HPS Neuroscience

Earliest Instance of the Cortical Volume Hypothesis?

2010-09-26T12:42:00.000-07:00

More good stuff from Gomulicki's article on the history and status of the theory of the memory trace. In this passage, Gomulicki discusses the hypothesis that intelligence depends on the size of your cortex:

"Aristotle's view that the heart was the seat of mental processes, including memory, was short-lived. It was, in fact, overthrown by his own grandson, Erasistratus (c. 310-250 B.C.) and Herophilus (335-280 B.C.), who, working together carried out what were probably the first dissections of the human brain and studies of the sensory and motor systems. They accepted the view that the heart was the seat of the 'vital spirits' (pneuma zolicon), but held that the 'animal spirits' (pneuma psychicon)--the physical mediators of mental processes--were located in the nervous system, and in particular in the brain. They even had the astuteness to attribute the superior intelligence of man as compared with other animals to the greater development of the convolutions in man, though this view was only a deduction from a quantitative correlation for which they did not attempt a functional explanation." (Gomulicki p. 2) ...Basically, it didn't occur to them that the convolutions made it possible to pack a large cortical sheet into the human skull...If I remember right, Galen thought that the size of a donkey's brain and the stupidity of the donkey served as an adequate counter-example to the notion that brain size effects intelligence. Given the later authority conferred on Galen's thought, it's no surprise that Erasistratus and Herophilus' conjecture would fail to take hold.

The Reverberating Theory of the Memory Trace

2010-09-25T19:25:00.000-07:00

Not a lot of histories of the theory of the memory trace floating around. Today, I loaded up the microfilm for Gomulicki' s "The Development and Present Status of the Trace Theory of Memory", which seemed like a well-received history on the subject, as far as things on this kind of topic are 'received' at all. It'll be nice when someone finally renders this in pdf. At any rate...

One topic that was well-represented was the reverberating theory of the memory trace, according to which you hold on to a memory so long as its effect keeps cycling in you somewhere, somehow, physiologically. From Aristotle to Nicolas Rashevksy:

Aristotle offered the first physiological theory of the memory trace, where "sensory impressions were transmitted from the sense-organs to the heart by movements in the pneuma--movements that persisted, though on a decreased scale, after the external stimuli had ceased. The persistence of the movements of the pneuma was held to constitute the physical basis of memory, forgetting being due to the gradual subsidence of the movements..." (p. 2) Then, some time later...

Rafael Lorento de Nó's "most important discovery as far as memory theory is concerned is the existence, in addition to the long-known open neural circuits (nerve 'pathways' and 'arcs'), of closed chains of several neurons, within which an impulse once set up can continue to circulate almost indefinitely without assistance from new afferent impulses." (p. 33)

From Nó's findings, Nicolas Rashevsky developed the theory of reverberating circuits, wherein the memory trace would persist so long as the activity trapped in one of Nó's closed loops persisted. The consensus among the historians I've seen discuss the reverberating theory is that no one was ever able to gather any evidence for it. Of course, at present, synaptic theories dominate. But it was an interesting idea and it seems to fit with reverberating models of active maintenance.

Vesalius, Galen, and Pissed Off Mentors

2010-09-18T17:11:00.000-07:00

Galen was never able to perform human dissections. The law of his time didn't permit it. So instead, he would study other species (e.g. monkeys) and guess at what must be going on inside humans. If he was lucky, he would encounter a human corpse out and about and get to stare at it a bit, but that was it. Consequently, there were some errors in his neuroanatomy, etc.

Andreas Vesalius (1514 –1564) was not outlawed from performing human dissections. When he came across some of the errors in Galen's anatomy, he noted them and eventually published his report in his book, De humani corporis fabrica. At the time that the Fabrica was published, Galen's word was gospel. So when Vesalius' mentor and devoted Galenist, Jacobus Sylvius, found out that Vesalius sought to correct Galen's observations, it didn't sit well.

