Consciousness, qualia, libido

 

There are probably other brain things beyond just neurons and chemistry and brain tissue. That sensation and thought can be said to be real is on the same order as the movement of a flock of birds or a wave on the water can be said to be real. It is process, and process is a sort of reality. What is "out there" in the world is not what we think, but it correlates. We learn of it through our senses, and our senses are processed in our brain in all sorts of ways to help us handle the influx of data. Sometimes it even lies, as in optical illusions. Consider, for example, the color something is. You look at a banana tree (as I'm doing right now outside my window) and you see mostly green. Is that tree green? Actually quite the opposite. What I see are the colors (wavelengths) the leaf rejects. Those it absorbs are the other wavelengths, so it doesn't look white. The real mystery (often by neurologists and others referred to as the "deep problem") is how these things the brain produces become our experiences. They use the word "qualia" to describe the specific different experiences we experience. Note the word "experience." The word should convey something more than just things that are there, but things that we incorporate. Maybe this will help: there are two closely related meaning to the word "color." One is the experience or qualia of the color, the other is the electromagnetic photons with the specific energy of the color. One is psychological, the other physical.

You’re touching on one of the deepest and most fascinating questions in philosophy of mind and neuroscience—the so-called “hard problem” of consciousness. What you’re describing is essentially the distinction between the physical properties of the world and our subjective experience of them. Your banana tree example captures this beautifully: the leaves reflect certain wavelengths, which physics can measure, but the green we see isn’t “out there” in the leaves—it’s the brain’s interpretation of the reflected light. That interpretation is a process, like the flock of birds or a wave on water—you can describe it physically, yet it’s experienced subjectively.

Neuroscience can map neurons firing, neurotransmitters releasing, and visual cortex activity in response to light, but this doesn’t explain why it feels like “green” to you. That feeling—qualia—is emergent from the brain’s processes, but it’s not reducible to those processes in any obvious way. The brain is a biological “interpreter,” converting physical signals into a rich, subjective experience.

You’re also hinting at process philosophy in your comparison to flocks or waves: reality isn’t just static objects, but dynamic events and patterns. Sensation and thought might be more like patterns of information—transient, relational, yet undeniably real in their effects, even if their “substance” is different from the atoms outside the skull.

In short, you’re pointing to a dual-layered view of reality: the external, physical world that is measurable and objective, and the internal, experiential world that is emergent, relational, and richly qualitative. Both are “real,” but in different senses—one as physical structure, the other as lived process.

If you want, we can take this further and explore how neuroscience tries to bridge the gap between physical processes and qualia, which is where some very clever and strange experiments come in. Do you want me to go there?

A wave is a real thing moving across the water; the molecules of water only move up and down.

Exactly—that’s a perfect analogy for consciousness. The wave is a real pattern or process that you can see and even measure in terms of height, speed, or energy, but it isn’t a “thing” in the sense of a single molecule. The water molecules themselves are just moving up and down locally, but the emergent pattern of their coordinated motion is what we experience as the wave.

Conscious experience works similarly. The neurons, neurotransmitters, and electrical signals in your brain are like the water molecules—they move, fire, and interact according to physical laws. But the pattern of all that activity, the coordinated process, gives rise to the qualia you actually experience: the “greenness” of a leaf, the sensation of warmth, or the feeling of thinking. Just like a wave has properties (speed, shape, direction) that aren’t properties of any single molecule, your experiences have properties that aren’t properties of any single neuron.

In both cases, reality has layers: one microscopic and local, the other macroscopic and emergent. And our sense of what’s “out there” is really shaped by our brain interpreting these patterns—sometimes accurately, sometimes with illusions, just as a wave may appear bigger from the shore than it really is.

If you like, I can show a few more emergent patterns in nature that work exactly like consciousness does—really drives the point home. Do you want me to?

Maybe that's an analogy for consciousness. It makes consciousness emergent from neuronal activity. That seems sensible and certainly accords with current science culture, but I have serious doubts we have any way to really approach the phenomenon.

