why old folks more easy lose their way,

Wiener et al. make observations that shed light on why older people have more difficulty finding their car in a shopping mall's large parking lot if they exit the mall by a different door than they used to enter it (or follow directions involving an intersection if they approach the intersection from a different direction than the one used for learning them.) From their introduction:
Everyday navigation can be based on different strategies. The hippocampus plays a key role in cognitive map or place strategies that rely on allocentric processing, whereas the parietal cortex and striatal circuits are involved in route or response strategies...To test the hypothesis that cognitive aging not only results in a shift away from allocentric strategies but in a specific preference for beacon-based strategies, we developed a novel experimental paradigm: participants first learned a route along a number of intersections and were then asked to rejoin the original route approaching the intersections from different directions. Trials in which participants approached the intersections from a direction different from that during training (see Fig. 1) allowed us (1) to compare the use and adoption of route-learning strategies between young and older participants and (2) to test for specific preferences for beacon-based strategies in older participants.
The abstract:
Efficient spatial navigation requires not only accurate spatial knowledge but also the selection of appropriate strategies. Using a novel paradigm that allowed us to distinguish between beacon, associative cue, and place strategies, we investigated the effects of cognitive aging on the selection and adoption of navigation strategies in humans. Participants were required to rejoin a previously learned route encountered from an unfamiliar direction. Successful performance required the use of an allocentric place strategy, which was increasingly observed in young participants over six experimental sessions. In contrast, older participants, who were able to recall the route when approaching intersections from the same direction as during encoding, failed to use the correct place strategy when approaching intersections from novel directions. Instead, they continuously used a beacon strategy and showed no evidence of changing their behavior across the six sessions. Given that this bias was already apparent in the first experimental session, the inability to adopt the correct place strategy is not related to an inability to switch from a firmly established response strategy to an allocentric place strategy. Rather, and in line with previous research, age-related deficits in allocentric processing result in shifts in preferred navigation strategies and an overall bias for response strategies. The specific preference for a beacon strategy is discussed in the context of a possible dissociation between beacon-based and associative-cue-based response learning in the striatum, with the latter being more sensitive to age-related changes.

Thursday, April 11, 2013

Defining when a visual stimulus become conscious to us.

Llinás and collaborators do a nice dissection of our conscious versus unconscious visual processing and note the timing (240 milliseconds) of a brain signal that correlates with our conscious awareness of a stimulus. (This is the same time epoch that I evoke in the "millisecond manager" term I use in several of my essays in the left column of this blog - a period during which we can note the onset of a visual or emotional perception before further action or interpretation begins.)
At perceptual threshold, some stimuli are available for conscious access whereas others are not. Such threshold inputs are useful tools for investigating the events that separate conscious awareness from unconscious stimulus processing. Here, viewing unmasked, threshold-duration images was combined with recording magnetoencephalography to quantify differences among perceptual states, ranging from no awareness to ambiguity to robust perception. A four-choice scale was used to assess awareness: “didn’t see” (no awareness), “couldn’t identify” (awareness without identification), “unsure” (awareness with low certainty identification), and “sure” (awareness with high certainty identification). Stimulus-evoked neuromagnetic signals were grouped according to behavioral response choices. Three main cortical responses were elicited. The earliest response, peaking at ∼100 ms after stimulus presentation, showed no significant correlation with stimulus perception. A late response (∼290 ms) showed moderate correlation with stimulus awareness but could not adequately differentiate conscious access from its absence. By contrast, an intermediate response peaking at ∼240 ms was observed only for trials in which stimuli were consciously detected. That this signal was similar for all conditions in which awareness was reported is consistent with the hypothesis that conscious visual access is relatively sharply demarcated.

Wednesday, April 10, 2013

Your smartphone, your social brain, and your vagus nerve.

I am always struck, when I go a local Starbucks for my noon coffee or do a happy hour at a local bar, that the great majority of those present are staring intently at their smartphones or tablets, while sitting in an environment meant to encourage interaction. As we spend less and less time engaging in face to face positive social contact in public places, what are we losing? The increasing aversion to human contact exhibited by people addicted to staring at their small screens suggests that our social brain follows the same rule as the rest of our brain and body: "Use it or loose it." I've done a post pointing to how modern hi-tech dialog devices fail to engage the evolved brain and body synchronization that accompanies face-to-face dialog.