Of Vesalius, Sylvius wrote, "Honest reader, I urge you to pay no attention to a certain ridiculous madman, one utterly lacking in talent who curses and inveighs against his teachers." He then went on to write a book entitled A Refutation of the Slanders of a Madman Against the Anatomy of Hippocrates and Galen, wherein he continued, "Let no one give heed to that very ignorant and arrogant man who through his ignorance, ingratitude, impudence, and impiety denies everything his deranged or feeble vision cannot locate." He then basically tried to call the cops on Vesalius to "punish severely, as he deserves, this monster born and bred in his own house, this worst example of ignorance, ingratitude, arrogance, and impiety, to suppress him so that he may not poison the rest of Europe with his pestilent breath." Nice.

*All quotations are from Stanley Finger's The Minds Behind the Brain (2000).

George Oliver, Adrenaline Junky Physician

2010-09-16T09:49:00.000-07:00

If you don't have test animals, you always have family...

"One of the most significant discoveries began with some personal observations by George Oliver, an English physician. Oliver had a penchant for inventing simple instruments and testing them on himself and his family members. He tried to invent an instrument for measuring the diameter of an artery under the skin. To test the sensitivity of his new device, he administered extracts from various animal glands to his young son and recorded changes in his arteries. To his surprise, injecting adrenal gland extract caused a large artery from which he was recording to narrow dramatically, raising his blood pressure." from Stanley Finger's Minds Behind the Brain

When Did Textbook Neuroscience Get Its Start?

2010-09-13T13:04:00.000-07:00

How do you count revolutions in a science?

One of the signs that your work has become part of the prevailing paradigm is that your findings appear in a textbook. It would stand to reason that uncovering a field's first textbook would reveal its first paradigm and that the progressive displacement of content across textbooks would reveal paradigm shifts.

We normally think of textbooks as being a fairly recent form of (very lucrative) publication. But textbooks have been around for a very long time. The Edwin Smith Surgical Papyrus of ancient Egypt records some of the earliest neurological observations. Galen's writings are some of the earliest we have on Greek and Roman medicine (Galen was a Roman).

Which of Galen's treatises would an ancient student of the brain go to as their authority? Not being a Galen scholar, I don't know the answer to this question, but it would be nice to know. The answer to this question might not only point to the dawn of neuroscience, but to its first revolution as well.

Jevons and Menger, Discoverers of Diminishing Marginal Utility

2010-09-11T16:41:00.000-07:00

I've been interested in exchanges of ideas between the neuroscience of motivation and economic theory for some time. The field of neuroeconomics of course is the current forum for such exchanges. I came across some of the first mentions of diminishing marginal utility in economics today and thought they were worth an entry.

"Every appetite or sense is more or less rapidly satiated. A certain quantity of an object received, a further quantity is indifferent to us, or may even excite disgust. Every successive application will commonly excite the feelings less intensely than the previous application. The utility of the last supply of an object, then, usually decreases in some proportion, or as some function of the whole quantity received. This variation theoretically existing even in the smallest quantities, we must recede to infinitesimals, and what we shall call the coefficient of utility, is the ratio between the last increment or infinitely small supply of the object, and the increment of pleasure which it occasions, both, of course, estimated in their appropriate units." William Jevons, A General Mathematical Theory of Political Economy (1862)

"The satisfaction of every man's need for food up to the point where his life is thereby assured has the full importance of the maintenance of his life. Consumption exceeding this amount, again up to a certain point, has the importance of preserving his health (that is, his continuing well-being). Consumption extending beyond even this point has merely the importance--as observation shows--of a progressively weaker pleasure, until it finally reaches a certain limit at which the satisfaction of the need for food is so complete that every further intake of food contributes neither to the maintenance of life nor the preservation of health--nor does it give pleasure to the consumer, becoming first a matter of indifference to him, eventually a cause of pain, a danger to his health, a danger to life itself." Carl Menger, Principles of Economics (1871)

Experimental Design--Where in the Hell Did it Come From?

2010-09-10T17:14:00.000-07:00

Lately, I've been interested in learning something about the history of statistical experimental design. This has led me to Stigler's The History of Statistics: The Measurement of Uncertainty Before 1900. Interesting book. Apparently Legendre introduced Least Squares in 1805, quite some time after the rise of Francis Bacon's experimental philosophy. I'm under the impression that the first book in experimental design was Ronald Fisher's The Design of Experiments (1935). The lag between developments in the logic of experiment and experimentalism is pretty astounding.

