Cognitive Processing – Michael Halassa | Science

The Quiet War Between Abstraction and Detail

michaelhalassa — Mon, 16 Mar 2026 22:31:52 +0000

Every time you walk into a new restaurant, your brain solves an invisible problem: Which parts of this experience are specific to this place (the menu, the layout, the staff) and which parts are general rules you can transfer (how to order, where to sit, when to pay)? Extract too much shared structure and you’ll confidently walk to the wrong counter. Protect too many specific details and you’ll fumble through every new restaurant like it’s your first.

This balance, between learning patterns that transfer and preserving details that matter, appears fundamental to how we navigate a world where some things repeat (traffic patterns, social norms, the physics of thrown objects) and some things are unique (this particular intersection floods, this friend needs space when upset, this specific mushroom will kill you).

The capacity for structural learning, extracting regularities that apply across situations, may be one of the defining features of human cognition. When a child learns that adding “ed” creates past tense, they’ve discovered a rule that applies to thousands of verbs they’ve never encountered. When you recognize that a new coworker uses the same conflict-avoidant communication style as your sibling, you’ve extracted a pattern that predicts future interactions. The alternative, learning every situation as a unique instance requiring its own solution, would be computationally intractable.

But structural learning creates a fundamental tension. The same cognitive machinery that lets you rapidly transfer knowledge to new situations may overwrite what you learned before. Learn French after Spanish and you might start mixing verb conjugations. Update your mental model of how your boss communicates and you might misremember what they actually said last month. The brain must somehow balance the benefits of generalization against the risk of interference.

A Task That Makes Strategies Visible

A new paper in Nature Human Behaviour by Eleanor Holton, Chris Summerfield, and colleagues has developed an elegant way to observe these competing strategies in action. The design is deceptively simple: participants learned to map fictional plants to locations on a circular planet, with separate locations for summer and winter. The key structural feature is that within each set of plants, there was a consistent angular rule. Winter locations were always a fixed offset from summer locations (say, 120 degrees clockwise).

Participants first learned one set of six plants (Task A) over ten repetitions.

Then they encountered six entirely new plants (Task B) with their own summer-winter rule, either identical to Task A, shifted by 30 degrees, or rotated 180 degrees.

After learning Task B, they returned to the original Task A plants, but this time received feedback only for summer locations. This allowed the team to observe what rule participants spontaneously applied when retested.

The experimental design cleverly separates two phenomena that usually travel together. Transfer refers to how much knowledge of rule A accelerates learning of rule B. If you immediately apply the 120-degree rule to new plants, your initial performance on Task B should be good (when the rule is similar) or systematically biased (when the rule differs). Interference refers to whether learning rule B corrupts your memory of rule A. When retested on the original plants, do you still apply rule A correctly, or do you now mistakenly use rule B?

In most learning paradigms, these processes are confounded. Here, the structure makes different algorithmic strategies visible through their distinct signatures across transfer and interference conditions.

Heterogeneity Hidden Beneath Averaged Performance

There are many interesting things about this paper (and some things that require taking with a grain of salt that I will point out in due course), but one big takeaway is how well individual differences in strategy choice was revealed by this work.

If you average across all participants (which many people routinely do), behavior would almost certainly appear to be relatively uniform. This is because people learn both tasks to high accuracy. Mean performance in Task B appears similar across individuals.

But beneath this averaged regularity lies what appears to be substantial heterogeneity in how people solve the task. This becomes most visible when the rules are similar enough to create genuine ambiguity (the 30-degree shift condition, though patterns may exist in the far condition too). The Near condition participants seem to split into two distinct behavioral profiles:

Some participants (called “lumpers”) showed high transfer but high interference. They immediately benefited from rule A when learning rule B, suggesting they were applying the previous rule to new stimuli. But when retested on task A, they were more likely to apply rule B, apparently overwriting their memory of the original rule.

Other participants (“splitters”) showed the opposite pattern: low transfer but low interference. They treated task B as effectively novel, gaining little immediate advantage from prior learning, and made many more mistakes upon transitioning (higher switching cost). But they maintained rule A better at retest, showing no contamination from the recently learned rule B.

This dissociation extended across multiple behavioral measures beyond the primary transfer and interference metrics. Lumpers appeared to generalize the rule better to held-out stimuli they’d never received feedback on, applying the angular relationship to infer correct responses. But they performed worse on memory for unique stimulus features, specifically the summer locations that had to be memorized rather than inferred from a rule. Splitters showed what looks like the mirror pattern: better memory for unique features, poorer rule-based generalization.

The groups even differed on explicit temporal memory tested at the end of the experiment. Splitters were better at reporting which half of the study they’d first encountered each stimulus in, as if they maintained more distinct representations of the two task contexts.

These differences appear to reflect distinct computational strategies rather than differences in overall ability. Splitters actually outperformed lumpers on some measures (the unique feature memory). Both groups achieved high final accuracy. These look like fundamentally different approaches to solving the same problem, each with complementary strengths and opposite vulnerability profiles.

An important unresolved question is whether these represent stable individual traits or context-dependent strategies. Does someone who lumps in this task lump everywhere? Or do people flexibly shift between strategies based on task structure, recent experience, or environmental statistics? The study design can’t answer this, and it’s a genuinely significant open issue for understanding what these behavioral patterns mean.

Formalizing the Trade-off Through Neural Networks

One of the interesting aspects of this work (and Summerfield’s work more generally) is the use of AI architectures to gain insight into the human mind (and sometimes the brain too).

In this study, the authors used a surprisingly simple neural architecture, a two-layered feedforward network to make some inferences about individual differences in cognitive strategy usage. By manipulating the scale of initial weights, the authors could guide networks toward “rich” (small initial weights leading to structured, low-dimensional representations) or “lazy” (large initial weights leading to high-dimensional, task-agnostic representations) learning regimes.

Networks in the rich regime captured what looks like the lumper behavioral profile: high transfer to Task B, high interference when retested on Task A, strong rule generalization to held-out stimuli, poor unique feature memory, and collapsed representations of the two tasks in neural space (measured via principal angles between task subspaces).

Networks in the lazy regime mirrored what appears to be the splitter pattern on every measure: low transfer, low interference, poor generalization, better unique feature memory, and maintenance of orthogonal representations for the two tasks.

This computational modeling makes the underlying trade-off explicit. Low-dimensional structured representations might enable efficient generalization by extracting shared rules, but precisely because representations are shared across tasks, new learning could overwrite old knowledge. High-dimensional representations might maintain separability between tasks, protecting against interference, but at the potential cost of failing to extract transferable structure.

The value of this modeling approach is that it formalizes what could otherwise remain a vague intuition about competing strategies. The networks make testable predictions: if someone shows high interference, they should also show better generalization within tasks. If they maintain orthogonal task representations, they should show poor transfer but preserved memory.

But we need to be careful about how far we extend the analogy. Having interacted with many humans, I can confirm that none are a two-layered neural networks trained via gradient descent on a single task. How people implement rapid learning likely involves multiple interacting brain systems: prefrontal cortex implementing gating policies that determine when to update versus maintain representations, hippocampus providing rapid contextualization that could separate task episodes, thalamocortical circuits routing information through different processing channels based on task demands. Our behavior, as individuals, probably emerges from how each of our systems interact and are weighted together, something like a mixture of experts where different computational solutions contribute to the final output. Also, the rich and lazy networks are unlikely to describe individual neural systems wholesale, instead, they demonstrate a computational principle that illustrate the trade-off at work (although who knows, maybe each of our brains has a mixture of these principles at work).