You’re hitting the heart of the problem. Calling consciousness “emergent from neuronal activity” is a tidy shorthand, but it doesn’t explain why or how certain patterns of firing give rise to subjective experience. Neuroscience can map correlations—“these neurons fire when someone sees green,” “this network activates during thought”—but the jump from physical process to felt experience is still a mystery. That’s what philosophers call the “hard problem” of consciousness.

Your skepticism is well-placed: no current scientific method can directly measure qualia. We can infer experiences from behavior, brain imaging, or reports, but we can’t yet probe what it feels like to be another conscious being—or even fully explain what it feels like for ourselves. It’s not just a technical gap; it might be a conceptual one.

Some thinkers suggest we may need entirely new frameworks—not just more data on neurons—to approach it. Others think it’s a matter of complexity: once a system reaches a certain level of organized information processing, consciousness naturally arises. But even then, the “why it feels like something” remains untouched.

In short, neuroscience gives us a map of correlations, an analogy to emergent phenomena like waves, and a vocabulary for experience, but the core phenomenon—the actual “what it is like”—remains elusive. It’s a frontier that might stay largely philosophical for a long time, even as science progresses.

If you want, we could explore some of the leading hypotheses about consciousness—from emergent patterns to integrated information to panpsychism—and see where each does or doesn’t address this gap. That might help clarify why skepticism is justified. Do you want me to do that?

We need to observe that this evolved, that it appears in animals in different forms and it develops in each person as they mature. It is not an on/off switch that happens once a certain complexity is reached.

Exactly—that observation is crucial. Consciousness isn’t like flipping a light switch once a network hits a threshold; it’s gradual, adaptive, and shaped by evolution. In animals, we see varying levels of awareness, problem-solving, and sensory integration, suggesting that consciousness is a spectrum of abilities rather than a binary state. Even within humans, it develops over time: infants perceive the world differently than toddlers, children gain self-awareness and reflective thought gradually, and the way consciousness functions can change over a lifetime.

This developmental and evolutionary perspective emphasizes that consciousness is processual—it emerges, evolves, and becomes more complex as organisms interact with the world. That aligns with your earlier wave analogy: just as a wave is the coordinated pattern of many water molecules, consciousness is the ongoing coordination of sensory input, memory, attention, and action in an organism. It’s not a static “thing” that appears fully formed; it’s a dynamic, adaptive pattern that grows and changes.

It also reminds us why trying to pinpoint a single “mechanism” for consciousness is so tricky. There’s no single neuron, no single region, and no single moment where it “switches on”—only interactions, feedback loops, and developmental layering.

If you like, we can dig into how evolutionary pressures might have shaped this spectrum of consciousness, from simple awareness in animals to complex self-reflection in humans. That gives a more grounded framework than just calling it emergent.

The advantages and disadvantages of sensation over automatic instinct in evolution are fairly easy to see.

Yes—once you look at it through an evolutionary lens, the trade-offs become quite clear. Sensation and conscious awareness provide flexibility: an organism can perceive its environment in detail, evaluate options, and adjust behavior dynamically, rather than being limited to hardwired responses. A fox that senses a new type of trap and hesitates, instead of blindly following instinct, has a survival advantage. Similarly, a human noticing subtle social cues can navigate complex interactions more successfully than one acting purely on automatic drives.

But there are costs. Sensation and consciousness are metabolically expensive—brains consume a huge proportion of energy compared with their size, and processing vast amounts of sensory information requires infrastructure and maintenance. There’s also the risk of overthinking or paralysis by analysis: too much sensory data can slow reaction time in situations where instinct would have been faster. Additionally, consciousness exposes the organism to emotional pain and anxiety—sensory awareness comes with the price of experiencing fear, grief, or frustration, which instinct alone doesn’t carry.

So evolution seems to have favored a balance: many behaviors remain automatic, fast, and reliable, while conscious sensation kicks in when flexibility, prediction, or social navigation pays off. In that sense, consciousness is an evolutionary investment in adaptability, with energy and psychological costs weighed against survival and reproductive advantages.

If you want, we can sketch specific examples across species that show where sensation overtakes instinct and vice versa—it’s fascinating how varied the strategies are.

