A recent interview on the website www.vox.com inadvertently gives us a portrait of the scrambled thinking of modern neuroscientists, whose thinking about the brain is senselessly guided not by the low-level characteristics of the brain discovered by neuroscientists, but by silly mechanical metaphors in which the non-mechanical brain is constantly compared to machines invented by men. The article containing the interview begins with the statement, "It’s difficult to talk about the human brain without inadvertently talking about computers." No, that isn't true.
The interview is with a zoologist named Matthew Cobb, who has written about the history of ideas about the brain. Cobb had some insightful and intelligent-sounding things to say about the improbability of eukaryotic cells evolving, which I quoted in a 2017 post. But in this interview his answers are empty-sounding.
Cobb makes it sound like scientists have a history of comparing the brain to whatever is the most impressive communications technology available in a particular time. So when the telegraph was the latest and greatest in communication technology (around 1850), the brain was compared to a telegraph; and when telephone technology was the latest and greatest in communication technology (in the early twentieth century), the brain was compared to a telephone switchboard; and when computers and Internet-capable devices were the latest and greatest in communications technology, the brain was compared to a computer.
None of these metaphors ever made sense. Telegraph systems, telephone systems and computer systems all are based on the signal transmission in copper wires that transmit signals with near-100% reliability. The chemical synapses in the brain that are by far the most common type of synapses have no such reliability. Tests have shown that in a chemical synapse the probability of successful transmission is less than 50%.
"There is, for example, unreliable synaptic transmission. This is something that an engineer would not normally build into a system. When one neuron is active, and a signal runs down the axon, that signal is not guaranteed to actually reach the next neuron. It makes it across the synapse with a probability like one half, or even less. This introduces a lot of noise into the system."
So according to this expert, synapses (the supposed storage place of human memories) transmit signals with a probability of less than 50 percent. That's very heavy noise – the kind of noise you would have if half of the characters in your text messages got scrambled by your cell phone carrier. A scientific paper tells us the same thing. It states, "Several recent studies have documented the unreliability of central nervous system synapses: typically, a postsynaptic response is produced less than half of the time when a presynaptic nerve impulse arrives at a synapse." Another scientific paper says, "In the cortex, individual synapses seem to be extremely unreliable: the probability of transmitter release in response to a single action potential can be as low as 0.1 or lower."
Another reason it never made sense to compare the brain to a telegraph system is that telegraph systems are based on a particular signal transmission code (the Morse Code) invented by Samuel Morse; but no one has ever discovered any evidence of any code system in the brain by which complex learned information can be reliably transmitted or stored or retrieved. No one has ever discovered a "brain code" or a "neuron code" analagous to the Morse Code.
It also never made any sense to compare the brain to a telephone switchboard. In an old-fashioned telephone switchboard, a caller would be routed exclusively to one particular telephone number. For example, a switchboard operator (after getting a request) might cause the caller with the number 342-2352 to be exclusively routed so that one and one phone number would ring: the number 342-4252. But the brain does not work like that. Most neurons are connected to very many other neurons. A scientific paper tells us, "Each neuron may be connected to up to 10,000 other neurons, passing signals to each other via as many as 1,000 trillion synapses."
This is actually an extremely strong reason for rejecting all claims that memory recall occurs in brains or that memories are stored in brains or that brains produce thinking. In my long post here I discuss this point at great length. I'll give just a short summary of my reasoning: reliable signal transmission only occurs when there is an exclusive or near-exclusive relation between a receiver and a transmission source. That's why TV sets never receive ten channels at the same time. When a receiver is bombarded by signals from very many sources at the same time, it would be like a TV that is simultaneously getting broadcasts from very many TV channels. The result would be an unintelligible jumble kind of like the mess shown in the visual below:
A jumble rather like the one above is something we should expect from a brain in which each neuron is always getting signals from very many other neurons, except that the jumble and unintelligibilty would be far worse; for most neurons receive signals from very many other neurons.