The neural network analysis also reveals something interesting about task similarity and strategy visibility. In the Same condition (where both tasks use identical rules), the distinction between lumpers and splitters may not matter much. Everyone can apply the same rule to new stimuli without cost. In the Far condition (180-degree shift), the rules are different enough that most people might naturally treat them as separate tasks, though there may still be some heterogeneity that’s less pronounced. It’s in the Near condition (30-degree shift) where the ambiguity forces different strategies into stark relief, creating the bimodal distribution.

This suggests that algorithmic heterogeneity in how people approach learning might be widespread but often invisible, only becoming apparent when task structure creates the right conditions to pull different strategies apart.

Environmental Contingency and the Absence of a Single Optimal Strategy

The environmental context matters critically for which strategy succeeds. Lumping might dominate when the world has stable structure worth extracting. If rules genuinely repeat across contexts, you learn faster by recognizing and applying patterns. The cost of occasional interference could be outweighed by the acceleration in learning new tasks that share structure with old ones.

Splitting might win when rules change frequently or when maintaining distinct memories is crucial. If what you learned before is often misleading rather than helpful, protecting each memory from contamination becomes more valuable than speed of transfer. The cost of slow learning could be justified by the accuracy of what you retain.

There may be no single “correct” strategy. The optimal approach likely depends on the statistics of the environment you’re navigating. A world with high regularity and stable rules rewards generalization. A world with frequent rule changes or high context-specificity rewards separation and protection of distinct memories. There is also the possibility that luck plays a role; what you just encountered may predispose you to lump or split depending on how successful you just were.

This raises an interesting possibility about cognitive diversity. Rather than representing noise around some ideal cognitive architecture, the coexistence of lumpers and splitters might reflect adaptation to environmental variability. A population containing both strategies might outperform a homogeneous population, with pattern-extractors thriving in stable domains and detail-preservers succeeding in volatile ones. Different algorithmic profiles suited to different ecological niches.

This interpretation is speculative, but it suggests we might want to think about individual differences in learning strategies as positions on a trade-off curve that evolution or development has explored.

Relevance for Understanding Disorders

This level of behavioral dissection seems important for understanding psychiatric heterogeneity. If we only measured final task accuracy, lumpers and splitters would be indistinguishable. Standard neuropsychological testing focused on whether performance is intact or impaired would miss this entirely. It’s only by examining the pattern of performance across multiple measures (transfer, interference, generalization, unique feature memory, temporal context) that the different strategies become visible.

This has potentially important implications for how we study psychiatric conditions. Consider what we know about cognitive function in schizophrenia. Working memory deficits are consistently documented. Counterfactual reasoning appears impaired. Context processing shows abnormalities. But we typically describe these as simple deficits, performance falling below some normative threshold.

What if some of this heterogeneity reflects people navigating trade-offs differently, perhaps forced toward one extreme by underlying capacity constraints? Someone with severe working memory limitations might be pushed toward splitting strategies, unable to maintain the flexible representations needed for successful generalization. Alternatively, they might be pushed toward excessive lumping, overgeneralizing because they can’t maintain distinct context representations. Or the computational machinery for balancing these strategies might be disrupted in ways that don’t map onto the healthy spectrum at all.

Without tasks that can behaviorally dissect these possibilities, separating transfer from interference, generalization from discrimination, rule application from memory for specifics, we can’t distinguish these accounts. We end up with general statements about “cognitive deficits” when we should be asking about specific algorithmic profiles and how they interact with task demands.

The implications here concern the level of analysis we need. Detailed statistics of behavior, comparison to normative computational models when available, careful dissection of performance patterns across conditions that pull different strategies apart.

And we should remember the limitations of the analogy: people aren’t one big neural network. Multiple brain systems (prefrontal gating, hippocampal context coding, thalamic routing) likely contribute to how we handle sequential learning. These computational principles might illuminate trade-offs and formalize what behavioral patterns we should look for, but the implementation almost certainly involves coordination across systems rather than a single learning mechanism. The behavioral signature we observe is likely the weighted output of this complex architecture.

Emphasis on Methodological Insight

The methodological contribution here may be as important as the empirical findings. Averaged behavior can look normal, even optimal, while masking fundamentally different computational strategies operating beneath the surface. Standard cognitive assessments can show intact performance while missing the algorithmic heterogeneity that might matter for understanding vulnerability, predicting treatment response, or matching individuals to environments.

The sequential learning paradigm with separate measures of transfer and interference provides one example of how to pull these strategies apart. The neural network modeling provides a formal framework for understanding what different patterns of performance might mean. The combination suggests a path forward for computational psychiatry that goes beyond asking whether performance is impaired.

The next generation of this work might ask: Which specific algorithmic trade-offs are being navigated differently? What behavioral signatures reveal underlying strategy? How do these computational profiles interact with environmental demands? When does being a lumper become maladaptive, and when does being a splitter limit learning?

The demonstration that careful behavioral dissection can reveal hidden heterogeneity in how people learn suggests we might be missing similar structure in other domains by averaging too quickly and testing too coarsely.

Synthesis: What We Learn About Learning

The capacity to abstract while preserving details represents a fundamental computational challenge for any learning system, biological or artificial. The tension appears intrinsic to intelligence itself.

What optimal looks like depends entirely on environmental structure. Stable worlds with repeating patterns reward those who extract and apply rules quickly. Volatile worlds where yesterday’s pattern misleads today reward those who maintain distinct memories and avoid overgeneralization. The problem itself changes based on context, making any single solution inadequate.

This has profound implications for how we think about cognitive diversity. Individual differences in learning strategies might represent different positions on a fundamental trade-off curve, possibly shaped by recent experience, current capacity constraints, or the statistics of environments people have navigated. Cognitive styles might reflect computational strategies. Apparent deficits might be extreme positions on trade-offs that have no objectively correct answer.

The biological implementation is almost certainly a weighted mixture of multiple brain systems coordinating to produce the behavior we observe. Disruption might affect these systems differently, push trade-offs toward extremes, or create computational patterns that don’t exist in healthy populations at all.

The brain’s solution to the quiet war between abstraction and detail appears to be “it depends on the brain and it depends on the world.” Understanding both dependencies seems necessary for making sense of how learning works, why it sometimes fails, and what interventions might actually help.

Work like this only matters if it reaches people wondering about these questions. If you found value here, consider sharing it with your community. Subscribe to michaelhalassa.substack.com if you want to see where this type of thinking and analysis goes.

The Currency of the Mind

michaelhalassa — Mon, 16 Mar 2026 22:22:43 +0000

How the brain constructs the values that guide everyday decisions reveals one of neuroscience’s most fascinating puzzles. Think about it: your brain adds and subtracts quantities that share no common unit! It can add morning light through kitchen windows to forty minutes in traffic, subtract image and status from a car’s reliability and comfort. These things exist in completely different dimensions (light, time, dollars, social signals) yet somehow the brain is constantly adding and subtracting them when making decisions.

Let’s take buying a home as a concrete example. On paper it looks like a financial transaction, but in practice it’s a clash of incomparable currencies. Square footage gets weighed against school districts, the energy of a neighborhood against the stability of an investment. Walk through one house and you can already imagine your life there, until you realize it means your partner endures an extra hour of daily commute. Somewhere in this mix of clear measurements and ones that are hard to describe, the brain assembles a decision.

To make matters more complicated, think about how volatile our internal value estimates can be. During COVID, when daily commutes vanished, the value of space ballooned, potentially trumping distance; the same house that once felt impractical now seemed like a refuge. A new context can make ostensibly identical attributes exhibit radically different valuations.

The types of contextual changes that shift valuation are also themselves diverse. A genuine Monet may sell for $70 million. A forgery, indistinguishable to the eye and identical to anyone but the equipment of an art authenticator, might fetch $5,000. Same paint, same canvas, same aesthetic experience. Yet the (inferred) backstory behind it transforms its value by four orders of magnitude.