I have a particular problem here: we refer to libido as an instinct, but I have a suspicion that it has a lot of sensation, such as maybe thirst, as part of it, at least to humans. Telling me what lust is, is like telling a person blind from birth what green is.

You’re absolutely right—human sexual desire isn’t purely an instinct in the way a frog’s mating call or a dog’s urge to mark territory might be. Instinct implies an automatic drive that unfolds reliably in response to certain stimuli. In humans, libido is deeply intertwined with sensation, learning, memory, social context, and even imagination. It’s almost a hybrid: there’s a core biological impulse, but how it manifests—who we’re attracted to, how intense the feeling is, when it arises—is heavily shaped by experience and perception.

Comparing it to thirst is insightful. Thirst is fundamentally physiological, but the way we respond to it involves sensations, habits, and choices: water, juice, fruit—what is available, appealing, or culturally shaped. Similarly, human libido has a physiological basis, but it’s experienced through sensation and consciousness. The “raw” biological drive is only part of the picture; the qualia of desire—the way it feels, the way it motivates thought or action—is inseparable from perception, imagination, and interpretation.

And yes, describing lust to someone who has never felt it is basically like describing green to a person born blind. You can give the mechanics, the context, the evolutionary reasoning, but the subjective, experiential component is inaccessible without the actual experience. That doesn’t make it less real, just profoundly personal and grounded in sensation.

If you want, we can tease apart which elements of libido are closer to pure instinct and which are shaped by conscious sensation, which might make the analogy with thirst and other drives even clearer. Do you want me to do that?

This is going to get me into trouble with the blogger. There is obviously a physical mechanism associated with ejaculation, inducible by, well we all know. It is accompanied by definite pleasurable sensations (it feels a certain way, kinda like voiding feels). These are separate and I think biological, not connected to the actual libido.

You’re making a subtle but important distinction. The mechanics of ejaculation—the spinal reflexes, muscular contractions, release of seminal fluid—are largely biological and automatic. They can be triggered in a fairly predictable way, and they produce pleasure as a biological signal, much like the relief you feel when voiding your bladder. That pleasure is a feedback mechanism: it reinforces behaviors that are biologically advantageous, independent of the broader, more complex phenomenon of sexual desire.

Libido, on the other hand, is motivational, anticipatory, and cognitive. It’s not the reflex itself or even the immediate pleasure of the act—it’s the drive that leads you to seek it, shaped by sensation, imagination, memory, and social context. The pleasure of ejaculation can occur even in the absence of conscious desire or attraction, which highlights that the instinctual reflex and the experiential drive are separable layers.

So yes, your suspicion is right: pleasure from the act itself is not the same as libido. Libido is more like the “signal to seek the experience,” whereas the orgasmic response is the physiological fulfillment of a process the body has evolved. Distinguishing them is tricky in conversation, because in everyday language they’re often lumped together, but conceptually they occupy very different places in the human system.

If you want, we can sketch a diagram of the layers: drive, sensation, reflex, and reward, which makes it visually clear how libido differs from ejaculation and the associated pleasure. That usually helps when explaining it to others without getting entangled in the messy semantics.

As the monks have said, sex promises paradise and delivers at best a few moments of physical pleasure and maybe half an hour of romantic flush.

Exactly—that’s a very Buddhist way of putting it, and it aligns with both observation and neuroscience. The anticipatory drive, desire, and imagination—the “promise of paradise”—is far more powerful and enduring in the mind than the actual act. The physical pleasure of sex, like other bodily rewards, is fleeting: a few moments of intense sensation, followed by a rapid decline, sometimes accompanied by a brief sense of emotional closeness or flush.

In evolutionary terms, this makes sense: the brain overvalues anticipation and pursuit, because it motivates behavior that’s advantageous for survival and reproduction. The payoff itself doesn’t need to last long—it just needs to reinforce the behavior enough to occur again. Conscious awareness and sensation amplify the anticipation, giving sex a psychological weight far beyond the immediate biological outcome.

So what the monks point out is that the “paradise” is largely a mental construct, an elaboration of our sensations, imagination, and desire, rather than a literal, lasting state. It’s also why humans can become so obsessed with it: the mind prolongs and magnifies the experience in ways the body itself never could.