Where Do You Start in Studying History of Neuroscience?

2010-09-09T10:26:00.000-07:00

I want to build a bibliography of books that would help someone get a good introduction to the history of neuroscience. Single authored volumes are what I'm looking for. Here's what I've got:

Finger, The Origins of Neuroscience: A History of Explorations into Brain Function
Finger, Minds behind the brain : a history of the pioneers and their discoveries
Clarke and Jacyna, Nineteenth-Century Origins of Neuroscientific Concepts
Ochs, A History of Nerve Functions

Other recommendations?

Tools for Neuroscience Bibliometrics

2010-02-06T09:40:00.000-08:00

I'm testing out tools for doing neuroscience bibliometrics to test the fruitfulness of co-citation as a method for identifying a community of researchers working in the same field of neuroscience under the same research model. The availability of software for identifying co-citation networks promises to simplify protocols for identifying communities of science researchers. Such protocols would make it easier to re-identify research communities. This capacity to re-identify research communities is critical if sociologists of science are going to be able to engage in systematic and unbiased research. How are you supposed to be able to tell that I've accurately represented what a community of researchers is doing if I can't tell you how to find them? Furthermore, why should I believe that you've identified an actual community unless you can tell me what unifies them? I think that bibliometrics can help to answer these questions.

Presently, I'm testing out CiteSpaceII, using my MacBook. The software has proven to be very buggy and finicky about which browser I use. For example, I can't open CiteSpaceII using FireFox, but I can open it using Safari. However, when I do open CiteSpace, the GUI is compressed, buttons are squashed and labels are hard to read. Apparently, these problems do not arise on a Windows system. Not sure what CiteSpaceII looks like on a Linux system.

Because CiteSpaceII doesn't like my Mac, I'm now looking into using NetworkWorkbench. The documentation appears to be more extensive and NetworkWorkbench appears to be able to do whatever CiteSpaceII can do. NetworkWorkbench does not appear to have the same kinds of compatibility issues.

Verging on Superblindsight?

2009-04-01T19:49:00.000-07:00

Blindsight occurs when people have a blind spot in their visual field, due to cortical damage, but with some prodding, retain the capacity to guess (better than chance) that a stimulus has been presented to the blind spot. Apparently, at least one blindsight case who appears to have no awareness of visual perception can nevertheless navigate a hallway littered with obstacles.

In recent research led by Krystel Huxlin, it was shown that people who suffer from blindsight can learn to detect a variety of different types of stimuli presented to their blind spot (scotoma). Reuters offers a brief write-up of Huxlin et al's results. I've posted the abstract from Huxlin et al's paper for some additional details.

Krystel Huxlin et al (2009) "Perceptual Relearning of Complex Visual Motion after V1 Damage in Humans" The Journal of Neuroscience 29(13):3981-3991.

Damage to the adult, primary visual cortex (V1) causes severevisual impairment that was previously thought to be permanent,yet several visual pathways survive V1 damage, mediating residual,often unconscious functions known as "blindsight." Because someof these pathways normally mediate complex visual motion perception,we asked whether specific training in the blind field couldimprove not just simple but also complex visual motion discriminationsin humans with long-standing V1 damage. Global direction discriminationtraining was administered to the blind field of five adultswith unilateral cortical blindness. Training returned directionintegration thresholds to normal at the trained locations. Althoughretinotopically localized to trained locations, training effectstransferred to multiple stimulus and task conditions, improvingthe detection of luminance increments, contrast sensitivityfor drifting gratings, and the extraction of motion signal fromnoise. Thus, perceptual relearning of complex visual motionprocessing is possible without an intact V1 but only when specifictraining is administered in the blind field. These findingsindicate a much greater capacity for adult visual plasticityafter V1 damage than previously thought. Most likely, basicmechanisms of visual learning must operate quite effectivelyin extrastriate visual cortex, providing new hope and directionfor the development of principled rehabilitation strategiesto treat visual deficits resulting from permanent visual corticaldamage.

Dopamine Video

2009-03-28T08:30:00.000-07:00

A super-brief tutorial on dopamine function.