This is the computational puzzle at the heart of value-based decision-making: how does the brain make incomparable things comparable? What neural mechanism allows attributes measured in completely different dimensions (light, time, dollars, authenticity) to compete on the same playing field? And how does this mechanism remain stable enough to produce coherent choices yet flexible enough to radically reweight those same attributes when context shifts?

From the Wall Street Journal. Read the story here

The Construction of Value

Here’s the truth: we don’t really understand how this problem is solved. The question of how brains integrate diverse attributes into unified decisions remains one of the deep mysteries in neuroscience. Ultimately, the answer will likely come in cognitive and neural forms; two faces of the same computational coin. These perspectives will jointly explain the magic of turning morning light into a quantity that can be compared with commute time.

Despite the lack of a satisfying single narrative, we do know some fascinating pieces of the puzzle. Let’s start with what psychology has revealed about how value gets constructed.

One of the most striking findings is that arbitrary starting points can anchor our entire valuation system. Dan Ariely and colleagues demonstrated this by asking students to write down the last two digits of their Social Security number before bidding on items like wine, chocolate, and computer accessories. Students with Social Security numbers ending in 80-99 bid nearly three times more than those with numbers ending in 00-19. For a cordless keyboard, high-number students offered $56 while low-number students offered just $16. The same pattern held across all items. The initial number, though completely unrelated to the products’ worth, set an implicit scale that influenced all subsequent valuations. Once the brain latches onto a reference point, even a meaningless one, it builds an internally consistent preference structure around it.

Beyond arbitrary anchors, our sense of ownership profoundly alters how we value objects. In experiments by Kahneman, Knetsch, and Thaler, students were randomly given coffee mugs and then asked to name their selling price. These new “owners” demanded about $7 to part with their mugs, while students without mugs were only willing to pay about $3 to acquire one. The mug itself hadn’t changed. What changed was the relationship: once something becomes “mine,” its value doubles in my eyes. Norton, Mochon, and Ariely extended this finding by having people assemble IKEA furniture or fold origami cranes. Participants valued their own creations at nearly the same price as expert-made versions, even when their handiwork was visibly inferior. The act of creation adds a new attribute to the value calculation: the effort invested becomes part of what we’re evaluating, not just the object itself.

Even memory rewrites value. Daniel Kahneman and Donald Redelmeier studied patients undergoing colonoscopies. Some patients had longer procedures that ended less painfully, others had shorter ones that ended abruptly at peak pain. Counterintuitively, patients preferred the longer procedures. Their memories followed the “peak-end rule”: they judged the whole experience not by its average pain but by its worst moment and how it ended (Redelmeier & Kahneman, 1996). How we remember an experience, not the experience itself, determines how we’ll value similar choices in the future.

And value is deeply social. In a massive online experiment, Matthew Salganik and colleagues (2006) created artificial “music markets.” When download counts were hidden, songs rose or fell on their own. But when popularity information was visible, some songs snowballed into “hits” while others languished, even though the songs were the same across markets. Popularity itself became an attribute folded into value, warping what people genuinely preferred.

Daniel Kahneman: A most incredible thinker and contributor to the science of decision making (also a Nobel Laureate)

The Computational Challenge

If value is constructed rather than retrieved from a fixed look-up table, what exactly is the brain computing? Consider what components must somehow become commensurable:

Sensory attributes: The warmth of sunlight, the bitterness of coffee, the smoothness of silk. These arrive in different neural codes from different sensory systems, yet must be integrated into unified preferences.

Abstract properties: Distance (20 minutes), quantity (800 square feet), probability (70% chance). The brain lacks sensory receptors for these dimensions, yet they powerfully shape value.

Social signals: Status, belonging, reputation. That Monet carries social meaning that a forgery doesn’t. A Harvard degree signals something another school may not. These intangible attributes somehow get converted into the same currency as tangible ones.

Temporal projections: Future pleasure, anticipated regret, imagined satisfaction. The brain must evaluate things that haven’t happened yet, experiences it can only simulate.

Effort and ownership: The IKEA table you assembled, the garden you planted, the thesis you wrote. Investment of effort literally changes the computed value, as if the brain adds your labor to the object’s attributes.

Comparison context: The same option valued differently depending on what else is available. That $2,500 apartment seems expensive or cheap depending entirely on the alternatives, even irrelevant ones.

The remarkable thing is that the brain somehow integrates these components despite their fundamental incomparability. One prominent theory suggests the brain converts everything into a “common currency”; perhaps the firing rates (or patterns) of neurons in valuation regions. But how does social status get converted into the same neural code as commute time? What algorithm transforms the warmth of sunlight into the same units as financial security? Even if there is a common currency at the point of decision, the translation process remains mysterious. When you’re choosing between jobs or homes or life partners, all these incomparable attributes must somehow become comparable. One option just feels better.

How does the brain perform this translation and integration? That’s what the neural machinery must somehow accomplish.

The Neural Implementation

If value is constructed, where in the brain does this happen, and in what format? Researchers often divide into two camps. One view is that the brain collapses everything into a single “common currency,” a scalar signal that can be compared across apples, Monets, and commutes. The other is that value is represented in a richer, multidimensional code, more like a map of attributes than a single number, with scalar readouts emerging only when a choice is required. The best available evidence points to the orbitofrontal cortex (OFC) and the adjacent ventromedial prefrontal cortex (vmPFC) as being central to these computations.

OFC and vmPFC: a value map with scalar readouts

Work in macaques by Camillo Padoa-Schioppa and colleagues showed that OFC neurons encode subjective value in a way that is “menu invariant,” meaning the value signal for one option stays stable regardless of what it is paired against (Padoa-Schioppa & Assad, 2006). This stability supports transitive choice: if juice A is valued more than B, and B more than C, then A will be valued more than C. Human neuroimaging extends this by showing vmPFC activity tracks subjective value across many domains, including money, food, and social approval (Chib et al., 2009; Bartra et al., 2013).

However, newer analyses suggest the OFC does not simply produce one number. Instead, its population activity preserves multiple dimensions of value, such as taste versus health or probability versus magnitude (Schuck et al., 2016; Hunt & Hayden, 2017). In this view, the OFC is a “map-maker,” maintaining a structured representation of options that can be flexibly reweighted depending on context. Scalar value signals may still emerge, but only as a projection of this richer map.

Figure 1 of Moneta et al., 2024 Trends in Neuroscience.

The role of dorsal prefrontal regions: shaping and acting on value

Other prefrontal areas contribute in complementary ways. The dorsolateral prefrontal cortex (dlPFC), which is heavily involved in executive control, appears to adjust the weights assigned to different attributes. When people are instructed to prioritize health over taste, dlPFC activity reflects health information more strongly, and when told to focus on taste it reflects taste (Hare et al., 2009). Under certain conditions, the dlPFC may determine which dimensions of the map matter in a given context.

The dorsal anterior cingulate cortex (dACC), which monitors conflict and effort, often signals the difficulty or cost of a decision. Because it connects closely to premotor regions, it is well placed to bind abstract values to concrete actions. In challenging or effortful choices, dACC appears to integrate both the value of options and the anticipated cost of exerting control (Shenhav et al., 2013, Neuron).

A distributed system

The emerging picture is that value does not reside in a single place or a single format. The OFC and vmPFC maintain a flexible, map-like code of options. dlPFC helps determine which axes of that map to emphasize. dACC translates the chosen value into action, especially when the choice is close or costly. Striatal circuits and dopamine signals supply the learning machinery that updates the map when outcomes deviate from expectations.

Understanding this distributed system may ultimately reconcile the debate between scalar and map-like coding. The brain can preserve a rich geometry of attributes while also collapsing them into a scalar readout when a choice demands it. That dual capacity may be the key to how incomparable things become comparable.