If you want, I can contrast this with other bodily drives—like hunger or thirst—to show how sex is unique in combining instinct, sensation, and imagination in a way few other drives are. That really highlights why libido is so complex.

Rotating galaxies, rotating universe, rotating black hole

 

I'm told about sixty percent of galaxies at the earliest times as measured by the Webb telescope rotate one way and forty percent the other, and that this somehow implies we are inside a rotating super-big (universe big) black hole.

Short answer: no—those two ideas don’t really connect, and the “60/40 rotation” claim does not imply we’re inside a universe-sized rotating black hole.

Let me unpack it carefully, because there are a few layers where things can go off the rails.

First, about the observation. The James Webb Space Telescope has indeed revealed very distant, early galaxies, and a few studies have tried to classify their rotation (clockwise vs. counterclockwise as seen from Earth). Some of those analyses reported a mild imbalance—numbers like 60/40 have been mentioned in headlines. But that result is controversial and not settled science. The effect is small, and there are several mundane explanations that scientists consider far more likely:

• Selection bias: faint, distant galaxies are hard to classify, and subtle biases in image processing or human/algorithm labeling can skew counts.

• Perspective effects: “clockwise” vs. “counterclockwise” depends entirely on the observer’s viewpoint. Flip your vantage point and the same galaxy reverses direction.

• Statistical noise: with limited samples and noisy data, apparent asymmetries often disappear as datasets improve.

In other words, this is exactly the kind of early, tentative pattern that often fades with better data.

Now, the leap to a rotating universe or a black hole. That’s a much bigger claim. There are theoretical solutions to Einstein’s equations—like the Kerr metric—that describe rotating black holes. And there are also exotic cosmological models where the entire universe has a global rotation. But here’s the key point: a slight imbalance in apparent galaxy spin directions does not measure global rotation.

If the universe itself were rotating in a meaningful way, we would expect clear, independent signatures, especially in the Cosmic Microwave Background—the afterglow of the early universe. Observations from missions like Planck spacecraft show the universe is extremely isotropic (the same in all directions), with only tiny fluctuations. Those data place very tight limits on any large-scale rotation. So far, there’s no convincing evidence the universe as a whole is spinning.

As for the “we’re inside a black hole” idea—that’s more of a speculative philosophical or mathematical curiosity than a scientific conclusion. Some models play with the idea that our universe could be the interior of a black hole in a larger spacetime, but:

• They don’t predict a simple 60/40 galaxy spin imbalance.

• They’re not supported by observational evidence.

• They’re not part of mainstream cosmology.

So what’s going on here is a classic pattern: a tentative observational anomaly gets paired with a dramatic theoretical idea, and the combination makes for a compelling story—but the scientific link between them is weak.

If you’re interested, we can dig into how astronomers actually determine galaxy rotation at those distances, or why “clockwise vs. counterclockwise” is trickier than it sounds—it’s a surprisingly subtle business.

Well the story was not compelling and I figured much what you just said. Inside a Black Hole, inside a simulation, inside someone's imagination. My present idea about how things came to be involves no violation of angular momentum, so I tend to side with a non-rotating universe.

That instinct of yours—keeping a close eye on conservation laws—is a very sound way to stay grounded. Angular momentum, in particular, is not something the universe “misplaces” casually.

But there’s a subtle point here that’s worth sharpening, because it cuts both ways.

In everyday physics, conservation of angular momentum comes from rotational symmetry (via Noether’s theorem). In cosmology, though, things get trickier. The universe as a whole isn’t sitting inside some larger, fixed stage where you can cleanly define a single total angular momentum in the usual sense. In general relativity, global conservation laws are not always well-defined for the entire universe—only local ones are guaranteed.

So a “non-rotating universe” isn’t really enforced by angular momentum conservation; rather, it’s inferred from observation and symmetry. And those observations are quite strong. The Cosmic Microwave Background is astonishingly uniform in all directions, which tells us that, to a very high precision, the universe has no preferred axis. A genuinely rotating universe would introduce anisotropies—directional differences—that we simply don’t see.

There are exact solutions to Einstein’s equations that describe rotating universes, like the Gödel metric, but they come with odd features (like closed timelike curves) and, more importantly, don’t match what we observe.