But what about the modern-day "brain as computer" metaphor? It never made any sense. To understand why, just read my post entitled "The Brain Has Nothing Like 7 Things a Computer Uses to Store and Retrieve Information." Below are the things I mentioned, things that are crucial components of computers, but have no counterpart in the brain:
- An Operating System
- An Application to Store and Retrieve Data
- The ASCII Code for Encoding Information
- A Decimal to Binary Conversion Table or Utility
- A Medium That Allows a Permanent, Stable Storage of Information
- A Storage Location System by Which the Exact Position of a Data Item Can be Specified, Allowing Fast Retrieval from an Exact Location
- Read/Write Functionality Allowing Data to Be Written to a Specific Location and Also Read From the Same Location
- The fact that no one has the slightest idea of how any arrangement of neurons could ever cause the arising of abstract ideas. Cobb's claim that neuroscientists aren't quite sure of how a brain could think is misleading. The truth is they haven't the slightest credible idea of how such a thing could occur.
- The fact that severe slowing factors should make it impossible for brains to produce the lightning fast thinking that occurs in people such as math savants who can produce very complex calculations with astonishing speed.
- The fact that unreliable synaptic transmission (discussed above) should make accurate memory recall and very accurate thinking impossible, contrary to the reality that humans such as Hamlet actors can recall large bodies of text with perfect accuracy, and other humans can do very complex mental calculations "in their head" with perfect accuracy.
(2) Synaptic delays, each about .5 millisecond, which end up being a huge slowing factor because so very many synapses must be traversed to pass through a decent amount of cortex tissue.
(3) Synaptic unreliability or noise, the fact that a signal across a synapse is typically transmitted with only between 10% to 50% likelihood, a factor that is typically ignored but which has a huge impact on effective speed.
(4) Synaptic fatigue, the fact that a synapse will so often need a rest period after firing, a period that can be more than a minute.
(5) Tortuosity, the fact that nerve signals must travel through sinuous paths that are not straight lines.
(6) Folding of cortex tissue, a further slowing factor.
Every one of these factors is ignored by 95% of discussions of brain signal speed in the popular press. Altogether these factors should cause us to conclude that the brain cannot possibly be the source of very fast recall and very fast thinking in people such as mathematical savants.
To see why this metaphor makes no sense, read my post entitled "The Brain Has Nothing Like 7 Things a Computer Uses to Store and Retrieve Information." Among the reasons why it is senseless to claim that brains make minds and brains are like computers, some additional reasons are:
- Minds are conscious, and computers are not.
- Minds can have novel abstract ideas, and computers cannot.
- Minds can have curiosity and morality, but computers cannot.
- Minds have experience and feelings, and computers do not.
- Minds can be interested in things, but computers cannot.
- Minds can experience pleasure and pain, but computers cannot.
What is your thoughts on neuroplasticity being used as an explanation for how cognition and memories are somehow intact after brain damage, or hemispherectomy?
ReplyDeleteNeuroplasticity is a claimed ability of the brain to very slowly grow new connections in a way that might involve a recovery of damaged functionality. So the claim is if you lose some chunk of your brain that was doing X, then maybe you very slowly grow some new connections that help slowly restore your ability to do X. But such an idea cannot explain the retention of learned knowledge claimed to exist in half of a brain that was removed. If a person's memories are stored in his brain, removal of half of the brain should cause the most gigantic memory loss. We cannot imagine that lost knowledge is magically restored by growing new brain connections. That would be like thinking that you can tear out half of the pages of a book, and that the first half of the book would grow back the lost pages.
ReplyDeleteNeuroplasticity is described as synapse reorganization, but there is no evidence that any synapses in the brain are ever organized, before or after brain injury. Synapses and their related dendritic spines always look as disorganized as cooked spaghetti strands in a pot. Human minds are organized, but there is no evidence of any kind of structural organization in synapses or dendritic spines. Conversely, DNA molecules show very strong signs of structural organization.
What I mean is that groups of synapses show no signs of structural organization, like pixels forming into a sentence or paragraph. But if we zoom down into the protein molecules that make up a synapse or a dendritic spine, we can find lots of organization inside such molecular building blocks.
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