Broader Implications

Understanding value as construction rather than retrieval has implications beyond individual choice. It might explain why the same economic conditions feel catastrophic or manageable depending on narrative framing. Why social media can shift entire populations’ valuation of political candidates through selective attribute highlighting. Why depression involves not just sadness but a fundamental inability to construct positive value from available attributes. Why cultural differences in what matters, individual achievement versus group harmony, lead to genuinely different experiences of the same situations.

The framework suggests that many societal conflicts aren’t really about different goals but about different attribute weightings. The same policy gets valued completely differently depending on whether you weigh “personal freedom” or “collective safety” more heavily. The same scientific finding gets valued differently depending on whether you weigh “economic growth” or “environmental protection.” Instead of viewing these as failures of rationality, an opposing view can be simply a different construction stemming from different weightings.

The Mystery of Value

We started with a puzzle: how does your brain weigh the comfort of a home’s interior against commute distance, nearby amenities against your spouse’s preferences? How do incomparable attributes become comparable values?

The evidence points toward construction rather than retrieval from a look-up table. Ariely’s anchoring studies show that random numbers shape our valuations. The endowment effect reveals that ownership doubles perceived worth. The peak-end rule demonstrates that certain details of memory encoding determine future value. Eye-tracking shows that attention creates preference. The Monet example shows that authentication can change value by four orders of magnitude.

These phenomena make sense if the brain builds value from available attributes, weights them according to context and goals, and compares through some form of competition. The neural data provides pieces: OFC/vmPFC may house a flexible map-like code that may be collapsed to a common currency scalar value for comparison. dlPFC circuitry may shape which axes of that map matter and dACC circuitry may read out the winning option in preparation for action.

But the core mystery remains. How does the brain actually perform the integration? What computation transforms sunshine through kitchen windows into a quantity that can be weighed against minutes of commute? How do narrative attributes like “painted by Monet himself” get converted into the same currency as visual beauty or investment potential?

The $70 million Monet shows how backstory can outweigh brushstrokes. What we don’t yet know is how the brain pulls off the trick of weighing sunlight against commute time, or authenticity against aesthetics. That algorithm remains one of neuroscience’s deepest mysteries.

If you enjoyed this piece, please consider subscribing to michaelhalassa.substack.com to follow along as I write about the brain, computation, and psychiatry. Some posts dive into the neuroscience of a particular mental phenomenon (like this one), while others deal with more clinically-relevant issues.

You can also share this post with a friend or colleague who might be curious about how our brains turn sunlight, stories, and symbols into value.

Bibliography:

Ariely, D., Loewenstein, G., & Prelec, D. (2003). “Coherent arbitrariness”: Stable demand curves without stable preferences. Quarterly Journal of Economics, 118(1), 73–106. https://doi.org/10.1162/00335530360535153

Bartra, O., McGuire, J. T., & Kable, J. W. (2013). The valuation system: A coordinate-based meta-analysis of BOLD fMRI experiments examining neural correlates of subjective value. NeuroImage, 76, 412–427. https://doi.org/10.1016/j.neuroimage.2013.02.063

Chib, V. S., Rangel, A., Shimojo, S., & O’Doherty, J. P. (2009). Evidence for a common representation of decision values for dissimilar goods in human ventromedial prefrontal cortex. Journal of Neuroscience, 29(39), 12315–12320. https://doi.org/10.1523/JNEUROSCI.2575-09.2009

Hare, T. A., Camerer, C. F., & Rangel, A. (2009). Self-control in decision-making involves modulation of the vmPFC valuation system. Science, 324(5927), 646–648. https://doi.org/10.1126/science.1168450

Hunt, L. T., & Hayden, B. Y. (2017). A distributed, hierarchical and recurrent framework for reward-based choice. Neuron, 96(2), 355–362. https://doi.org/10.1016/j.neuron.2017.09.031

Kahneman, D., Knetsch, J. L., & Thaler, R. H. (1991). Anomalies: The endowment effect, loss aversion, and status quo bias. Journal of Economic Perspectives, 5(1), 193–206. https://doi.org/10.1257/jep.5.1.193

Kaplan, R., & Friston, K. J. (2018). Planning and navigation as active inference. Biological Cybernetics, 112(4), 323–343. https://doi.org/10.1007/s00422-018-0753-2

Norton, M. I., Mochon, D., & Ariely, D. (2012). The IKEA effect: When labor leads to love. Journal of Consumer Psychology, 22(3), 453–460. https://doi.org/10.1016/j.jcps.2011.08.002

Padoa-Schioppa, C., & Assad, J. A. (2006). Neurons in the orbitofrontal cortex encode economic value. Nature Neuroscience, 9(3), 367–373. https://doi.org/10.1038/nn1726

Redelmeier, D. A., & Kahneman, D. (1996). Patients’ memories of painful medical treatments: Real-time and retrospective evaluations of two minimally invasive procedures. Pain, 66(1), 3–8. https://doi.org/10.1016/0304-3959(96)02994-6

Salganik, M. J., Dodds, P. S., & Watts, D. J. (2006). Experimental study of inequality and unpredictability in an artificial cultural market. Science, 311(5762), 854–856. https://doi.org/10.1126/science.1121066

Schuck, N. W., Cai, M. B., Wilson, R. C., & Niv, Y. (2016). Human orbitofrontal cortex represents a cognitive map of state space. Neuron, 91(6), 1402–1412. https://doi.org/10.1016/j.neuron.2016.08.019

Shenhav, A., Botvinick, M. M., & Cohen, J. D. (2013). The expected value of control: An integrative theory of anterior cingulate cortex function. Neuron, 79(2), 217–240. https://doi.org/10.1016/j.neuron.2013.07.007

The Next Chapter of AI: Leveraging the Evolutionary Principles Powering Human Intelligence

michaelhalassa — Thu, 17 Jul 2025 09:04:13 +0000

A mouse can explore a new environment, find food and adapt when the rules change, all using less energy than a lightbulb. Meanwhile, our most powerful computers can solve chess and master protein folding, but still can’t walk across a messy room without crashing into a chair.

This contrast reveals something profound about intelligence itself and where we need to go next. As we celebrate Geoffrey Hinton and John Hopfield’s recent Nobel Prize in Physics for their foundational work on neural networks, it’s the perfect time to ask: what’s the next chapter in understanding intelligence?

The Great Intelligence Paradox

We’re living through what some call the “Great Intelligence Paradox.” Our most advanced computational systems can master protein folding and beat world champions at Go, tasks that require incredible sophistication. But they’re surprisingly brittle when faced with the kind of flexible, real-world intelligence that any animal takes for granted.

Consider this: no machine can build a nest, forage for berries, or care for young. Today’s computational systems cannot compete with the sensorimotor capabilities of a four-year old child or even simple animals. The reason isn’t that we lack computational power. It’s that we’ve been approaching intelligence from a different angle.

As researcher Hans Moravec put it, abstract thought “is a new trick, perhaps less than 100 thousand years old, effective only because it is supported by this much older and much more powerful, though usually unconscious, sensorimotor knowledge.” In other words, when trying to capture natural intelligence, we’ve been focusing on the penthouse without first understanding the foundation.

The Deep History of NeuroAI: A 70-Year Symbiosis

This realization has sparked the emergence of NeuroAI, a field that recognizes something remarkable: evolution has already solved many of the problems we’re struggling with in artificial intelligence. But the connection between neuroscience and computing isn’t new. It can be traced to the very foundations of modern computer science itself.

John von Neumann’s seminal 1945 report outlining the first computer architecture (EDVAC) dedicated an entire chapter to discussing whether the proposed system was sufficiently brain-like. Remarkably, the only citation in this foundational document was to Warren McCulloch and Walter Pitts’ 1943 paper, widely considered the first work on neural networks. This early cross-pollination between neuroscience and computer science set the stage for decades of mutual inspiration.