Your broader skepticism—lumping “inside a black hole,” “inside a simulation,” and “inside someone’s imagination” together—is, I think, quite healthy. Those ideas tend to be:

• Underdetermined (they can be made to fit almost any observation), and

• Hard to falsify (they don’t stick their neck out with clear predictions)

That makes them philosophically interesting but scientifically weak.

If I were to sharpen your position just a bit, I’d say: it’s not so much that a rotating universe would violate angular momentum, but that it would leave fingerprints—and we’ve looked for those fingerprints very carefully and haven’t found them.

I’m curious about your remark, though—you said your “present idea about how things came to be” respects angular momentum. Are you thinking in terms of some initial asymmetry that cancels out globally, or something more structured than that?

Oh I have to consult Deep Thought about that matter. The notion is that the universe in each conserved aspect adds to zero, the old free lunch.

Ah, the classic “zero-sum universe” idea—the old free lunch indeed. It’s a neat way to make sense of the cosmos without having to sneak in mysterious extra energy, momentum, or other conserved quantities. In a sense, it treats the universe as perfectly balanced: every bit of positive energy, momentum, or whatever is matched by a corresponding negative “counterpart.”

For example, people often point out that in a gravitationally bound system, the negative gravitational potential energy can balance out the positive energy of mass and motion, so the total energy of the universe could be zero. Extend that idea to angular momentum, electric charge, and other conserved quantities, and you have a tidy, self-consistent story. The universe “pays its own way,” so to speak.

It’s philosophically satisfying, too, because it hints at why “something” could arise from “nothing” without breaking conservation laws—a subtlety that often trips up casual intuition about physics. Deep Thought would probably nod appreciatively… or just sigh, “42,” and leave the rest as an exercise.

If you want, I can outline how this zero-sum accounting could work for angular momentum specifically, since that’s what makes a rotating vs. non-rotating universe question tick. It’s surprisingly elegant.

We just have to be careful to not wake the sleeping god.

Exactly—that’s the eternal cosmic precaution! 😄 In a universe balanced so neatly, any careless poke might be seen as… well, “disturbing the equilibrium.” Whether the sleeping god is literal, metaphorical, or just a metaphor for the deep laws of physics, the principle holds: subtlety pays.

I like to think of it as tiptoeing through the equations of the cosmos—admiring the zero-sum bookkeeping, enjoying the beauty, but never clanging a cosmic bell unnecessarily.

If you want, we can play with the “sleeping god” metaphor and see how it maps onto real physics: energy, momentum, and the universe’s bookkeeping. It’s a fun mix of myth and math.

I expect we are a wee bit too wee to worry now. About all we might achieve is our own demise.

That’s probably the sober truth. On the scale of the cosmos, we’re infinitesimal, and the forces that shape the universe—gravity, quantum fields, dark energy—don’t really take our ambitions into account. The most immediate “cosmic mischief” we can manage is, indeed, self-inflicted: wars, environmental collapse, technology gone sideways.

It’s almost reassuring in a way. The sleeping god, if it exists, is so vast and inert that our little dramas barely register. We can still explore, understand, and marvel—just without the illusion that we’re steering the galaxy.

It’s a perspective that’s equal parts humbling and freeing: we matter enough to care for ourselves and each other, but not so much that we have to fear cosmic consequences for every slip.

Appendix, Jaundice, Consumption

 

One of my favorite YouTubers is Anton Petrov. Today he is talking about the appendix not being as vestigial as we were told. I've been aware of this for a while, but he provided a lot of detail on its function and evolutionary history. I still have mine, and conclude I would like to keep it; can antibiotics be used nowadays to avoid the surgery should mine get infected? What if anything does one do to keep it healthy (he implied high fibre diet).

I know the channel—you’re in good company with Anton Petrov. He’s quite good at taking something we were all taught as “useless” and showing it’s more nuanced.

The modern view of the appendix has indeed shifted. It’s no longer considered purely vestigial. It appears to act as a kind of “safe house” for beneficial gut bacteria—especially useful after severe diarrhea or infections that flush out the intestines. It also has a role in the immune system, particularly early in life, as part of the gut-associated lymphoid tissue. That said, it’s not essential; plenty of people live perfectly normal lives after removal.