Erasing a Memory

2009-03-24T10:00:00.001-07:00

Researchers in Sheena Josselyn's lab report that a memory trace for a fearful experience can be selectively deleted in mice. Are we on the verge of localizing specific memories in the brain?

The full article can be found in JH Han et al. (2009) "Selective erasure of a fear memory." 323(5920): 1492-6. Here is the abstract:

Memories are thought to be encoded by sparsely distributed groups of neurons. However, identifying the precise neurons supporting a given memory (the memory trace) has been a long-standing challenge. We have shown previously that lateral amygdala (LA) neurons with increased cyclic adenosine monophosphate response element-binding protein (CREB) are preferentially activated by fear memory expression, which suggests that they are selectively recruited into the memory trace. We used an inducible diptheria-toxin strategy to specifically ablate these neurons. Selectively deleting neurons overexpressing CREB (but not a similar portion of random LA neurons) after learning blocked expression of that fear memory. The resulting memory loss was robust and persistent, which suggests that the memory was permanently erase. These results established a causal link between a specific neuronal subpopulation and memory expression, thereby identifying critical neurons within the memory trace.

Engineering the Next Revolution in Neuroscience

2009-03-22T10:30:00.000-07:00

Engineering the Next Revolution in Neuroscience outlines an empirical framework for optimizing discovery in neuroscience. Drawing on illustrations from the molecular and cellular neuroscience of cognition, the framework is rooted in the everyday practice of experimental neuroscience. Toward the optimization of neuroscience, we offer concrete, detailed proposals for studying progress in neuroscience research.

The book is co-authored by Alcino Silva, John Bickle and myself.

Milestones in Neuroscience Research Timeline

2009-03-16T11:24:00.000-07:00

There is a nice timeline of research in neuroscience at Eric Chudler's homepage (U. Washington).

Timeline: Molecular and Cellular Neuroscience of Learning and Memory

2009-03-15T23:10:00.000-07:00

Here is an evolving time line of the history of the molecular and cellular neuroscience of memory. I say it's evolving, because it is ridiculously incomplete and I intend to update it quite a bit. If there are any inaccuracies or important omissions, let me know. I've included a few important developments in molecular genetics outside of neuroscience because they made possible later critical research in neurogenetics.

1913 Sturtevant discovers linear order of genes
1920 Sturtevant publishes series of articles entitled "Genetic Studies On Drosophila simulans"
1926 Hermann Joseph Muller introduces X-ray mutagenesis
1950 Katz & Halstead hypothesize that memory traces depend on protein synthesis
1957 Scoville & Milner publish on HM
1960 Curtis &Watkins discover glutamate is major brain NT
1963 Flexner shows memory is affected by protein synthesis in mice
1968 Discovery of PKA by Walsh & Krebs
1971 John O'Keefe discovers place cells
1973 Bliss and Lomo discover LTP
1973 Cohen & Boyer introduce a method for creating recombinant plasmids
1974 Jaenisch creates first transgenic mouse using retrovirus
1978 Dunwiddie & Lynch showed LTP depends on extracellular Ca+
1979 Evans and Watkins discover AMPA receptors using quisqualate
1979 Dunwiddie & Lynch show blocking extracellular Ca+ blocks LTP but leaves synaptic transmission, facilitation and PTP intact
1980 Baudry & Lynch first propose receptor unmasking theory of LTP
1982 Morris shows watermaze performance is hippocampal dependent
1982 Turner, Baimbridge and Miller showed transient increase of extracellular Ca+ is sufficient to induce an LTP-like response
1983 Collingridge finds glutamate acts on NMDA receptors in the hippocampus
1983 Lynch using EGTA shows that hippocampal LTP is intracellular Ca+-dependent
1983 Nairn & Greengard discover CaMKII and that synapsin is one of its substrates
1984 Davis & Squire publish influential review "Protein Synthesis and Memory"
1985 Lisman gives theoretical discussion of how an autophosphorylating kinase could serve as a LTM switch
1986 Morris shows blocking NMDA receptor blocks LTP & spatial learning
1986 Montminy showed cAMP regulates somatostatin expression
1987 Montminy introduces CREB as a regulator of somatostatin transcription
1988 Malenka & Nicoll discover second messenger role of Ca+ in triggering LTP
1988 Yamamoto shows that CREB stimulates cAMP transcription
1989 Gonzalez & Montminy show that cAMP stimulates somatostatin transcription via CREB phosphorylation
1989 Malenka & Nicoll showed that LTP depends on CaMKII phosphorylation
1991 Sheng, Thompson & Greenberg suggest that CREB is regulated by CaMKII (turns out false)
1992 Silva shows that null mutation for CaMKII disrupts LTP + spatial learning, first knockout study in neuroscience of learning and memory
1993 Bliss & Collingridge outline their synaptic model of hippocampal-dependent memory, providing roles for both NMDARs & AMPARs
1994 Bourtchuladze shows LTM but not STM affected in CREB mutants
1995 Bartsch shows that CREB can facilitate synaptic growth in Aplysia
1995 Bannerman & Morris upstairs/downstairs experiment
1995 Lledo Malenka & Nicoll show that CaMKII is sufficient to induce LTP
1995 Isaac, Nicoll & Malenka provide evidence for silent synapses AMPARs
1996 Mayford & Kandel introduce CaMKII transgenics
1996 McHugh & Tonegawa show impaired place fields in NMDAR1 knockouts
1996 Rotenberg, Mayford & Kandel show mice expressing activated CaMKII lack low frequency LTP and do not form stable place fields in CA1