The relationship deepened with Frank Rosenblatt’s introduction of the perceptron in 1958. The revolutionary idea here wasn’t just that machines could learn, but that they should learn from data rather than being explicitly programmed. Rosenblatt established synaptic connections as the primary locus of learning in artificial neural networks, a concept heavily influenced by Donald Hebb’s 1949 work highlighting the importance of the synapse as the physical basis of learning and memory.

This neuroscience-inspired principle that synapses are the plastic elements of neural networks has remained absolutely central to modern computation. Even when Marvin Minsky and Seymour Papert’s 1969 critique of perceptrons triggered the first “neural network winter,” the core insight persisted.

The symbiosis between artificial and biological neural network research has produced numerous breakthrough success stories. Perhaps the most celebrated is the convolutional neural network (CNN), which powers many of today’s most successful artificial vision systems. CNNs were directly inspired by David Hubel and Torsten Wiesel’s model of the visual cortex, work that earned them a Nobel Prize more than four decades ago.

Another home run is reinforcement learning, which has driven groundbreaking achievements including Google DeepMind’s AlphaZero and AlphaGo. The computational principles underlying these systems mirror the dopamine-mediated learning circuits in biological brains. When a monkey reaches for a reward and receives more than expected, dopamine neurons fire in patterns that precisely match the temporal difference learning algorithms used in these game-playing systems.

More recently, the concept of “dropout” has gained prominence in artificial neural networks. This technique, in which individual neurons are randomly deactivated during training to prevent overfitting, draws inspiration from the brain’s use of stochastic processes. By mimicking the occasional misfiring of neurons, dropout encourages networks to develop more robust and resilient representations.

Critically, this relationship is truly mutualistic, not parasitic. Computational advances have revolutionized neuroscience as much as neuroscience has inspired computation. Artificial neural networks now form the backbone of state-of-the-art models of the visual cortex. The success of these models in solving complex perceptual tasks has generated new hypotheses about how biological brains might perform similar computations.

Why Animals Are the Ultimate Intelligence Teachers

Instead of trying to replicate what makes humans special, we should look at what makes all animals successful. These are the capabilities that have been tested and refined over 500 million years of evolution.

This is where Tony Zador and his colleagues propose the “embodied Turing test.” The idea is straightforward but profound: instead of asking whether computation can fool us in conversation, we should ask whether an artificial beaver can build a dam as skillfully as a real one, or whether an artificial squirrel can navigate through trees with the same agility.

This shift in perspective reveals three crucial capabilities that current computational systems lack:

They Engage Their Environment

The defining feature of animals is their ability to move around and interact with their environment in purposeful ways. It’s about understanding how actions affect the world and using that understanding to achieve goals.

Consider the computational challenge this represents. When you watch a cat stalking prey, you’re witnessing real-time integration of visual tracking, motor prediction, uncertainty estimation, and action selection. The cat must predict the prey’s trajectory, estimate the optimal interception point, account for its own motor delays, and continuously update its strategy as the situation evolves. This requires what computational scientists call forward models, inverse models, and optimal control, all running simultaneously in a brain that weighs 30 grams.

Or take nest building in birds. A Baltimore oriole weaves together hundreds of individual grass fibers, each requiring precise motor control and spatial reasoning. The bird must estimate structural integrity in real-time, adapt to varying material properties, and maintain a global architectural plan while executing thousands of local actions. No current robotic system can approach this level of sensorimotor sophistication.

They Behave Flexibly

Animals are born with most of the skills needed to thrive or can rapidly acquire them from limited experience, thanks to their strong foundation in real-world interaction, courtesy of evolution and development. Unlike computational systems that catastrophically fail when encountering scenarios outside their training data, animals excel at handling novel situations by drawing on their general understanding of how the world works.

This flexibility emerges from what neuroscientists call compositional representation. Rather than memorizing specific stimulus-response patterns, animals build internal models of causal structure that can be recombined in novel ways. A squirrel encountering an unfamiliar tree can still navigate it by applying general principles of branch mechanics, gravity, and momentum.

Recent work by Rajalingham and colleagues has provided a striking demonstration of this principle. They trained monkeys to play “mental Pong,” where a ball disappeared behind a barrier and the animal had to predict where it would emerge. Neural recordings from the monkeys’ frontal cortex revealed that the brain was running a mental physics engine, maintaining an internal trajectory that matched physical reality even when the ball was invisible.

Even more remarkably, when computational systems were trained on the same task but required to infer the ball’s hidden path, they produced patterns of activity that mirrored the monkey frontal cortex. This suggests that both biological and artificial systems converge on similar computational solutions when solving similar problems, but biological systems achieve this with far greater efficiency and flexibility.

They Compute Efficiently

Here’s a staggering comparison that reveals the depth of the efficiency gap: training a large language model such as GPT-3 requires over 1000 megawatt-hours, enough electricity to power a small town for a day. The human brain uses about 20 watts, roughly the same as a bright light bulb.

This efficiency gap points to fundamentally different computational principles. Biological circuits operate in a regime where spikes are sparse and energy-efficient, using asynchronous communication protocols that bear little resemblance to the synchronous, dense matrix operations that characterize current computational systems.

The brain achieves this efficiency through several key innovations. First, it uses event-driven computation, where neurons only consume energy when they have something important to communicate. Second, it employs local learning rules that don’t require global coordination or backpropagation of error signals. Third, it multiplexes different types of information in the same circuits, allowing the same neural hardware to support multiple functions depending on context.

Recent advances in neuromorphic engineering are beginning to capture some of these principles. Intel’s Loihi chip and IBM’s TrueNorth processor implement spiking neural networks that dramatically reduce power consumption for certain tasks. But we’re still far from achieving the full computational elegance of biological systems.

Our Research: Natural Architectures for Cognitive Flexibility

This broader NeuroAI vision connects directly to collaborative research efforts my colleagues and I have been pursuing through the Thalamus Conte Center at Princeton. Working alongside talented investigators, we’ve been studying how thalamic circuits, particularly the mediodorsal thalamus, regulate uncertainty and cognitive flexibility.

The thalamus has long been thought of as a simple relay station, passively transferring information between brain regions. Our work reveals a far more sophisticated picture: the thalamus acts as a regulator of cortical representations, actively regulating the flow of information based on context, confidence, and computational demands.

Recent findings show that the mediodorsal thalamus exhibits distinct coding properties from prefrontal cortex. While prefrontal areas represent information in high-dimensional, mixed formats that can support many different behaviors, the thalamus compresses this information into lower-dimensional representations focused on key contextual variables like task rules and uncertainty estimates.

This architectural arrangement resembles what computational scientists call “regularization,” where a system constrains its processing to focus on the most relevant dimensions of a problem. The thalamus appears to provide this kind of regularization to prefrontal networks, helping them avoid getting lost in irrelevant details while maintaining the flexibility to handle novel situations.

This has direct implications for understanding psychiatric disorders. Schizophrenia, for instance, involves difficulties with cognitive flexibility and context processing. Our work suggests that these may reflect specific disruptions in thalamic computation rather than global deficits in learning or reasoning.

Understanding how evolution solved the uncertainty problem in biological brains could be the key to creating computational systems that are truly adaptive and robust in the face of novel situations. Current systems struggle precisely because they lack principled ways to handle uncertainty and adjust their confidence based on context.

The Road Ahead: From Lab to Life

The implications of this NeuroAI approach extend far beyond academic laboratories. The convergence of insights from biological intelligence and computational innovation points toward systems that could:

Adapt like animals: Robots that learn to navigate new environments with the flexibility of a mouse exploring new territory. Imagine search and rescue robots that can adapt to novel disaster scenarios, or autonomous vehicles that can handle completely unprecedented road conditions by drawing on fundamental principles of navigation and obstacle avoidance rather than memorized patterns.