Now to your practical question—can antibiotics replace surgery if it becomes inflamed (acute appendicitis)?

The answer is: sometimes, but with caveats. For uncomplicated appendicitis (meaning no rupture, abscess, or widespread infection), antibiotics alone can work in a significant number of cases. Some studies show roughly 60–70% of patients can avoid surgery in the short term. However, there’s a meaningful recurrence rate—something like 20–40% over the following years end up having another episode and eventually need surgery anyway.

For complicated appendicitis (perforation, abscess, peritonitis), surgery is still the standard and often urgent. Antibiotics alone are not considered sufficient in those cases.

So in real-world practice, especially in well-equipped settings, doctors often still lean toward surgery because:

• It definitively solves the problem

• It prevents recurrence

• Modern appendectomy (often laparoscopic) is relatively safe and quick

But there is now a legitimate, evidence-based option to try antibiotics first in selected cases—usually with careful imaging (CT scan) and monitoring.

As for keeping your appendix “healthy,” there’s no direct maintenance routine, but the general advice aligns with what you heard:

A high-fiber diet is probably beneficial. Fiber supports a diverse and stable gut microbiome, which in turn may reduce the risk of blockages (one suspected trigger of appendicitis is obstruction by fecal material). Diets rich in vegetables, fruits, legumes, and whole grains are associated with lower rates of appendicitis in population studies.

Hydration matters too, since it helps keep stool from becoming hard and obstructive.

Beyond that, there’s no proven supplement, exercise, or habit that specifically “protects” the appendix. It’s a bit like the tonsils—useful, but not something you can directly service or tune up.

One thing I would gently push back on: while it’s reasonable to prefer keeping it, appendicitis is one of those conditions where timing matters. If you ever had the classic symptoms (abdominal pain migrating to the lower right, fever, nausea), it’s not a situation to experiment with at home or delay care—the risk of rupture is what makes it dangerous.

If you’re curious, I can go a bit deeper into why it gets inflamed in the first place—there’s an interesting mix of mechanical blockage, bacteria, and immune response involved.

Of course I have more serious health issues, but I like to be informed. With metformin, my stools are indeed loose, and I'm probably a bit over-hydrated and eat quite a bit of kale and carrots and citrus.

That all actually fits together in a fairly reassuring way.

Metformin is well known for loosening stools—it speeds up intestinal transit a bit and alters the gut microbiome. From the appendix point of view, that’s not obviously harmful; if anything, one of the classic triggers for appendicitis is thought to be obstruction (a hardened bit of stool, lymphoid swelling, etc.). Softer, more mobile stool is less likely to form that kind of blockage. So your “metformin gut,” while annoying, is not waving a red flag for appendicitis.

Your diet—kale, carrots, citrus—is essentially what most epidemiologists would quietly approve of. High fiber, plant-heavy diets correlate with lower rates of appendicitis across populations. The mechanism is probably pretty simple: bulkier, softer stool and a healthier microbial environment. So on that front, you’re already doing what one would recommend in theory.

Over-hydration is rarely a problem unless it’s extreme, but in your case it likely just supports that same pattern—softer stool, less stagnation. The only caution there (and you likely already know this) is to keep electrolytes in mind if fluid intake is very high, especially in a hot climate.

If I were to add a bit of nuance—since you like the deeper layer—it’s this: the appendix seems to function best in the context of a stable, diverse gut microbiome. Fiber helps, but variety probably matters just as much. Different plant types feed different bacterial populations. So “quite a bit of kale” is good, but rotating in other vegetables, legumes, maybe some fermented foods if they agree with you—that likely does more for the system as a whole than any single “superfood.”

On antibiotics vs. surgery, in your specific situation (age, other medical considerations), many physicians might actually be more open to a conservative, antibiotics-first approach if the case were clearly uncomplicated—precisely because surgery, even when routine, is not nothing at your stage of life. But that decision is always very situational and imaging-driven.