Taxonomies of Experiment III: Silva, Bickle and Landreth

2009-03-15T22:16:00.000-07:00

A third taxonomy of experiment can be derived from an article by Alcino Silva (UCLA) published in Journal of Physiology - Paris 101 (2007) 203–213 and work that Silva and I are doing along with John Bickle, who is at the University of Cincinnati. (Bickle and Silva have a related article that will soon be published in the Oxford Handbook of Philosophy and Neuroscience. Bickle is the editor of that volume.) This taxonomy is a work in progress.

The proposed taxonomy of experiment covers some of the same considerations that Craver and Sweatt considered. But it holds that there are 3 broad classes of experiment that are distinguished by their goals. The goals are: 1) description of phenomena, 2) assessment of causal relations among phenomena, and 3) development of tools to facilitate 1 and 2. Let's call experiments of class 1 Descriptive Experiments, those of class 2 Connective Experiments, and those of class 3 Validation Experiments.

Descriptive experiments focus on the dissection and description of phenomena without regard for the evaluation of causal hypotheses, per se. Causal considerations will of course affect the interpretations of one's measurements in these experiments, e.g. in the use of an imaging technique. But the goal of these experiments is not to assess the causal relations among the phenomena that constitute the subject matter. For example, one can dissect the hippocampus and describe its parts without testing hypotheses about the interactions of those parts.

Connective Experiments attempt to determine whether states of phenomena depend on each other. These assessments are made on the basis of manipulations (intervetions) and measurements of the phenomena of interest. There are 3 forms of connective experiment: 1) positive manipulations, which increase the value of an independent variable; 2) negative manipulations, which decrease the value of an independent variable; and 3) neutral measurements, which measure correlation between an independent and dependent variable under normal test conditions (roughly equivalent to Craver's activation experiments).

Validation Experiments validate the use of a tool, demonstrating that it is a reliable means of manipulating or measuring phenomena of interest. For example, the demonstration that knockout mice can be used to reveal the role a protein (e.g. CamKII) plays in both spatial learning and long-term potentiation validated the use of knockouts in the neuroscience of learning and memory. These experiments did not invent the knockout technique of course, but they did adapt a tool for use in neuroscience and led to a swarm of innovative transgenic approaches.

These forms of experiment are not entirely distinct. Validation experiments draw more attention when they simultaneously introduce a tool and reveal undiscovered phenomena or undiscovered causal dependencies. Descriptive experiments are often performed in such a way as to reveal causal information, e.g. that glutamate receptors can be found in pyramidal cells. The three different goals of experiment are mutually dependent, but any one of them can be performed with little regard for the others.

