Introduction to the Human Body PDF

Summary

This document provides an introduction to human anatomy and physiology. The text details the fundamental aspects of both. It covers topics such as macroscopic anatomy, microscopic anatomy, and systemic anatomy. It also explains the interrelationship of structures within a specific body region.

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1. INTRODUCTION
TO THE
HUMAN BODY
 1.1
Overview of
Anatomy & Physiology
Human anatomy is the scientific study of the body’s structures. Some
of these structures are very small and can only be observed and analyzed
with the assistance of a microscope. Other larger structures can readily be
seen, manipulated, measured, and weighed. The word “anatomy” comes
from a Greek root that means “to cut apart.” Human anatomy was
first studied by observing the exterior of the body and observing the
wounds of soldiers and other injuries. Later, physicians were allowed to
dissect bodies of the dead to augment their knowledge. When a body is
dissected, its structures are cut apart in order to observe their physical
attributes and their relationships to one another. Dissection is still used in
medical schools, anatomy courses, and in pathology labs. In order to
observe structures in living people, however, a number of imaging
techniques have been developed. These techniques allow clinicians to
 Like most scientific disciplines, anatomy has areas of specialization. Gross
anatomy is the study of the larger structures of the body, those visible
without the aid of magnification (Figure 1.2 a). Macro- means “large,” thus,
gross anatomy is also referred to as macroscopic anatomy. In contrast,
micro- means “small,” and microscopic anatomy is the study of
structures that can be observed only with the use of a microscope or other
magnification devices (Figure 1.2 b). Microscopic anatomy includes
cytology, the study of cells and histology, the study of tissues. As the
technology of microscopes has advanced, anatomists have been able to
observe smaller and smaller structures of the body, from slices of large
structures like the heart, to the three-dimensional structures of large
molecules in the body.
Gross and Microscopic Anatomy
(a) Gross anatomy considers large structures such as the brain.
(b) Microscopic anatomy can deal with the same structures,
though at a different scale. This is a micrograph of nerve cells
from the brain. LM × 1600.
 Anatomists take two general approaches to the study of the body’s
structures: regional and systemic.

 1. Regional anatomy is the study of the interrelationships of all of the
structures in a specific body region, such as the abdomen. Studying
regional anatomy helps us appreciate the interrelationships of body
structures, such as how muscles, nerves, blood vessels, and other
structures work together to serve a particular body region.

 2. Systemic anatomy is the study of the structures that make up a
discrete body system—that is, a group of structures that work together
to perform a unique body function. For example, a systemic anatomical
study of the muscular system would consider all of the skeletal muscles
of the body.
 Whereas anatomy is about structure, physiology is about function.
 Human physiology is the scientific study of the chemistry and
physics of the structures of the body and the ways in which they work
together to support the functions of life. Much of the study of
physiology centers on the body’s tendency toward
homeostasis. Homeostasis is the state of steady internal conditions
maintained by living things. The study of physiology certainly includes
observation, both with the naked eye and with microscopes, as well
as manipulations and measurements. However, current advances in
physiology usually depend on carefully designed laboratory
experiments that reveal the functions of the many structures and
chemical compounds that make up the human body.
 Physiologists typically specialize in a particular branch of physiology. For example,
neurophysiology is the study of the brain, spinal cord, and nerves and how these work
together to perform functions as complex and diverse as vision, movement, and thinking.
Physiologists may work from the organ level (exploring, for example, what different parts of
the brain do) to the molecular level (such as exploring how an electrochemical signal travels
along nerves).
 Form is closely related to function in all living things. For example, the thin flap of your eyelid
can snap down to clear away dust particles and almost instantaneously slide back up to allow
you to see again. At the microscopic level, the arrangement and function of the nerves and
muscles that serve the eyelid allow for its quick action and retreat. At a smaller level of
analysis, the function of these nerves and muscles likewise relies on the interactions of
specific molecules and ions. Even the three-dimensional structure of certain molecules is
essential to their function.
 Your study of anatomy and physiology will make more sense if you continually relate the form
of the structures you are studying to their function. In fact, it can be somewhat frustrating to
attempt to study anatomy without an understanding of the physiology that a body structure
supports. Imagine, for example, trying to appreciate the unique arrangement of the bones of
the human hand if you had no conception of the function of the hand. Fortunately, your
understanding of how the human hand manipulates tools—from pens to cell phones—helps
you appreciate the unique alignment of the thumb in opposition to the four fingers, making
your hand a structure that allows you to pinch and grasp objects and type text messages.
 1.2
Overview of
Anatomy & Physiology
 Before you begin to study the different structures and functions of the human body, it is
helpful to consider its basic architecture; that is, how its smallest parts are assembled into
larger structures. It is convenient to consider the structures of the body in terms of:
 fundamental levels of organization that increase in complexity:
 subatomic particles,
 atoms,
 molecules,
 organelles,
 tissues,
 organs,
 organ systems, organisms and biosphere
Levels of Structural
Organization of the Human
Body The organization of the
body often is discussed in terms of
six distinct levels of increasing
complexity, from the smallest
chemical building blocks to a
unique human organism.
 The Levels of Organization
 To study the chemical level of organization, scientists consider the simplest
building blocks of matter: subatomic particles, atoms and molecules. All matter in
the universe is composed of one or more unique pure substances called elements,
familiar examples of which are hydrogen, oxygen, carbon, nitrogen, calcium, and
iron.
 The smallest unit of any of these pure substances (elements) is an
atom. Atoms are made up of subatomic particles such as the proton,
electron and neutron. Two or more atoms combine to form a
molecule, such as the water molecules, proteins, and sugars found in
living things.
 Molecules are the chemical building blocks of all body structures.