In a recent NYTimes piece, Barabara Fredricksen describes some of her recent work on countering the toxic effects of isolation from direction person-to-person contact. Some clips, to which I have added a few reference links:
My research team and I conducted a longitudinal field experiment on the effects of learning skills for cultivating warmer interpersonal connections in daily life. Half the participants, chosen at random, attended a six-week workshop on an ancient mind-training practice known as metta, or “lovingkindness,” that teaches participants to develop more warmth and tenderness toward themselves and others....We discovered that the meditators not only felt more upbeat and socially connected; but they also altered a key part of their cardiovascular system called vagal tone. Scientists used to think vagal tone was largely stable, like your height in adulthood. Our data show that this part of you is plastic, too, and altered by your social habits.
To appreciate why this matters, here’s a quick anatomy lesson. Your brain is tied to your heart by your vagus nerve. Subtle variations in your heart rate reveal the strength of this brain-heart connection, and as such, heart-rate variability provides an index of your vagal tone. By and large, the higher your vagal tone the better. It means your body is better able to regulate the internal systems that keep you healthy, like your cardiovascular, glucose and immune responses.
Beyond these health effects, the behavioral neuroscientist Stephen Porges has shown that vagal tone is central to things like facial expressivity and the ability to tune in to the frequency of the human voice. By increasing people’s vagal tone, we increase their capacity for connection, friendship and empathy.
In short, the more attuned to others you become, the healthier you become, and vice versa. This mutual influence also explains how a lack of positive social contact diminishes people. Your heart’s capacity for friendship also obeys the biological law of “use it or lose it.” If you don’t regularly exercise your ability to connect face to face, you’ll eventually find yourself lacking some of the basic biological capacity to do so.

Tuesday, April 09, 2013

Mindfulness training improves working memory and cognitive performance while reducing mind wandering.

Yet another study, by Mrazek et al., on the salutary effects of mindfulness:
Given that the ability to attend to a task without distraction underlies performance in a wide variety of contexts, training one’s ability to stay on task should result in a similarly broad enhancement of performance. In a randomized controlled investigation, we examined whether a 2-week mindfulness-training course would decrease mind wandering and improve cognitive performance. Mindfulness training improved both GRE reading-comprehension scores and working memory capacity while simultaneously reducing the occurrence of distracting thoughts during completion of the GRE and the measure of working memory. Improvements in performance following mindfulness training were mediated by reduced mind wandering among participants who were prone to distraction at pretesting. Our results suggest that cultivating mindfulness is an effective and efficient technique for improving cognitive function, with wide-reaching consequences.
(The GRE is the Graduate Record Examination meant to test cognitive capacity of graduate school applicants. Readers interested in the details of the experiment, performed on the usual batch of ~50 college undergraduates, can email me.)

Monday, April 08, 2013

Alteration of paralimbic self awareness circuits in behavioral addiction.

Changeux and collaborators look at the brain correlates of pathological gambling, evaluating whether addictions might occur because of a predisposition linked to abnormal functioning of a frontal circuitry associated with self awareness, preceding any use of drugs. Some clips:
The introduction of magnetoencephalography (MEG) has made it possible to study neural mechanisms even in deeper parts of the cortex with a high degree of temporal resolution in combination with a decent spatial resolution. This allows investigation of one of the major networks of the brain, the paralimbic interaction between the medial prefrontal/anterior cingulate (ACC) and medial parietal/posterior cingulate (PCC) cortices. This interaction has in several recent studies been associated with self-awareness.

Schematic representation of the medial cortical components of the paralimbic network of self-awareness. Schematic localization of the medial sources for MEG registration. Red, ACC; Blue, PCC.




They compared 14 pathological gamblers and 11 age- and sex-matched controls using a stop-signal task consisting of “go” and “nogo” trials. In go trials, the participant is instructed to press a button as soon as an “O” appears on the screen. In nogo trials, the O is followed by an “X,” and the participant is instructed to withhold his response. The task can be used to measure a number of variables associated with impulsivity such as the stop-signal reaction time (SSRT), which is the time required for the stop signal to be processed so a response can be withheld. In particular, the SSRT has been widely used as a valid measure of impulsivity in general, and in studies of patients suffering from addiction.
The main finding of the present study was that behavioral addiction is linked to abnormal activity in, and communication between, nodal regions of the paralimbic network of self-awareness, the ACC and PCC, which are effective in different aspects of self-awareness processing. Pathological gamblers had lower synchronization between the ACC and PCC at rest in the high gamma band compared with controls, and failed to show an increase in gamma synchronization during rest compared with the task (as observed in controls). These findings could not be attributed to previous drug abuse or smoking habits. Furthermore, pathological gamblers without previous drug abuse had lower PCC power than controls and gamblers with previous stimulant abuse during the stop-signal task. In contrast, a history of stimulant abuse in gamblers caused a marked increase in power across regions and frequencies both at rest and during the stop-signal task.