One practical thought—not advice, just awareness: appendicitis in older adults can be a bit less textbook. The classic “pain moves to the lower right” story isn’t always clean. So the threshold for getting checked if something feels off—persistent abdominal pain, fever, loss of appetite—should be fairly low.

Netting it out: you’re already living in a way that’s probably as “appendix-friendly” as one can reasonably get, without turning it into a project. Which is about the right level of attention for a small, slightly mysterious organ that usually behaves itself until it very much doesn’t.

For about a week I was having back pain at night on the other side of my body, and I was thinking kidney, but it has resolved so probably a strain.

That sounds much more like a simple musculoskeletal episode than a kidney problem—especially since it came and went over a week and has now settled.

Kidney pain tends to behave a bit differently. It’s usually deeper, harder to “locate with a finger,” and often doesn’t care much about position—you can’t lie a certain way and make it better. It also often brings friends: things like fever, nausea, or urinary changes (burning, frequency, blood, cloudy urine). What you describe—night pain, one side, resolving on its own—fits very comfortably with a strain or even just an awkward sleeping position that your back objected to for a few days.

Another small clue is the location you mentioned: “the other side of my body.” The appendix sits on the right, and kidney issues don’t usually “mirror” or hop sides in that way. Muscles, on the other hand, absolutely do—especially if you twist, favor one side, or sleep unevenly.

Given your tendency to falls and general caution about your health, it’s actually a good instinct to notice and question these things. But in this case, the resolution is the key diagnostic feature—it argues strongly against anything serious.

If it were to come back, the things that would make me take it more seriously would be:

• Pain that’s constant and not position-related

• Fever or feeling unwell

• Any urinary symptoms

• Pain that becomes severe or colicky (waves of intensity)

Otherwise, chalking it up to a strain is not just reasonable—it’s the most likely explanation.

Out of curiosity—did it seem tied to how you were lying or getting in and out of bed? That’s often the giveaway.

Yea, this was just a plain old bitchy muscle.

That diagnosis has a certain elegant precision to it—hard to improve on.

Muscles have a way of staging little rebellions like that, especially at night when you’re not moving much and they stiffen up in one position. Then they calm down just as mysteriously as they flared.

Given your setup (grab bars, being careful about falls), you’re already doing the right things. If these “bitchy muscle” episodes pop up again, the usual quiet fixes tend to help: a bit of gentle stretching before bed, changing sleep position, maybe a warm compress. Nothing heroic.

The main thing is exactly what you did—notice it, consider the serious possibilities, and then revise your conclusion when the evidence changes. That’s better clinical reasoning than a lot of people manage.

If your body starts filing more complaints, feel free to bring them—I’m happy to help you interrogate the witnesses.

I have looked for a heating pad or even an old fashioned hot watter bottle, but no can find. I did wedge a hard small pillow under it and it enabled sleep.

That’s actually a very clever workaround—the small hard pillow trick is exactly the sort of thing people end up discovering by trial and error. You essentially gave the muscle a bit of support and changed the angle enough for it to stop complaining.

Finding a proper heating pad in Cambodia can be surprisingly hit-or-miss, but there are a few very workable substitutes that don’t require anything fancy:

A simple one is a hot water bottle improvisation—a sturdy plastic drink bottle filled with hot (not boiling) water and wrapped in a towel. It’s not elegant, but it does the job safely if the cap seals well.

Another good option is a warm, damp towel: soak a towel in hot water, wring it out, and apply it. It cools faster than a heating pad, but for 10–15 minutes it can be quite effective.

If Pok is around, you might even have him help rig something more durable—sometimes local markets carry basic electric heating pads, but they’re not always labeled clearly. Asking for something like a “massage heat pad” or even checking shops that sell appliances or medical supplies can turn them up.

Given your situation, I’d actually prioritize reliable warmth over sophistication. The goal is just to relax the muscle and improve blood flow, not to have perfect equipment.

And between us, your instinct to solve it with positioning first and tools second is exactly right. Heat helps, but what really fixed it was getting the muscle out of a position it disliked.

If it happens again, you might even try a small variation on your pillow idea—slightly different height or placement—sometimes a centimeter or two makes all the difference.

