Just as the title asks I’ve noticed a very sharp increase in people just straight up not comprehending what they’re reading.

They’ll read it and despite all the information being there, if it’s even slightly out of line from the most straightforward sentence structure, they act like it’s complete gibberish or indecipherable.

Has anyone else noticed this? Because honestly it’s making me lose my fucking mind.

  • @chaorace
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    31 year ago

    Well, technically it’s a disorder which can emerge from any number of different causes. Yes, generally ADHD emerges as a developmental issue, but you could arrive at the same physiology through sufficiently specific neurodegeneration or brain trauma and these things would still be diagnosable as ADHD and even effectively treated using ADHD medication.

    Saying that might seem like a stretch, but consider the fact that we can consistently visually identify an ADHD prefrontal cortex in brain scans. When reduced volume is observed, it’s even possible to predict to some extent the symptom severity by how much appears to be missing. For several decades of research, the precursor to the modern ADHD diagnosis was even called “minimal brain damage”.

    • Blake [he/him]
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      11 year ago

      All of the scientific literature that I have ever read on the topic has strongly stated that there is no way to identify ADHD from brain scans or anything like that.

      Also, no, any situation you describe wouldn’t be diagnosable as ADHD, one of the requirements of an ADHD diagnosis is that the condition is present from birth.

      What you’re describing sounds like what I wrote above, and it’s not ADHD, it’s traumatic brain injury, or MS, or what have you. And they may or may not be treatable in the same way as ADHD, because the symptom’s cause is likely totally different.

      • @chaorace
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        1 year ago

        All of the scientific literature that I have ever read on the topic has strongly stated that there is no way to identify ADHD from brain scans or anything like that

        Identify =/= diagnose. You also cannot diagnose ADHD with a genetic test, despite genetics being a strong indicator. I alluded to this by following up with “when reduced volume is observed”, but you’re right in saying that it would have been less misleading to state directly that brain scans are never in and of themselves used to diagnose ADHD.

        Also, no, any situation you describe wouldn’t be diagnosable as ADHD, one of the requirements of an ADHD diagnosis is that the condition is present from birth.

        If we’re talking DSM-5, the criteria is actually that the onset of symptoms occur by 12 years of age. Even if you take the DSM-5 as gospel, it’s entirely possible for a 6 year old to experience a traumatic brain injury to the prefrontal cortex, heal from the initial trauma, continue to demonstrate symptoms, then receive an ADHD diagnosis. You might call that a misdiagnosis, but I don’t see much of a difference if the symptoms and treatment are the same. There are also recent studies which explore the development of ADHD secondary to traumatic brain injury in adults which I think could eventually warrant further broadening the diagnostic criteria.

        • Blake [he/him]
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          11 year ago

          Would you share some academic sources for brain scanning being able to identify or diagnose ADHD, please?

          • @chaorace
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            11 year ago

            I’m posting a source for my original claim: “we can consistently visually identify an ADHD prefrontal cortex in brain scans”. This is not the same as a source which proves that brain scanning is able to identify/diagnose ADHD itself. The order of operations is reversed, because the only way to diagnose a disorder like ADHD is through observation of symptoms, not physiology.

            To be clear: what I claim is that you can compare brain imaging of an average individual (oxymoron notwithstanding) diagnosed with ADHD against the brain imaging of an average individual not diagnosed with ADHD and visually see a difference.

            Source for this claim, w/ attention to table 4: https://sci-hub.se/https://doi.org/10.1016/j.biopsych.2006.06.011

            • Blake [he/him]
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              11 year ago

              I don’t really think this is showing what you think it is - table 4 references four studies which finds a significant difference in volume of the prefrontal lobe… but table 3 references three studies which do not find a significant difference. The sample sizes are very low in almost all of the studies being fewer than 20 people with ADHD. And even those studies which show that statistically significant difference have a relatively high probability that the results are explained by chance (heterogenity p)

              There’s quite a bit of research into this area, but it has all of the classic problems of ADHD studies, having been conducted on predominantly male children. Studies have been conducted on adults with ADHD and tend to find a significantly smaller difference, if any. A lot of the studies I read about stated explicitly that any difference, when compensated for gender, age, race, etc. is so slight as to be completely unnoticeable unless the imaging was conducted by expert specialists who were specifically looking for it.

              • @chaorace
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                11 year ago

                Table 3 and Table 4 aren’t combined because they assessed different regions of interest. The tables don’t contradict each other, because they don’t even include the same ROIs:

                Presented in Table 4 are ROIs that were assessed in only two studies and show significant SMDs between the ADHD and control subjects.

                As for the heterogeneity, the paper notes which ROIs failed to remain statistically significant after correction. The Prefrontal region is not included this list:

                Although frontal gray and white matter and premotor ROIs show substantial SMDs ranging from .59 to .75, they also show statistically significant levels of heterogeneity, indicating rather variable results across the two studies in each meta-analysis. Due to the lack of power for the meta-analyses in this table, we need to interpret these results with caution. For example, the measures of intracranial volume, frontal lobe, right amygdala, and the splenium using the O’Kusky et al. (1988) method failed to remain significant after correction for multiple comparisons.

                As you say, the studies aren’t golden, but that’s why I picked a meta-analysis. To be honest, if I knew I was going to be held to such a high standard, I would have just kept my mouth shut!

                • Blake [he/him]
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                  11 year ago

                  I don’t think that’s quite right - I no longer have the study in front of me to reference and I may have misread it, but if I remember correctly, the definition of Table 3 is the findings of studies that DO NOT show significant SMDs and Table 4 is studies that DO. If you look at the descriptions of table 3 and table 4 and compare then I think you’ll see what I mean. It may even be in the titles of the tables, I’ll check it again when I get home in case I misread, in which case I apologise.

                  And yeah, the authors call out the high probability of chance for those regions especially, but that doesn’t mean the other regions are perfect either - the data is all there in table 4, you can look for yourself! It’s the heterogeneity columns, the lower the p value, the more likely the effect is consistent. A p value of 0.05 is usually considered the baseline for statistical significance, or for meta analyses with low sample sizes (such as this one), it’s not unreasonable to consider higher values significant because of differences in methodology, but these are some pretty high values.

                  I’m not saying that any of this is reason enough to fully discount the findings, or that there’s no correlation found by the studies, it’s just that, in my personal opinion, the quantity of the data is significantly too low, too narrow in scope, and the margin of error is too large to use the data to say “yes, we can identify differences in brain volume between an average person with ADHD, and an average person without ADHD” with any confidence.

                  At best, you could say that “given an average white male child with ADHD, there’s a higher than normal chance that the prefrontal regions of their brain would be lower than average” and even that is quite an opinionated stance tbh

                  I’m sorry for making you feel attacked though, you seem to have made the claim in good faith, it’s just that a lot of people make claims like that in poor faith and use it to justify treating people with neurological differences as inferior people or even as subhuman, so I think it’s important that people don’t make broad statements about how science has proven that people with ADHD have smaller brains or whatever.