Friday, April 05, 2013

Training our emotional brain - improving affective control.

Schweizer et al. suggest that our ability to keep a cool head in emotionally charged situations can be enhanced by working memory training, because both functions are associated with the same frontoparietal neural circuitry, including the dorsolateral prefrontal cortex (PFC), the inferior parietal and the anterior cingulate cortices, that can exert downregulatory effects on experienced emotional distress through projections to the amygdala and midbrain nuclei from the lateral and medial PFC components. Here is their abstract, followed by a description of the emotional working memory (not regular working memory) training that was evaluated.
Affective cognitive control capacity (e.g., the ability to regulate emotions or manipulate emotional material in the service of task goals) is associated with professional and interpersonal success. Impoverished affective control, by contrast, characterizes many neuropsychiatric disorders. Insights from neuroscience indicate that affective cognitive control relies on the same frontoparietal neural circuitry as working memory (WM) tasks, which suggests that systematic WM training, performed in an emotional context, has the potential to augment affective control. Here we show, using behavioral and fMRI measures, that 20 d of training on a novel emotional WM protocol successfully enhanced the efficiency of this frontoparietal demand network. Critically, compared with placebo training, emotional WM training also accrued transfer benefits to a “gold standard” measure of affective cognitive control–emotion regulation. These emotion regulation gains were associated with greater activity in the targeted frontoparietal demand network along with other brain regions implicated in affective control, notably the subgenual anterior cingulate cortex. The results have important implications for the utility of WM training in clinical, prevention, and occupational settings.
A description of the training:
The emotional working memory training... comprised an affective dual n-back task consisting of a series of trials each of which simultaneously presented a face (for 500 ms) on a 4 × 4 grid on a monitor and a word (for 500–950 ms) over headphones. Each picture-word pair was followed by a 2500 ms interval during which participants responded via button press if either/both stimuli from the pair matched the corresponding stimuli presented n positions back; 60% of the words (e.g., evil, rape) and faces (fearful, angry, sad, or disgusted expressions) were emotionally negative with the others affectively neutral in tone. Trial presentation order was randomized across training sessions.

Thursday, April 04, 2013

Impersonating your younger self makes your body physiologically younger - a rediscovered post.

For several years I've been trying to find or recall a MindBlog post or an article read, and couldn't come up with it. A blog reader sent an email recalling it, and I couldn't find it. FINALLY, on doing a string search in this blog (for 'mindfulness') I found it, an August 2010 post that I had given the misleading title of "The Psychology of Possibility." It referenced an article in Harvard Magazine on the work of Ellen Langer (1,2,3). Some of her early work is fascinating, and the post is worth repeating here:

An interesting article in the Harvard Magazine describes the life work of Ellen Langer, her demonstrations that our social self image (old versus young, for example) strongly patterns our actual vitality and physiology, her work on Mindfulness, unconscious processing, etc. I recommend that you read the article. Here are some clips from its beginning that hooked me (I actually did my own mini-repeat of the experiment described, a simple self-experiment of pretending that I had been transported back in time to 40 years ago, and convinced myself I was experiencing some of the effects described)...
In 1981, early in her career at Harvard, Ellen Langer and her colleagues piled two groups of men in their seventies and eighties into vans, drove them two hours north to a sprawling old monastery in New Hampshire, and dropped them off 22 years earlier, in 1959. The group who went first stayed for one week and were asked to pretend they were young men, once again living in the 1950s. The second group, who arrived the week afterward, were told to stay in the present and simply reminisce about that era. Both groups were surrounded by mid-century mementos—1950s issues of Life magazine and the Saturday Evening Post, a black-and-white television, a vintage radio—and they discussed the events of the time: the launch of the first U.S. satellite, Castro’s victory ride into Havana, Nikita Khrushchev and the need for bomb shelters.

...Before and after the experiment, both groups of men took a battery of cognitive and physical tests, and after just one week, there were dramatic positive changes across the board. Both groups were stronger and more flexible. Height, weight, gait, posture, hearing, vision—even their performance on intelligence tests had improved. Their joints were more flexible, their shoulders wider, their fingers not only more agile, but longer and less gnarled by arthritis. But the men who had acted as if they were actually back in 1959 showed significantly more improvement. Those who had impersonated younger men seemed to have bodies that actually were younger.

Wednesday, April 03, 2013

Do we need an Apollo moon project for the brain?