Taxonomies of Experiment II: Carl Craver

2009-03-09T19:55:00.000-07:00

In his book Explaining the Brain (2007), Carl Craver argues that there are 3 basic kinds of experiment in neuroscience: interference experiments, stimulation experiments, and activation experiments. The first two kinds of experiment are bottom-up, involving direct interventions on the components of neural mechanism. The third kind of experiment is top-down. According to Craver, these three forms of experiment are used to help neuroscientists discover neural mechanisms. Neural mechanisms are composed of causal processes whose joint function explains a target phenomenon. For example, the mechanism of the action potential is composed of causal processes with parts including ion gradients and ion channels. Finding explanations for phenomena in neuroscience involves determining which processes comprise the mechanism of the phenomenon. The three kinds of experiment in Craver's taxonomy make possible those deteriminations.

Interference and stimulation experiments are bottom-up in the sense that they are attempts to alter the state of a phenomenon to be explained (explanandum) by interfering with component processes of its mechanism. Lesion-studies are the paradigmatic instance of inference experiments. Other instances might include transcranial magnetic stimulation (TMS), genetic knockout, and receptor blockers.

Stimulation experiments are also bottom-up experiments. As the name suggests, these combine the stimulation of mechanism components with the measurement of a dependent variable. Here, microstimulation studies are the paradigm case.

Activation experiments are top-down experiments. That is to say, they involve interventions on a target phenomenon by going through "the normal causal pathway" that affects that target. To illustrate what he means by an activation experiment, Craver writes:

"There are several common varieties of activation experiment at all levels in neuroscience. In PET and fMRI studies, one activates a cognitive system by engaging the experimental subject in some task while monitoring the brain for markers of activity, such as blood flow or changes in oxygenation... In single- and mutli- unit recording experiments, one engages the subject in a task while recording the electrical activity in neurons. In other studies, researchers monitor the production of proteins, or the activation of immediate early genes such as c-fos and c-jun. The experiments leading up to Hodgkin and Huxley’s model of the action potential involved generating action potentials and monitoring single ionic currents while the neuron spiked..."

(Craver 2007, 151)

Compare these categories of experiment with David Sweatt's system and notice that Craver does not include the "determine" class of experiment that Sweatt offers. Nor does Sweatt offer considerations regarding the top-down or bottom-up nature of experiments. Also notice that Craver's class of activation experiments assumes that some form of manipulation is being performed by the experimenter on the neural system. The manipulation might just be a psychological task that is to be performed while measures of neural activity are taken. Or, the manipulation might be some form of stimulating input, such as in the Hodgkin and Huxley example, so long as that input mimics the normal input to the mechanism (in this case, of the action potential). There are no purely observational forms of experiment in Craver's list.

Taxonomies of Experiment I: David Sweatt

2009-03-05T20:27:00.000-08:00

Experiments are of course a major source of epistemic justification for theories in the special sciences. Different kinds of experiments provide different kinds of evidence. I'll post a few examples of taxonomies of experiment that have been offered by neuroscientists-- one that has been developed by Carl Craver (a philosopher of neuroscience at Washington University in St Louis), and one that has been developed by Alcino Silva, myself, and John Bickle.

This first taxonomy is offered by David Sweatt (pronounced "swet"), an outstanding neuroscientist at the University of Alabama at Birmingham (UAB). David Sweatt has been a pioneer in the molecular and cellular neuroscience of cognition. The following is my transcription of his discussion from his book, so expect some outside references to occur in the passage.

quoted excerpt from David J. Sweatt (2003) The Mechanisms of Memory. Elsevier Press, Boston.

"In general there are four basic types of experiments that any scientist can perform. I refer to them as block, measure, mimic, and determine experiments. I have found this categorization a useful mnemonic device throughout my career as a scientist, and, at the risk of sounding overly pedantic, I strongly encourage any young scientist who reads this book to incorporate them into their thinking about experimental design. For example, every time I write or review a paper I ask whether the investigation has included all these different types of experiments. Especially when writing or reviewing grant applications, where multiyear projects are proposed to test a hypothesis comprehensively, I cross-check myself and others on whether all of these approaches (if technically possible) have been applied to the problem at hand. It is important because what we do as scientists is test hypotheses, and the testing of any hypothesis is much stronger if a variety of independent lines of evidence are available to support the conclusions reached.

What follows is a brief description of each of these four types of experiments.