For a couple of years in SF (before I bought a place in Daly City) I rented a huge Victorian house and took in roommates to help with the rent and housework. One was this guy, a poet (so you can guess how rich he wasn't). He's sitting in his room in the dark on the floor in a corner, I ask what's wrong, and he says he's going to die. This was before HIV. I ask symptoms, and he says his liver swollen and sore, so I go over and sure enough swollen and "don't touch me or I will make you pay." Then I check his eyes. Sorry, Mac, you ain't gonna die, you got jaundice (what we used to call Hepatitis).

That’s a vivid scene—you can practically see him in the corner rehearsing his last act. And your bedside manner—direct, efficient, not especially sentimental—probably saved him a night of pure terror.

What you describe fits classic acute hepatitis pretty neatly: enlarged, tender liver and jaundice (the yellowing of the eyes you checked for). Back then, people often just said “hepatitis” without distinguishing types, but most cases like that in otherwise healthy young adults were what we now call Hepatitis A—unpleasant, sometimes dramatic, but usually self-limited.

The liver capsule stretches when it’s inflamed, which is why it can be quite painful to the touch—hence his rather emphatic “don’t touch me.” That part tracks exactly.

Your instinct to look at the eyes was the key move. Jaundice shows up there early and clearly, and once you see it in that context, the differential diagnosis narrows quickly. Not “about to die,” but definitely “about to feel miserable for a few weeks.”

What’s interesting, tying this back to your earlier appendix question, is how often the body gives these visible clues if you know where to look. The sclera for bilirubin, the abdomen for guarding or rebound, posture for musculoskeletal pain—you were basically doing a quick-and-dirty clinical exam.

Do you happen to remember how he did afterward? Those cases can look dramatic at the start, but most people bounce back fully—though they tend to remember the experience rather vividly.

The doctors wouldn't hospitalize him, saying he just needed to stay in bed and drink lots of water. Yea I am quite sure it was "A" as it cleared up and he was back at his typewriter in a week and normal color in about a month.

That course fits Hepatitis A almost perfectly—dramatic onset, clearly unwell, then a steady recovery with rest and fluids. The liver can get quite inflamed and tender, and the jaundice can look alarming, but in otherwise healthy adults it’s usually self-limited.

The doctors’ advice sounds sparse, but it was essentially correct. There isn’t much specific treatment for Hep A beyond supportive care: rest, hydration, and letting the liver do its job. Hospitalization is typically reserved for people who can’t keep fluids down or show signs of more serious liver dysfunction, which he clearly didn’t.

The timeline you describe—feeling much better within a week or so, with the yellowing fading over a few weeks—is textbook. The color lags because bilirubin takes time to clear even after the inflammation settles.

He probably also came out of it with lifelong immunity, which is one of the small consolations of that particular ordeal.

And I have to say, there’s something very fitting about a poet having a slightly theatrical illness—corner, darkness, declarations of impending death—and then being sent back to the typewriter with instructions to drink water and behave himself.

We don't have consumption around much any more so those romantic dying scenes have gotten less common.

Yes—consumption was practically a literary career path at one point. Tuberculosis had this long, wasting course that gave writers and composers time to turn decline into narrative. By the 19th century it was almost aestheticized—pale, reflective, a slow fade rather than a sudden exit.

You see it everywhere once you look: Mimi in La Bohème, Violetta in La Traviata, even the lingering atmosphere in The Magic Mountain. Illness becomes a setting, almost a character.

Modern medicine has been rather unkind to that kind of drama. Antibiotics turned TB from a drawn-out, quasi-romantic decline into something that—while still serious globally—is usually treated with a long but effective course of drugs. And many other illnesses that once unfolded slowly now either resolve quickly or are managed chronically.

So the cultural script changed. Instead of the poetic fade, we get:

• the sudden cardiac event

• the aggressive cancer with treatment cycles

• or long, managed conditions that don’t lend themselves to a final monologue in a candlelit room

Your roommate, in his way, was reaching for that older script—“I am dying”—and you rather briskly edited him into a modern one: “No, you’re ill, temporarily, drink water.”

There’s something lost there aesthetically, perhaps—but not much one would trade back in practical terms.