 A cell is the smallest independently functioning unit of a living organism. Even
bacteria, which are extremely small, independently-living organisms, have a cellular
structure. Each bacterium is a single cell. All living structures of human anatomy
contain cells, and almost all functions of human physiology are performed in cells or
are initiated by cells.
 A human cell typically consists of flexible membranes that enclose cytoplasm
organelles.-a water-based cellular fluid together with a variety of tiny functioning
units called
tissue- is a group of many similar cells (though sometimes composed of a few
related types) that work together to perform a specific function.
organ- is an anatomically distinct structure of the body composed of two or more
tissue
organ system- is a group of organs that work together to perform major functions
or meet physiological needs of the body.
Organ Systems of the Human Body (continued) Organs that work
together are grouped into organ systems.

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1.3 Function of Human
Life

Organization

A human body consists of trillions of cells organized in a way that maintains distinct internal
compartments. These compartments keep body cells separated from external environmental
threats and keep the cells moist and nourished. They also separate internal body fluids from
the countless microorganisms that grow on body surfaces, including the lining of certain
passageways that connect to the outer surface of the body. The intestinal tract, for example, is
home to more bacterial cells than the total of all human cells in the body, yet these bacteria
are outside the body and cannot be allowed to circulate freely inside the body.

Cells, for example, have a cell membrane (also referred to as the plasma membrane) that
keeps the intracellular environment—the fluids and organelles—separate from the extracellular
environment. Blood vessels keep blood inside a closed circulatory system, and nerves and
muscles are wrapped in connective tissue sheaths that separate them from surrounding
structures. In the chest and abdomen, a variety of internal membranes keep major organs such
as the lungs, heart, and kidneys separate from others.

The body’s largest organ system is the integumentary system, which includes the skin and its
associated structures, such as hair and nails. The surface tissue of skin is a barrier that
protects internal structures and fluids from potentially harmful microorganisms and other
toxins.
 Metabolism
 The first law of thermodynamics holds that energy can neither be created nor
destroyed—it can only change form. Your basic function as an organism is to consume
(ingest) energy and molecules in the foods you eat, convert some of it into fuel for
movement, sustain your body functions, and build and maintain your body structures.
There are two types of reactions that accomplish this: anabolism and catabolism.
 Anabolism is the process whereby smaller, simpler molecules are combined into
larger, more complex substances. Your body can assemble, by utilizing energy, the
complex chemicals it needs by combining small molecules derived from the foods you
eat
 Catabolism is the process by which larger more complex substances are broken
down into smaller simpler molecules. Catabolism releases energy. The complex
molecules found in foods are broken down so the body can use their parts to assemble
the structures and substances needed for life.

Taken together, these two processes are called metabolism. Metabolism is the sum
of all anabolic and catabolic reactions that take place in the body (Figure 1.6). Both
anabolism and catabolism occur simultaneously and continuously to keep you alive.
Figure 1.6
Metabolism Anabolic
reactions are building
reactions, and they consume
energy.
Catabolic reactions break
materials down and release
energy.

Metabolism includes both
 Anabolism Catabolism
Requires energy Releases energy

Builds larger, complex molecules from Breaks down large, complex molecules
smaller, simpler ones into smaller, simpler ones

Forms chemical bonds between Breaks chemical bonds within
molecules molecules

Basis Anions Cations

An anion may be defined as A cation may be defined as
Definition an atom or molecule that is an atom or molecule that is
negatively charged. positively charged.