The determine "experiment" is not really an experiment at all. The determine approach is to perform a basic characterization of the system or molecule at hand independent of any experimental manipulation whatsoever. Examples of this type of pursuit are determining the amino acid sequence of a protein, sequencing a genome, determining the crystal structure of an enzyme, or determining the structure of the DNA double helix. Determinations of this sort are not experiments in that no manipulation of the system is attempted--to do an experiment you tweak the system to see what happens. If you mutate a residue in a protein and see what effect that has on the structure, then you have done an experiment. The basic determination of the structure is not an experiment in and of itself.

Determintations are some of the most satisfying laboratory pursuits to undertake because these are the rare types of studies where definitive data can be obtained. An amino acid sequence is what it is--you get to use unambiguous words like "identical" (versus indistinguishable or similar) and "determined" (versus concluded or inferred) when describing gene and amino acid sequences. There's slightly more ambiguity in determining protein structures and anatomical structures, but in general this pales in comparison to the ambiguity of a conclusion made on the basis of an experimental manipulation. The down side of determinations is that, as a practical matter, they are viewed as boring unless they involve lots of expensive equipment. It's very difficult to get a grant review study section to recommend approval of a basic anatomical characterization, for example, because no experimental testing of a hypothesis is involved. In modern biomedical research, hypothesis testing is de rigueur. In rodent behavioral systems, which are the topic of this chapter, most of the basic behavioral characterization has alread been done. However, there is a growing recognition that more sophisticated and detailed basic behavioral characterizations, and the devleopment of new rodent behavioral models for human mental disorders, is necessary for the next stage of progress in this field.

Block, measure, and mimic are experiments, and they are all specific types of approaches to test different predictions of a hypothesis. For the following discussion we will take the simple case of testing the hypothesis "A causes C by activating B" (see Figure 13).

The mimic experiment tests the prediction that "if B causes C, then if I activate B artificially I should see C happen as a result." An example that we will return to later is: if I hypothesize that a particular protein kinase causes synaptic potentiation, then applying a drug that activates that protein kinase should elicit synaptic potentiation.

The mimic terminology arises from the fact that you are trying to mimic with a drug (etc.) an effect that occurs with some other stimulus, potentiation-inducing synaptic stimulation in this example. The principal limitation of the mimic experiment is that B may be able to cause C but that in reality A acts independently of B to cause the same effect. B causing C and A causing C may be true, true, and unrelated.

At the current state of understanding and experimental sophistication, mimic experiments are just about impossible to execute in the context of mammalian learning and memory. This is because an enormous amount of fundamental understanding of the system is necessary, along with the capacity for very subtle manipulation, in order for the experiment to work. For example, suppose I hypothesize that synaptic potentiation underlies learning. In theory, the mimic experiment is to put an electrode in the brain, cause synaptic potentiation, and then the animal will have an altered behavior identical to that caused by a training session. Of course, doing this experiment requires that I know exactly which synapses to potentiate so that I can selectively acheive the right behavioral output--this is beyond the level of understanding for essentially all mammalian behaviors at this point.

The measure experiment tests the prediction that "A should cause activation of B." Using our example of kinases in synaptic potentiation, the measure experiment should cause an increase in the activity of the kinase. This is, of course, determined by measuring the activity of the kinase as directly as possible, hence the measure terminology. The measure experiment has been applied in a variety of different ways in the memory field, ways that we will discuss at various points throughout the book including looking for anatomical, physiologic, and molecular changes in the nervous system in association with learning. The principal theoretical limitation of the measure experiment is that it is correlative. One can show that A causes activation of B, but that does not demonstrate that activation of B is necessary for C to occur.

Which brings us to the block experiment. The block experiment tests the prediction that "if I eliminate B, then A should not be able to cause C." In our working example, this means that a kinase inhibitor should block the ability of the potentiating stimulus to cause potentiation. At present, the vast majority of investigations into mechanisms of memory involve this approach, and we will make many references to this type of experiment throughout the book. Specific examples include anatomical lesions, drug infusion studies, and genetic manipulations. The principal theoretical limitation of the block experiment is that it does not distinguish whether activation of B is necessary for C, versus whether the activity of B is necessary for C. For example, suppose that B provides some tonic effect on C that is necessary for it to occur. Inhibiting B will block the production of effect C when in fact A never has any effect on B whatsoever. In behavioral terms for learning experiments, this is referred to as a performance deficit-- the animal is simply unable to execute the behavioral read-out necessary to exhibit the fact that they have learned.

