Sometimes you may read some moonshine in the science news, some bunk article promoting the latest science paper, and then ask yourself: who is to blame for this baloney, this BS? Is it one or more of the paper authors, or is it the author of a university press release, or is it some science journalist working from the press release and the paper? So you have a kind of "figure out the culprit" challenge that is a bit like playing the board game Clue.
Head Truth
The huge case for thinking minds do not come from brains
Thursday, July 2, 2026
Psychologists May Misrepresent Their Research As Badly As Neuroscientists Often Do
Monday, June 29, 2026
No, Split-Brain Patients Do Not Have "Two Conscious Minds in One Skull"
Once again, we have an article in which a neuroscientist misinforms us very badly on the very important topic of split-brain patients. This time it is an article I read recently at the MIT Press Reader. The article is entitled "What Split-Brain Patients Reveal About Consciousness." After discussing facts that contradict his claim, the author (neuroscientist Christof Koch) senselessly refers without any warrant to "two conscious minds in one brain."
A split-brain patient is typically a patient who underwent an operation severing the corpus callosum, a mass of fiber-like nerves that connect the left hemisphere of the brain and the right hemisphere of the brain . Each of these hemispheres makes up half of the brain. Such an operation is typically done to treat very severe and frequent seizures. Below is a Google Gemini infographic on the topic of this operation, called a corpus callosotomy.
After this operation is performed, a person is left with two disconnected brain halves. If it were true that your brain makes your mind, such an operation should produce two minds in the same individual. But no such thing happens.
Split-brain patients who underwent surgery to split their brains are not the only people with two separated brain hemispheres. Sometimes split-brain subjects arise when the corpus callosum fails to form during the mother's pregnancy. This is called agenesis of the corpus callosum. Making a generalization about people born without a corpus callosum connecting the two sides of the brain, a scientific paper states this:
"The major anatomic feature of Primary AgCC [agenesis of the corpus callosum] is the absence of the corpus callosum....Primary AgCC has surprisingly limited impact on general cognitive ability. Although the full-scale IQ may be lower than expected based on family history, scores frequently remain within the average range."
We hear no mention of any "two minds in one body" effect. Another paper states this, using the term "agenesis of the corpus callosum" which means a failure of someone's body to ever have the corpus callosum connecting the two halves of the brain:
"In the 37 adult cases of agenesis of the corpus callosum, 19 (51%) had some degree of intellectual impairment, with the remainder being judged to have a normal IQ. Of those with learning difficulties, two thirds had a mild impairment, and one third had a moderate or severe problem."
So roughly half of these 37 split-brain people had a normal IQ. You can find papers on the condition of being born with no corpus callosum by searching on Google Scholar for papers having the phrase "agenesis of the corpus callosum." You will not find any discussion of "two minds in one body" in such papers about split-brain subjects, which helps show that the claim of such an effect is groundless.
Thursday, June 25, 2026
Be Skeptical of "Consciousness in Comatose" Claims, Which Are Probably More Brain Expert Pareidolia
Neuroscientists often make groundless boasts of having discovered things in brains that are not actually there. What is going on is pareidolia, people reporting seeing something that is not there, after wishfully analyzing large amounts of ambiguous and hazy data. It's like someone eagerly analyzing his toast every day for years, looking for something that looks like the face of Jesus, and eventually reporting he saw something that looked to him like the face of Jesus. It's also like someone eager scanning the clouds, looking for animal shapes, while trying to confirm his belief that after an animal dies, his ghost goes up and lives in the clouds.
On this blog I have provided very many examples of neuroscientist pareidolia. Some examples can be found in my posts here:
Neuroscientists Claim "Drifting Representations," But It's Mainly Just Their Pareidolia
Pareidolia Helps Neuroscientists Getting Nowhere Trying to Show a Brain Basis for Memory
Some Brain Wave Analysts Are Like "Face of Jesus in My Toast" Claimants
Normally when neuroscientist pareidolia occurs it is relatively harmless. There is the epistemic harm and intellectual harm caused when bad evidence is provided of things that are not true, but little other harm. However, one type of neuroscientist pareidolia can cause bad psychological harm in the relatives of those who are in a coma. I speak of the case of neuroscientists making shoddy claims of having discovered consciousness in comatose patients.
