Part 37 (1/2)

559. No one can doubt that respiration and animal heat are closely connected. Those animals whose respiratory apparatus is the most extended, have the highest temperature. An example is seen in birds, whose organs of respiration extend over a large part of the body, and their temperature is 12 above man; while the respiratory apparatus of cold-blooded animals, as some kinds of fish, is imperfect, and only a small quant.i.ty of blood is subjected, at any time, to the effects of respiration.

560. To understand the process by which heat is generated in the human system and in animals, it will be necessary to state: 1st. That the apparent heat of a body, as perceived by the touch, or as indicated by a thermometer, is not the measurement of heat contained in the body, or its capacity for heat.

_Ill.u.s.tration._ If we mix one pound of water, at the temperature of 60, with another pound at 91, the resulting temperature will be exactly the medium, or 75. But, if we mix a pound of water at 60 with a pound of quicksilver at 91, the resulting temperature will be only 61, because the capacity of water for heat is so much greater than that of quicksilver, that the heat which raised the quicksilver 31 will raise the water only 1.

561. 2d. When the density and the arrangement of the atoms of a body are changed, its capacity to hold heat in a latent state is altered.

If it will retain more, heat will be absorbed from contiguous and surrounding substances; but, if its capacity for caloric is lessened, heat will be set free and given out to surrounding bodies.

The objection? 559. In what do all the physiologists of the present day concur? How is it proved that respiration and animal heat are closely connected? 560. What is said of the apparent heat of bodies?

How is this ill.u.s.trated? 561. What is the effect when the density and the arrangement of the atoms of a body are changed?

_Ill.u.s.trations._ 1st. Ice and salt, (Chl. of Sodium,) when mixed, are converted into a fluid. In this state they will hold more heat than when solid. The heat necessary to produce this change is drawn from the surrounding medium, which is made proportionally colder by the loss of caloric imparted to the ice and salt. It is by this chemical process that ”ice-cream” is made.

2d. On the other hand, mix water and sulphuric acid, (oil of vitriol,) of the temperature of 60, and the mixture will become quite warm, and will freely impart its heat to surrounding and contiguous objects.

562. The same principle is exhibited, when oxygen unites with an inflammable body, as in the burning of wood, coal, oil, &c. In combustion, the oxygen of the atmosphere unites with carbon and hydrogen, and carbonic acid and water are produced. This process, according to all the known laws of caloric, is attended with heat. The quant.i.ty of heat disengaged in combustion is always in proportion to the amount of carbon and hydrogen consumed; thus a piece of wood weighing one pound, in burning slowly, would give out the same quant.i.ty of heat as a pound of shavings of the same wood, in burning rapidly. Upon these principles, the production of animal heat may be understood.

563. The food contains carbon and hydrogen. These exist in the chyle.

The old and waste atoms of the body likewise contain the same elements. In the lungs the oxygen and nitrogen of the inspired air are separated. It is now supposed that the oxygen enters the capillary vessels of the lungs, and mingles with the blood, with which it is carried to the heart and thence to the nutrient capillary vessels of every part of the system.

Give the 1st ill.u.s.tration. The 2d. 562. What changes take place when oxygen unites with an inflammable body? To what is the quant.i.ty of heat proportionate in combustion? Give an example. 563. How are carbon and hydrogen supplied to the system? How the oxygen? Where does the oxygen mingle with the blood?

564. In the capillary vessels, the oxygen of the arterial blood unites with the carbon and hydrogen which the refuse materials contain, and carbonic acid and water are formed. The combustion of carbon and hydrogen in the capillaries of every part of the system, (the lungs not excepted,) is attended with a disengagement of heat, and the carbonic acid and water are returned to the lungs in the dark-colored blood, and evolved from the system.

565. Sir Benjamin Brodie and some others have maintained, that the heat of the system is generated exclusively by the influence of the brain and nerves. This theory is discarded by most physiologists; yet it is true that the nervous system exercises a great influence over the action of the capillary vessels in the process of nutrition, secretion, and absorption. When these operations are most active, the change among the particles of matter of which the body is composed, is then greatest, and the generation of heat is increased in a corresponding degree.

566. The necessity of pure, red blood in the production of animal heat, is shown when the vessels that carry blood to a limb are ligated, or tied; the part immediately becomes colder. The necessity of nervous influence is seen in the diminished temperature of a paralytic limb.

567. Our next inquiry is, By what means is the uniformity of temperature in the body maintained? As there is a constant generation of heat in the system, there would be an undue acc.u.mulation,--so much so as to cause disagreeable sensations,--if there were no means by which it could be evolved from the body, or its production lessened.

564. Where does it unite with the carbon and hydrogen contained in the body, and how is heat generated? 565. What was the theory of Sir Benjamin Brodie? Is this theory in general discarded? What is true of this theory? 566. How is the necessity of pure, red blood and nervous action shown in the production of animal heat?

568. It has been ascertained that the princ.i.p.al means by which the system is kept at a uniform temperature, is the immense evaporation from the skin and lungs. These membranes, in an ordinary state, are constantly giving out water, which is converted into vapor, and carried off by the surrounding air. The quant.i.ty of heat abstracted from the system to effect this, depends on the rapidity of the change of air, its temperature, and the amount of water it contains in a state of vapor. The quant.i.ty removed is greatest when the air is warm and dry, and the change, or current, rapid.