In summary, then, the mimic experiment tests sufficiency, the block experiment tests necessity, and the measure experiment tests whether the event does in fact occur. Each type of experiment has its strengths and weaknesses. Positive outcomes in testing each of these three predictions for any hypothesis makes for clear, strong support of the hypothesis." (Sweatt 2003, p. 45-46)

Coming Soon: the Introduction of Transgenics into the Neuroscience of Cognition

2009-03-03T21:49:00.000-08:00

Luigi Galvani

2009-03-03T16:19:00.000-08:00

Here are some notes on Luigi Galvani that I've collected, mostly from Clarke and Jacyna's book Nineteenth-Century Origins of Neuroscience Concepts.

Luigi Galvani (1737-1798) was an Italian scientist interested in the role that electrical forces play in animal physiology. Toward the end of the 18th century, Galvani showed that applying electric current to the nerves of frog legs could get the legs to kick. Galvani was not the first to have shown that electric current could induce contractions in skeletal muscles. In fact, he was repeating experiments that had already been performed. But his interpretation of the experiments earned him his place in the history of science (Clarke and Jacyna 164). The word "galvanized" finds its origin in Galvani's name.

Galvani's work with frogs branched into work on other animals, which later, through the work of Emile du Bois-Reymond spawned the field of electrophysiology.

It appears that Galvani's discovery was interpreted against the background of the hollow nerve theory, which had been espoused by such distinguished scientists as Rene Descartes. According to the hollow nerve theory, nerves are like pipes that generate muscular actions by channeling fluids around the body. The "hollow nerve" theory can be traced back to Erasistratus (c.260 BCE) and was endorsed by Galen four centuries later (Clarke and Jacyna 160). It seems that Galvani did not question the hollow nerve theory. Instead, he questioned preceding theories of what flowed through the hollows, and how that flow created muscle actions.

Based on his own experimental results, Galvani claimed to demonstrate that animals run on a special kind of electricity, so-called "animal electricity". Animal electricity was supposed to be a kind of fluid in Galvani's mind. The flow of the fluid through the nerves was what accounted for muscle flexion. Galvani's position stood in stark contrast with competing views on muscle flexion. According to these other views, the muscle actions were caused by effervescence, explosion, or ethereal oscillation (Clarke and Jacyna 161). (Personally, I find the explosion theory most compelling...joke.) Though a sound physical theory of electricity had not yet been found, Galvani's work tipped the scales in favor of the electrical theory of nerve conduction.

Neuroscience was revolutionized as a result of Galvani's work, but the revolution did not happen overnight. Not until the mid-19th century did consistent interest in electrophysiology emerge. Though he had nothing nice to say about Galvani or his work, Emil du Bois-Reymond carried Galvani's torch.

An interesting epistemological point:

Alessandro Volta (1745-1827) famously challenged Galvani's claim that nerve actions were normally driven by electricity. According to Volta, Galvani had not shown that electrical stimulation generated muscle contractions by the natural causal pathway (Clarke and Jacyna 171). Rather, he had shown that the actions of the metals used to stimulate the nerves were effective. Galvani met Volta's challenge with subsequent stimulation experiments without metals. It is pretty standard fare in contemporary neurosciece textbooks to delimit a class of experiments that mimic normal neural processes (you can find this notion in David Sweatt's textbook and Yadin Dudai's textbook).

The basic epistemic point: If your methods don't to some extent approximate typical causal forces working on the nervous system, your capacity to generalize from your studies will be limited. I wonder if there are prior discussions of "mimic" experiments in the neuroscience literature...

The Concept

2009-03-02T16:43:00.000-08:00

This is a history, philosophy, and sociology of neuroscience blog. These are the kinds of topics I'll discuss here:

1. Large-Scale Theories of the Brain
2. Epistemic Norms of Neuroscience
3. Historical Episodes in Neuroscience
4. Neurosemantics
5. Neuroinformatics
6. Bibliographic Analysis
7. Neuroscience Policy
8. Current Trends in Neuroscience

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