We read some examples in a Harvard Medicine article entitled "The Covert Consciousness Dilemma." The article is written by someone falling "hook, line and sinker" for some very dubious claims that were never well-supported. Early in the article the writer states this:
"Around the same time, Edlow heard about a paper published in Science that stunned him. The 2006 study focused on a patient who sustained extensive brain injuries following a traffic accident. Six months later she was still in a vegetative state. She showed no evidence of purposeful behaviors, such as following commands or making intentional movements. But then the researchers put her in an fMRI machine. While scanning her brain, they asked her to imagine walking through her house, moving slowly from room to room. And they told her to imagine playing a game of tennis, swinging for the ball with forehand and backhand strokes... Her brain responded to the commands with activity patterns that matched those of a healthy person, as if to say, I’m still here."
The 2006 study referred is the very low-quality paper "Detecting Awareness in the Vegetative State," which fails to provide any decent evidence justifying its title. The paper provides no robust evidence that any consciousness was detected in the single subject it studied. The paper claims that "Speech-specific activity was observed bilaterally in the middle and superior temporal gyri, equivalent to that observed in healthy volunteers listening to the same stimuli (fig. S1)." The Figure S1 referred to is one of those extremely misleading visuals in which neuroscientists artificially color-highlight particular regions of the brain that showed only tiny differences such as 1 part in 200, to create the false impression that there was some big difference in brain activity in some region which merely had a difference such as 1 part in 200.
"We used two complementary methods to determine the significance of differences in the frequency content of the EEG signal between the task and rest conditions: a univariate (frequency-by-frequency) approach and a multivariate approach. For each subject, both analyses were applied on a channel-by-channel basis to each run individually and to all runs combined.
For the univariate approach, we used a z-statistic, the Two Group Test (TGT) (Bokil et al., 2007), as implemented by the Chronux toolbox routine, two_group_test_spectrum (http://chronux.org), with a cutoff of p≤0.05 by jackknife method. Because spectral estimates within 2 Hz of each other are correlated by the taper functions, a difference identified by the TGT was only considered significant if it was present for all frequencies contiguously over a range greater than 2 Hz. This implies significance over at least two neighboring but non-overlapping windows of the multi-taper estimate and is indicated in figures with a rectangle drawn around the results (Figure 3B). Spectral differences over ranges narrower than 2 Hz represent only a trend to significance. To compensate for multiple comparisons (60 frequencies per channel in 29 or 37 channels), the False Discovery Rate (FDR) (Benjamini and Hochberg, 1995; Benjamini and Yekutieli, 2001) was applied to the TGT p-values determined from analyses of all runs combined.
To look for spectral differences that might only be apparent if combinations of frequencies are considered, we employed a multivariate approach, Fisher’s linear discriminant (FLD) (Fisher, 1936). This approach has been used successfully for classification of EEG responses to motor imagery (Hung et al., 2005; Bai et al., 2007). To limit dimensionality, we binned the log spectra from 4 to 24 Hz into 2 Hz windows, reducing the spectrum to 10 values. The FLD was then defined as the linear combination of these quantities that maximized the ratio of the power variance between the conditions to the power variance within the conditions. To determine the significance of the FLD, we used a shuffle method: we recomputed the FLD from 1000 shuffles of the two conditions, and determined the p-value as the fraction of shuffled datasets that yielded an equal or larger value to the actual FLD. To take into account the possibility that neighboring snippets had similar spectra because of a slowly changing underlying brain state (rather than the task) (Menzer et al., 2010), the shuffled datasets kept the snippets from the nine-second-response period after each command together during all shuffles. To control for multiple comparisons (since the FLD was applied separately to each channel), the FLD p-value was only considered significant for a channel if it was less than an FDR-corrected rate of 0.05. This is shown as an asterisk on the summary figures (e.g. channel Oz in Figure 3B). For each subject, this analysis was applied to each run individually, and to all runs combined."