Learn efficiently: Systems that acquire new skills from limited examples, like how animals quickly adapt to new food sources or threats. A key insight from biological learning is the importance of strong inductive biases, the built-in assumptions that help guide learning in the right direction. Animals don’t start from scratch; they leverage millions of years of evolutionary optimization.

Handle uncertainty gracefully: Systems that know when they don’t know, actively seeking information to improve their decisions rather than confidently making wrong choices. This requires implementing something like the thalamic uncertainty computation we’ve been studying, a principled way to calibrate confidence and adjust exploration strategies based on current knowledge state.

Integrate seamlessly: Computation that works alongside humans as naturally as animals coordinate in flocks or herds. This requires understanding not just individual intelligence but collective intelligence, how multiple agents can share information and coordinate actions without centralized control.

Recent experimental work provides concrete examples of how these principles might be implemented. Researchers at DeepMind have developed systems that can learn to play multiple Atari games using the same general-purpose algorithm, rather than requiring game-specific training. Their success comes from incorporating biological principles like replay (reactivating and reorganizing memories during rest) and curiosity-driven exploration.

Similarly, researchers at OpenAI have shown that large language models can exhibit emergent reasoning capabilities when scaled up, suggesting that some aspects of flexible intelligence might emerge from sufficient computational scale combined with appropriate architectural principles.

But perhaps the most promising developments come from robotics, where researchers are beginning to implement embodied learning principles. Boston Dynamics’ robots can navigate complex terrain and recover from perturbations in ways that would have been impossible just a few years ago. Their success comes from combining traditional control theory with machine learning approaches that can adapt to novel situations.

A New Kind of Intelligence

Building models that can pass the embodied Turing test requires more than tweaking existing algorithms. As Zador and colleagues argue, we need a “large-scale effort to identify and understand the principles of biological intelligence and abstract those for application in computer and robotic systems.”

Two key insights emerge from this challenge. First, intelligence isn’t about building internal representations—it’s about discovering affordances, the opportunities for action that emerge from the interaction between an agent and its environment. Second, animals don’t just learn; they develop, with their learning capabilities changing over time. Understanding how biological systems bootstrap from simple reflexes to sophisticated reasoning could transform how we build adaptive computational systems.

The convergence of neuroscience and computation offers concrete opportunities for progress. Animals solve computational problems that current systems struggle with, using principles refined over hundreds of millions of years of evolution. The mouse exploring a maze demonstrates flexible navigation, efficient learning from limited experience, and robust generalization. These capabilities emerge from biological circuits that balance exploration with exploitation, build and update internal maps, and adapt to novel situations.

Progress will require sustained collaboration between neuroscientists, computer scientists, and engineers. The questions are concrete: How do biological systems achieve such efficiency? What computational principles underlie adaptive behavior? How can we implement these in artificial systems?

Want to dive deeper into these ideas? Join us at CNS2025 in Florence, Italy (July 5-9, 2025) for our NeuroAI workshop, where we’ll explore how the convergence of neuroscience and computation is shaping the future of both fields. More details at cnsorg.org/cns-2025.

References

Zador, A., Escola, S., Richards, B., Ölveczky, B., Bengio, Y., Boahen, K., Botvinick, M., Chklovskii, D., Collins, A., Doya, K., Hassabis, D., Kording, K., Konidaris, G., Marblestone, A., Olshausen, B., Pouget, A., Sejnowski, T., Simoncelli, E., Solla, S., Sussillo, D., Tsao, D., & Tsodyks, M. (2023). Catalyzing next-generation Artificial Intelligence through NeuroAI. Nature Communications, 14, 1597. https://doi.org/10.1038/s41467-023-37180-x

Zador, A. (2024). NeuroAI: A field born from the symbiosis between neuroscience and computation. The Transmitter. https://www.thetransmitter.org/neuroai/neuroai-a-field-born-from-the-symbiosis-between-neuroscience-ai/

Rajalingham, R., Sohn, H. & Jazayeri, M. (2025). Dynamic tracking of objects in the macaque dorsomedial frontal cortex. Nature Communications, 16, 346. https://doi.org/10.1038/s41467-024-54688-y

Thalamus Conte Center. (2024). Princeton University. https://conte.thalamus.princeton.edu/

Hubel, D. H., & Wiesel, T. N. (1962). Receptive fields, binocular interaction and functional architecture in the cat’s visual cortex. The Journal of Physiology, 160(1), 106-154.

von Neumann, J. (1945). First Draft of a Report on the EDVAC. University of Pennsylvania.

McCulloch, W. S., & Pitts, W. (1943). A logical calculus of the ideas immanent in nervous activity. Bulletin of Mathematical Biophysics, 5(4), 115-133.

Rosenblatt, F. (1958). The perceptron: A probabilistic model for information storage and organization in the brain. Psychological Review, 65(6), 386-408.

Hebb, D. O. (1949). The Organization of Behavior: A Neuropsychological Theory. Wiley.

Minsky, M., & Papert, S. (1969). Perceptrons: An Introduction to Computational Geometry. MIT Press.

Moravec, H. (1988). Mind Children: The Future of Robot and Human Intelligence. Harvard University Press.

When the Brain’s Uncertainty computer goes offline: New Human Evidence for Thalamic Regulation of Decision-Making

michaelhalassa — Fri, 11 Jul 2025 04:32:22 +0000

An Elegant Natural Experiment

The study by Mackenzie et al. (2025, bioRxiv) represents a particularly clever approach to understanding human thalamic function. Rather than relying on correlational neuroimaging, the researchers capitalized on an unintended consequence of focused ultrasound thalamotomy for essential tremor. When post-surgical vasogenic edema extended beyond the intended motor target into cognitive thalamic regions, it created a rare opportunity to assess the causal contribution of different thalamic nuclei to decision-making behavior.

What makes this approach so powerful is the precision it affords. Patients served as their own controls, tested before and after surgery on a sophisticated decision-making paradigm that probes the exploration-exploitation trade-off under uncertainty.

Computational Dissection of Behavioral Changes

Using the restless four-armed bandit task, which requires continuous adaptation to changing reward contingencies, the researchers could probe multiple aspects of decision-making simultaneously. The task’s Gaussian random walk structure creates ongoing uncertainty, forcing participants to balance between exploiting currently favored options and exploring alternatives that might yield better outcomes.

The key innovation came from their computational modeling approach. Rather than simply observing that patients made more “stay” choices post-surgery, the authors fitted multiple reinforcement learning model variants to decompose the underlying decision processes. This revealed that the behavioral shift was best captured by a Bayesian learning model with increased reward sensitivity (β) but eliminated exploration bonus—suggesting that patients weren’t simply perseverating, but had fundamentally altered confidence in their value estimates.

Most strikingly, when using their winning model to classify choice types, the researchers found a dramatic reduction in directed exploration—the strategic sampling of uncertain options to gain information (Mackenzie et al., 2025). This wasn’t random exploration or simple indecision, but the specific loss of information-seeking behavior that would normally help resolve uncertainty about option values.

Anatomical Precision and Circuit Specificity

The neuroimaging analysis provided crucial anatomical specificity. The degree of behavioral change correlated specifically with edema extension into the lateral (parvocellular) mediodorsal nucleus—not other thalamic regions including the intended surgical target (VIM). This specificity is important given the known functional subdivisions within MD:

Lateral MD → DLPFC/Frontal Pole: Dense reciprocal connectivity with areas involved in cognitive control and abstract rule formation
Medial MD → OFC/vmPFC: Connections with valuation and reward-processing regions

The functional connectivity analysis further supported this anatomical specificity. Using normative connectome data, individual patients’ behavioral changes could be predicted from the connectivity profile between their lesioned MD voxels and prefrontal cortex—but only for MD, not other thalamic nuclei.

