Essentials of Anatomy and Physiology

Regulation of Heat Loss

1. The hypothalamus is the thermostat of the body
   and regulates body temperature by balancing heat
   production and heat loss.


2. The hypothalamus receives information from its
   own neurons (blood temperature) and from the
   temperature receptors in the dermis.


3. Mechanisms to increase heat loss are vasodilation
   in the dermis and increased sweating. Decreased
   muscle tone will decrease heat production.


4. Mechanisms to conserve heat are vasoconstriction
   in the dermis and decreased sweating. Increased
   muscle tone (shivering) will increase heat produc-
   tion.

Fever—an abnormally elevated body temper-
ature

1. Pyrogens are substances that cause a fever: bacteria,
   foreign proteins, or chemicals released during
   inflammation (endogenous pyrogens).


2. Pyrogens raise the setting of the hypothalamic
   thermostat; the person feels cold and begins to
   shiver to produce heat.


3. When the pyrogen has been eliminated, the hypo-
   thalamic setting returns to normal; the person feels
   warm, and sweating begins to lose heat to lower the
   body temperature.


4. A low fever may be beneficial because it increases
   the activity of WBCs and inhibits the activity of
   some pathogens.


5. A high fever may be detrimental because enzymes
   are denatured at high temperatures. This is most
   critical in the brain, where cells that die cannot be
   replaced.

Metabolism—all the reactions within the
body

1. Anabolism—synthesis reactions that usually
   require energy in the form of ATP.


2. Catabolism—decomposition reactions that often
   release energy in the form of ATP.


3. Enzymes catalyze most anabolic and catabolic reac-
   tions.

Cell Respiration—the breakdown of food
molecules to release their potential energy
and synthesize ATP (Fig. 17–3)

1. Glucose oxygen yields CO 2 H 2 O ATP 
   heat.


2. The breakdown of glucose involves three stages:

glycolysis, the Krebs cycle, and the cytochrome

(electron) transport system (see also Table 17–3).

3. The oxygen necessary comes from breathing.


4. The water formed becomes part of intracellular
   fluid; CO 2 is exhaled; ATP is used for energy-
   requiring reactions; heat provides a body tempera-
   ture.

Proteins and Fats—as energy sources (see

Table 17–4 for hormonal regulation)

1. Excess amino acids are deaminated in the liver and
   converted to pyruvic acid or acetyl groups to enter
   the Krebs cycle. Amino acids may also be converted
   to glucose to supply the brain (Fig. 17–3).


2. Glycerol is converted to pyruvic acid to enter the
   Krebs cycle.


3. Fatty acids, in the process of beta-oxidation in the
   liver, are split into acetyl groups to enter the Krebs
   cycle; ketones are formed for transport to other
   cells (see Fig. 17–3).

Energy Available from Food

1. Energy is measured in kilocalories (Calories):
   kcal.


2. There are 4 kcal per gram of carbohydrate, 4 kcal
   per gram of protein, 9 kcal per gram of fat. With
   reference to food, kilocalories may be called calo-
   ries.

Synthesis Uses of Foods (Fig. 17–4)

1. Glucose—used to synthesize the pentose sugars for
   DNA and RNA; used to synthesize glycogen to
   store energy in liver and muscles.


2. Amino acids—used to synthesize new proteins and
   the non-essential amino acids; essential amino
   acids must be obtained in the diet.


3. Fatty acids and glycerol—used to synthesize phos-
   pholipids for cell membranes, triglycerides for fat
   storage in adipose tissue, and cholesterol and other
   steroids; essential fatty acids must be obtained in
   the diet.


4. Any food eaten in excess will be changed to fat and
   stored.


5. Vitamins and minerals—see Tables 17–5 and 17–6.

Metabolic Rate—heat production by the

body; measured in kcal

1. Basal metabolic rate (BMR) is the energy required
   to maintain life (see Box 17–4); several factors
   influence the metabolic rate of an active person.

414 Body Temperature and Metabolism