I have collected a sampling of the many commentaries on the Brain Activity Map project to which Barack Obama alluded in his State of the Union address which is becoming a high profile 3-billion dollar endeavor. For a few examples, see the NYTimes, The Altantic, and Plos Blogs. I finally want to put in my two cents worth to say that such an effort is completely misguided. But first, clips from a Science article contributed by 'big science' luminaries who would profit from such a project.
...the mechanisms of perception, cognition, and action remain mysterious because they emerge from the real-time interactions of large sets of neurons in densely interconnected, widespread neural circuits. It is time for a large-scale effort in neuroscience to create and apply a new generation of tools to enable the functional mapping and control of neural activity in brains with cellular and millisecond resolution...This initiative, the Brain Activity Map (BAM), could put neuroscientists in a position to understand how the brain produces perception, action, memories, thoughts, and consciousness
The last phrase, in particular, is borderline delusional. As John Horgan points out, we don't even see the side of the barn yet. Apart from the fact that we don’t know what to include in a simulation and what to leave out, we already have conclusive evidence that a search for a road map of stable neural pathways that can represent brain functions is futile. Edited from Horgan:
...the brain is radically unlike and more complex than any existing computer. A typical brain contains 100 billion cells, and each cell is linked via synapses to as many as 100,000 others. Synapses are awash in neurotransmitters, hormones, modulatory peptide (small proteins), neural-growth factors and other chemicals that affect the transmission of signals, and synapses constantly form and dissolve, weaken and strengthen, in response to new experiences...not only do old brain cells die, new ones can form via neurogenesis...many genes are constantly turning on and off and thereby further altering operations of brain nerve cells...the brain may be processing information at many levels below and above that of individual neurons and synapses...each individual neuron, rather than resembling a transistor, maybe be more like a computer in its own right, engaging in complex information-processing.
I fear that these big, much-hyped initiatives will turn out to be as disappointing as the Decade of the Brain. Rather than boosting the status of neuroscience, they may harm its credibility.
A particularly telling story comes from my long time friend and colleague Tony Stretton at the University of Wisconsin, who studies the very simple nervous system of the parasitic nematode Ascaaris suum, that has only 298 neurons, for which a functional circuit from the morphological synapses, scored by electron microscopy, has been obtained. This is just the sort of information the Brain Activity Map project is trying to obtain for our brains. So, do we know how the Ascaris nervous system works? No, we're not even close, because Stretton has discovered that their are numerous peptides (as many as 250) that modulate the activity of neurons. Go figure how neurons in that complex modulatory soup work!! And multiply the problem by at least a billion for our brains.

To be fair, the vigorous discussion over the merits of a big push has led, as Markoff and Gorman describe in the NYTimes, to cast the enterprise as trying to better define the playing field, rather than assuming that we now know what it is.  

Tuesday, April 02, 2013

A next generation of antidepressants?

Russo and Charney do a brief write up on recent work of Nasca et al., who find that a common dietary supplement, L-acetylcarnitine, is a potential rapidly acting antidepressant:
Over the past 50 y, there have been few mechanistically distinct drugs for the treatment of major depressive disorders, despite the fact that nearly two-thirds of patients do not achieve full remission of symptoms on currently available antidepressants. In addition, even when adequate remission is achieved, patients require 2–4 wk of treatment before any significant effects, increasing the risk for complications, such as suicide. This delay in effectiveness has resulted in a major push to identify and develop novel therapeutics with more rapid effects. The recent identification of ketamine as a rapid antidepressant effective in treatment-resistant patients has been groundbreaking.
Nasca et al.  describe in PNAS a unique potential rapidly acting antidepressant, l-acetylcarnitine (LAC), which is a dietary supplement that acts by acetylating protein targets to control their function. LAC is reported to be well tolerated and can readily cross the blood-brain barrier. A recent study suggests it has promise in the treatment of Parkinson disease because of its neroprotective properties. Strikingly, LAC exhibits antidepressant efficacy within 2–3 d following intraperitoneal administration in rodents, compared with 2–3 wk with a standard antidepressant treatment, such as chlorimipramine. Although LAC is relatively nonspecific and can target many biological pathways, it is suggested by Nasca et al.  to promote rapid antidepressant responses by acetylation of histone proteins that control the transcription of BDNF and metabotropic glutamate 2 (mGlu2) receptors in the hippocampus (Hipp) and prefrontal cortex (PFC).
One of the more impressive aspects of this article is that Nasca et al. verify rapid antidepressant efficacy of LAC in both a genetic rat model of susceptibility [Flinders Sensitive Line (FSL)] and following chronic stress exposure, factors that are thought to be the primary cause of depression in humans. Although there is clearly far more work necessary to understand the mechanisms of antidepressant action of LAC in rodents, and the dose and relative safety profile for depression treatment in humans, these exciting results are a first step toward that goal.