Mechanistic Insights: From Confidence Calibration to Circuit Function

The computational framework reveals something more nuanced than simple “inflexibility.” The post-lesion behavioral profile suggests a specific breakdown in uncertainty representation—what we might call miscalibrated confidence. When MD-PFC communication is compromised, the system appears to default to high confidence in existing value representations, reducing sensitivity to contradictory information.

This aligns with emerging theoretical frameworks positioning the MD thalamus as a critical node in hierarchical inference, helping to coordinate distributed computations for flexible and efficient learning (Scott et al., 2024). The loss of directed exploration particularly supports this view, as this behavior specifically emerges when agents are uncertain about their value estimates and seek information to reduce that uncertainty.

Bridging Animal Models and Human Neuroscience

The convergence with our rodent findings is striking:

Animal Studies (MD inactivation/optogenetics):

Reduced flexibility in volatile environments
Animals fail to revise beliefs when contingencies change
Inflated certainty in action values
Deficit specific to belief updating, not initial learning

Human Study (accidental MD lesions):

Reduced switching in uncertain environments
Patients fail to explore when exploration would be beneficial
Increased confidence in value estimates
Preserved basic learning ability

This cross-species convergence suggests we’ve identified a fundamental computational principle rather than a species-specific curiosity.

Therapeutic Implications: Beyond Motor Applications

The findings suggest intriguing therapeutic possibilities, particularly for disorders characterized by altered belief updating and confidence calibration. The demonstration that MD disruption leads to overconfident exploitation with reduced information-seeking offers a compelling framework for understanding psychiatric conditions where belief revision goes awry.

Consider schizophrenia, where patients often exhibit pathological certainty in delusional beliefs despite contradictory evidence. The current findings suggest a potential mechanism: if MD-PFC circuits that normally regulate confidence in beliefs become dysregulated, patients might lose the capacity for adaptive doubt that would otherwise prompt belief revision. The specific loss of directed exploration observed here—the strategic sampling of information to resolve uncertainty—parallels the clinical observation that individuals with psychosis often fail to seek disconfirming evidence for their beliefs.

This connects to broader hypotheses about uncertainty processing in cognitive control. Rather than viewing delusions simply as “false beliefs,” they might reflect a fundamental breakdown in the brain’s ability to appropriately weight confidence in its own predictions. When the system becomes overconfident in existing representations (as seen post-thalamotomy), it loses the motivation to gather information that might challenge those representations—a hallmark of delusional thinking.

Broader Significance: Rethinking Thalamic Function

This work contributes to a fundamental reconceptualization of thalamic function – from simple relay station to active computational processor. The thalamus isn’t just routing information; it’s dynamically modulating the confidence and precision of cortical computations based on behavioral context.

Personal Reflection: When Theory Meets Unexpected Validation

For our lab, this study is quite awesome – when years of circuit-level investigation receive independent validation from an entirely different methodology. The fact that this confirmation came through a clinical study aimed at treating human suffering makes it even more meaningful.

It’s the rare convergence where theory and evidence transform each other: the theory gains human causal validation, while the evidence gains mechanistic understanding. Together, they point toward a future where we might not just understand the circuits of adaptive decision-making, but actively repair them when they break.

The patients in this study, seeking relief from debilitating tremor, graciously contributed to our understanding of one of the brain’s most fundamental computations: how to balance confidence with curiosity. Their experience shows us what happens when certainty becomes a cage – when we lose the capacity to doubt ourselves when doubt would serve us best.

The work discussed builds on extensive research into thalamocortical circuits and decision-making, offering new insights into the neural mechanisms underlying adaptive behavior and potential therapeutic applications for disorders of motivation and cognitive flexibility.

References:

Mackenzie, G., et al. (2025). Focused ultrasound neuromodulation of mediodorsal thalamus disrupts decision flexibility during reward learning. bioRxiv.
Scott, D.N., Mukherjee, A., Nassar, M.R., & Halassa, M.M. (2024). Thalamocortical architectures for flexible cognition and efficient learning. Trends in Cognitive Sciences, 28(7), 639-652.

On The Value and Power of Well-Parameterized Tasks in Small Animals

michaelhalassa — Thu, 31 Oct 2024 16:15:06 +0000

Human Psychophysics: The Foundation

Psychophysics, the study of the relationship between physical stimuli and perceptual experiences, has a rich tradition in human research, dating back to pioneers like Gustav Fechner and Ernst Weber. By designing tasks that precisely control stimulus properties, experimenters have been able to quantify perceptual abilities and decision-making processes with remarkable rigor. For instance, using well-parameterized tasks, early psychophysicists were able to explore fundamental sensory thresholds—such as the minimum intensity of light detectable in a dark room or the smallest detectable difference in weight between two objects. By adjusting parameters like intensity, duration, or spatial frequency, these studies provided structured insights into how the brain processes sensory information and formed the basis of our knowledge on perceptual acuity and sensory integration.

As psychophysics advanced, so too did the sophistication of tasks and measurements used to probe more complex processes, such as motion coherence in a moving dot field or the contrast of Gabor patches in visual perception studies. Researchers began tracking behavioral metrics like choice probability, reaction time, and accuracy to map out the underlying computations of perception and judgment. The controlled nature of these tasks allowed for precise manipulation of sensory input, which made it possible to model the resulting behavioral outputs with mathematical precision. Furthermore, the responses collected from these experiments could be interpreted using normative modelssuch as drift diffusion models for perceptual decision-making. These models provide interpretive parameters that not only explain the observed behaviors but also offer a structured approach for linking behavior with brain activity. Psychophysics, thus, not only illuminated sensory processing in humans but laid the groundwork for exploring cognition and perception in ways that would later be adapted for studying neural circuits in non-human animals.

Extending to Higher Cognition

Building on the success of perceptual studies, researchers began applying the same rigor of well-parameterized tasks to explore more complex cognitive functions such as working memory, multi-step planning, and decision-making. These higher cognitive processes, which go beyond basic sensory perception, required innovative task designs that could isolate specific mental operations. For instance, tasks like the N-back are used to assess working memory by requiring participants to keep track of a sequence of stimuli over time, while multi-step planning tasks may present a maze or a problem that requires a series of strategic choices. These types of tasks demand more than just perception—they engage neural circuits involved in memory, attention, and executive function, providing insight into how the brain organizes and manipulates information.

The introduction of such tasks created what is often termed a “behavioral clamp”—a controlled setting in which specific cognitive processes are activated reliably, making it possible to measure and model them with precision. When paired with functional brain imaging techniques like fMRI or electrophysiological recordings such as EEG, researchers could observe not only behavioral outputs but also the brain regions and networks activated during these tasks. This combination of behavioral precision with neural measurements allowed for a more detailed understanding of how cognitive operations are represented in the brain. For example, the use of fMRI in conjunction with multi-step decision-making tasks directly exposes the concurrent activation of the prefrontal cortex and basal ganglia, linking executive function with reward processing. Similarly, EEG studies could track the real-time brain dynamics that accompany choices, memory recall, or error detection, mapping out the temporal flow of information processing.

Importantly, the data from these higher cognitive tasks can also be interpreted through normative models like reinforcement learning for decision-making or Bayesian inference models for probabilistic reasoning. These models help distill the cognitive processes underlying task performance into quantifiable parameters, which in turn can be related back to neural signals. For instance, reinforcement learning models provide parameters such as learning rate or exploration-exploitation trade-offs, which offer mechanistic insights into how the brain might update strategies or adapt to changing environments. By fitting these models to task performance data, researchers could infer the underlying cognitive strategies and relate them to specific brain regions or patterns of brain activity, enriching our understanding of the neural basis of human cognition.

