Answer:
Most general problem: Homeostasis would be thrown off.
Explanation:
When a person sweats, they are trying to cool themselves off from a high internal body temperature, sweating when cold can make the person colder and make it even harder for that person to maintain homeostasis without throwing multiple body functions out of sync.
However there is a condition that is associated with Hyperhyrosis (increased sweating) that makes a person sweat when cold: cold sweats, however this is also concerning when a person is cold. But as long as a person has no other symptoms, it is no need for concern.
Other than that, organs can take damage. It would be like the skin going into goose bumps when a person is getting heat stroke, the organs are too hot as is the skin, but it is unable to let any response out to maintain homeostasis.
Cold sweats are also triggered by a fight or flight responce. So the main take away is that the body would not know how to react because Homeostasis has been thrown off.
Positive feedback amplifies changes, so if your body used this to regulate temperature, you would sweat when cold, further lowering your body temperature. This could lead to dangerous situations, such as hypothermia. Normally, the body uses negative feedback to regulate temperature.
If the body used positive feedback to regulate body temperature, it would disrupt the body's homeostasis. Positive feedback amplifies changes rather than counteracting them like negative feedback. So, if you began to sweat when your body temperature decreased, you would lose even more body heat, causing your body temperature to drop further. This could lead to a dangerous situation, such as hypothermia, where your body's temperature falls too low to perform physiological functions correctly.
Normally, body temperature is regulated by negative feedback. When the body gets too warm, it sweats to cool down, and when the body gets too cold, it shivers to produce heat. Thus, flipping this balance would disrupt the body's ability to maintain a stable internal environment.
#SPJ3
The cytoplasm is where cellular respiration starts off. Here, glucose gets disassembled into smaller molecules. Additionally, a small amount of energy is released. The mitochondrion hosts the second stage.
The Krebs cycle, oxidative phosphorylation, and glycolysis—an anaerobic process—are the three phases of aerobic cellular respiration.
The Krebs cycle, the second phase of cellular respiration, happens in the matrix. On the inner membrane, electron transport occurs in the third stage.
Glycolysis, the citric acid cycle, and oxidative phosphorylation are the three basic processes that take place during cellular respiration. The citric acid cycle happens in the mitochondrial matrix, oxidative phosphorylation happens on the inner mitochondrial membrane, and glycolysis happens in the cytoplasm.
What two anaerobic cellular respiration pathways are there? Instead, some species use anaerobic respiration, which doesn't need oxygen, to make ATP from glucose. Fermentation is a crucial method of producing ATP without the use of oxygen. Fermentation comes in two flavors: lactic acid fermentation and alcohol fermentation.
Where do aerobic phases occur? The mitochondrial matrix of the cell is where aerobic respiration takes place.
To Learn more About cellular respiration, Refer:
#SPJ2
The first stage of cellular respiration occurs in the cytoplasm. This is where glucose is broken down into smaller molecules. A small amount of energy is also released. The second stage occurs in the mitochondria. This is where the small molecules combine with oxygen to produce water, carbon dioxide, and a large amount of energy.
(1) It regulates the secretion of digestive
enzymes.
(2) It promotes sperm production in males.
(3) It influences the development of adult sex
characteristics.
(4) It maintains blood sugar levels.
B. slowly degrading chemicals
C. coastal mining booms
D. improperly disposed trash
Irregular galaxy
Spiral galaxy
Elliptical galaxy
Random Galaxy
...
Because Reasons
Answer:
Random
Explanation:
b. Once the enzyme binds to the specific substrate molecule, structural changes can occur in the active site to accomodate the product.
c. Once the enzyme binds to a specific substrate molecule, subtle structure changes occur in the active site, which are reverted when the reaction is over.
Answer:
The main pigment responsible for the yellow color of urine and the brown color of feces is called urobilin.
Explanation:
Here's how it works:
1. When red blood cells break down in the body, a molecule called bilirubin is produced. Bilirubin is a yellow pigment.
2. Bilirubin is transported to the liver, where it undergoes further processing.
3. In the liver, bilirubin is conjugated with glucuronic acid, forming a water-soluble compound called bilirubin glucuronide.
4. Bilirubin glucuronide is then secreted into the bile, a digestive fluid produced by the liver.
5. The bile flows into the small intestine, where it aids in the digestion and absorption of fats.
6. In the intestine, bilirubin glucuronide is broken down by bacteria into urobilinogen.
7. Some urobilinogen is reabsorbed into the bloodstream and eventually excreted by the kidneys, giving urine its yellow color.
8. The remaining urobilinogen is further processed by bacteria in the colon, resulting in the formation of urobilin. Urobilin gives feces its brown color.
It's important to note that factors such as hydration levels and certain medications can influence the color of urine. In some cases, a darker yellow color may indicate dehydration, while lighter or clear urine may indicate excessive hydration.
Similarly, changes in diet, certain medications, and underlying health conditions can affect the color of feces. If you notice any significant changes in the color of your urine or feces, it's always a good idea to consult a healthcare professional for further evaluation.