Through this structured approach, the field has uncovered valuable insights into human cognition, establishing a framework for systematically probing complex brain functions that would later be adapted for non-human primate and rodent studies. These human experiments thus paved the way for studying brain computations not only in isolation but also as part of a broader cognitive architecture, setting the stage for cross-species exploration of brain function.

Non-Human Primates: Precision in Neural Coding

The success of well-parameterized tasks in human cognitive research was followed by their application to non-human primates, such as macaque monkeys, whose research aspires to model certain aspects of human mental processing. By training monkeys on tasks requiring visual fixation, visuospatial attention, and visual motion processing, people have gained insight into the neural correlates of perception and attention in a species capable of complex, human-like responses (in certain domains). Non-human primates are highly trainable and share many homologous brain structures with humans, making them invaluable for studies requiring both behavioral complexity and precise neural recordings. Tasks adapted for monkeys, such as the delayed match-to-sample for working memory or visual search tasks for attention, closely mirror the structured nature of human experiments but allow for a far more detailed look at the neural code underlying these processes.

One major advantage of non-human primate studies is the ability to record single-neuron activity in real-time. Unlike techniques used in human studies, which generally capture broad neural activity (e.g., fMRI measures blood flow changes across thousands of neurons), single-neuron recordings in monkeys enable pinpointing the activity of individual neurons and neuron populations involved in a task. This capability provides an incredibly detailed view of how specific neurons encode and compute sensory information, motor plans, and decision outcomes.

Furthermore, single-neuron recordings enable a unique approach to studying cognitive processes like attention, working memory, and decision-making. One can observe, for instance, how neurons in the prefrontal cortex change their firing patterns as attention is directed toward a stimulus or held in working memory over a delay period. These dynamic changes in neural activity provide clues about the coding mechanisms for cognitive control, goal-directed behavior, and information maintenance—processes that are more complex and nuanced in non-human primates than in rodents. In multi-step planning or decision-making tasks, researchers can track the sequence of neural firing patterns as monkeys evaluate their options and make choices, offering a granular look at how the brain integrates sensory information with learned rules and expected outcomes.

Another critical aspect of non-human primate research is the ability to decode neural signals directly and assess how they correspond to specific task parameters or behavioral choices. By linking single-neuron activity with task-based behaviors, researchers can validate and refine normative models derived from human studies, such as drift diffusion models or Bayesian inference models, at an incredibly fine level. This level of detail provides a complementary perspective to human studies, enabling a more comprehensive understanding of the neural code underlying cognitive processes and offering testable hypotheses for interpreting human neural data

Rodents: The Power of Causal Tools

While well-parameterized tasks have transformed our understanding of perception and cognition in humans and non-human primates, applying this rigor to rodents has unlocked an entirely new realm of possibilities, particularly in the domain of causal manipulation. Historically, rodent research focused on tasks with more degrees of freedom and little structure or parameter control. However, the introduction of well-parameterized tasks in rodents—such as two-alternative forced-choice (2AFC) for perceptual decision making—has enabled the application of structured, rigorous task design of human psychophysics to smaller animals, providing a pathway to study fundamental computations with unprecedented mechanistic resolution.

The unique strength of rodent research lies in combining controlled tasks, neural measurements and optogenetics, which enables the manipulation of specific neural populations with extraordinary speed and precision. Using light to activate or inhibit targeted neurons, optogenetics can directly probe neural circuits at the millisecond timescale, matching the speed of natural neural processing. This capability allows for investigating how specific neurons or circuits causally contribute to behaviors in real-time. For instance, in a visual discrimination task where rodents decide on the orientation of a Gabor patch, one can selectively stimulate or silence neurons in the visual cortex precisely when stimuli are presented. By observing how these manipulations affect performance, one can expose the causal link between specific patterns of neural activity and perceptual decision-making, elucidating the role of neural circuits in fundamental computations.

This type of rodent behavioral data can also be fit by normative model, and directly link model parameters (e.g., decision thresholds, learning rates) to neural activity. Causal tools can directly validate these fits and their relationship to neural activity patterns and/or behavioral outcomes.

While rodent models offer a unique level of control over neural circuits, there are inherent limitations when it comes to studying higher-level cognitive functions. Rodents, though capable of learning and performing complex tasks, do not possess the advanced working memory, abstract reasoning, or planning faculties observed in primates. This creates a ceiling to our understanding of higher cognition based solely on rodent studies, underscoring the value of a cross-species approach.

The importance of Cross-Species studies

With the rise of well-parameterized tasks and precision tools in neuroscience, causal manipulations are now an integral aspect of research across species, each adding unique insights into brain function and computation. While optogenetics and other causal techniques were initially developed for rodent models, they are increasingly being adapted for use in non-human primates, providing the potential to explore more sophisticated cognitive functions with causal precision. This cross-species approach leverages each model’s strengths: rodents for detailed circuit analysis and precise manipulation, non-human primates for higher-order cognitive tasks closer to human cognition, and humans for investigating uniquely human capabilities.

The move to optogenetics in non-human primates is enabling experimenters to link specific neural circuits to behaviors with unprecedented specificity in a species capable of complex tasks and social behaviors. However, while non-human primates are invaluable for studying higher-order cognition, unique aspects of human cognition, such as abstract reasoning, language processing, and complex social behavior, remain beyond their scope. In humans, single-neuron recording capabilities have recently become available, mostly through collaboration with clinical neurosurgery patients. These recordings provide a window into uniquely human cognitive abilities, allowing researchers to examine individual neuron responses during tasks involving complex reasoning or language comprehension. This is especially valuable because these capabilities are distinct to humans and require the highest-resolution insight into the neural code for human-specific cognitive functions.

Human single-neuron recording studies have led to new discoveries in areas such as episodic memory, social processing, and abstract reasoning. For instance, single-neuron recordings in the medial temporal lobe have demonstrated neuron populations that respond selectively to specific memory cues, effectively serving as neural markers for individual memories. Such findings highlight how human-specific neural coding mechanisms operate within broader cognitive architectures. However, human studies are naturally constrained by the limited contexts in which electrodes can be placed—typically restricted to clinical cases where electrode implantation is necessary for therapeutic reasons. Thus, while human recordings offer remarkable insights, they are limited to specific brain regions and contexts.

Causal manipulations using genetically-based tools like optogenetics are unlikely to be implemented in humans due to ethical and technical constraints. As such, rodent and non-human primate models remain crucial for probing the neural basis of cognition at a level of causality that is not feasible in human studies. For instance, in rodents, we can modulate neural activity in a single cell or a small group of cells within circuits that support memory, reward, or decision-making, and observe the direct effects on behavior. This level of precision is invaluable for testing hypotheses about circuit function and validating models of computation that might later be refined and examined in non-human primate and human contexts.

The development of miniaturized, wireless recording systems and single-cell optogenetics has further advanced cross-species research by allowing the study of natural behaviors and social interactions in freely moving animals. These innovations are proving invaluable for understanding neural computations within complex, naturalistic contexts that closely resemble the environments in which cognition naturally operates. Additionally, optogenetics in non-human primates is advancing our ability to perform causal manipulations in the study of high-level cognition, enabling researchers to make specific, time-locked neural adjustments while animals engage in cognitively demanding tasks.

This progression in causal tools across species represents a continuum in neuroscience, where each species adds a unique perspective. Rodents provide unparalleled causal precision for dissecting foundational computations, non-human primates allow us to study complex cognition within neural circuits homologous to those of humans, and humans bring us insights into uniquely human cognitive capacities. This cross-species toolkit, integrating well-parameterized tasks and causal manipulations, is rapidly advancing our understanding of the neural basis of cognition, perception, and behavior, establishing a comprehensive framework for the future of neuroscience.