Charge Type Negative Positive
Type of Element Non-Metal Metal
Sulfide, Oxide, Fluoride,
Examples Iron, Lead, Sodium
Chloride
 Responsiveness
 Responsiveness is the ability of an organism to adjust to changes in its internal and
external environments. An example of responsiveness to external stimuli could include
moving toward sources of food and water and away from perceived dangers. Changes
in an organism’s internal environment, such as increased body temperature, can cause
the responses of sweating and the dilation of blood vessels in the skin in order to
decrease body temperature, as shown by the runners in Figure 1.7.

 Movement
 Human movement includes not only actions at the joints of the body, but also the
motion of individual organs and even individual cells. As you read these words, red and
white blood cells are moving throughout your body, muscle cells are contracting and
relaxing to maintain your posture and to focus your vision, and glands are secreting
chemicals to regulate body functions. Your body is coordinating the action of entire
muscle groups to enable you to move air into and out of your lungs, to push blood
throughout your body, and to propel the food you have eaten through your digestive
tract. Consciously, of course, you contract your skeletal muscles to move the bones of
your skeleton to get from one place to another (as the runners are doing in Figure 1.7),
and to carry out all of the activities of your daily life.
Figure 1.7 Marathon
Runners Runners demonstrate
two characteristics of living
humans—responsiveness and
movement. Anatomic
structures and physiological
processes allow runners to
coordinate the action of muscle
groups and sweat in response to
rising internal body temperature.
(credit: Phil Roeder/flickr)
 Development, growth and reproduction

 Development is all of the changes the body goes through in life. Development
includes the process of differentiation, in which unspecialized cells become
specialized in structure and function to perform certain tasks in the body. Development
also includes the processes of growth and repair, both of which involve cell
differentiation.
 Growth is the increase in body size. Humans, like all multicellular organisms, grow by
increasing the number of existing cells, increasing the amount of non-cellular material
around cells (such as mineral deposits in bone), and, within very narrow limits,
increasing the size of existing cells.
 Reproduction is the formation of a new organism from parent organisms. In humans,
reproduction is carried out by the male and female reproductive systems. Because
death will come to all complex organisms, without reproduction, the line of organisms
would end.
1.4 Requirements of
Human Life
 Oxygen
 Atmospheric air is only about 20 percent oxygen, but that oxygen is a key component of
the chemical reactions that keep the body alive, including the reactions that produce ATP.
Brain cells are especially sensitive to lack of oxygen because of their requirement for a
high-and-steady production of ATP. Brain damage is likely within five minutes without
oxygen, and death is likely within ten minutes.
 Nutrients
 A nutrient is a substance in foods and beverages that is essential to human survival. The
three basic classes of nutrients are water, the energy-yielding and body-building nutrients,
and the micronutrients (vitamins and minerals).
 The most critical nutrient is water. Depending on the environmental temperature and our
state of health, we may be able to survive for only a few days without water. The body’s
functional chemicals are dissolved and transported in water, and the chemical reactions of
life take place in water. Moreover, water is the largest component of cells, blood, and the
fluid between cells, and water makes up about 70 percent of an adult’s body mass. Water
also helps regulate our internal temperature and cushions, protects, and lubricates joints
and many other body structures.
 The energy-yielding nutrients are primarily carbohydrates and lipids, while proteins mainly
supply the amino acids that are the building blocks of the body itself. You ingest these in
plant and animal foods and beverages, and the digestive system breaks them down into
molecules small enough to be absorbed. The breakdown products of carbohydrates and
lipids can then be used in the metabolic processes that convert them to ATP. Although you
might feel as if you are starving after missing a single meal, you can survive without
consuming the energy-yielding nutrients for at least several weeks.
 Water and the energy-yielding nutrients are also referred to as macronutrients because the
body needs them in large amounts. In contrast, micronutrients are vitamins and minerals.
These elements and compounds participate in many essential chemical reactions and
processes, such as nerve impulses, and some, such as calcium, also contribute to the
body’s structure. Your body can store some of the micronutrients in its tissues, and draw
on those reserves if you fail to consume them in your diet for a few days or weeks. Some
others micronutrients, such as vitamin C and most of the B vitamins, are water-soluble and
cannot be stored, so you need to consume them every day or two.
Narrow Range of Temperature

You have probably seen news stories about athletes who died of heat stroke, or hikers who
died of exposure to cold. Such deaths occur because the chemical reactions upon which the
body depends can only take place within a narrow range of body temperature, from just below
to just above 37°C (98.6°F). When body temperature rises well above or drops well below
normal, certain proteins (enzymes) that facilitate chemical reactions lose their normal
structure and their ability to function and the chemical reactions of metabolism cannot
proceed.
That said, the body can respond effectively to short-term exposure to heat (Figure 1.8) or cold.
One of the body’s responses to heat is, of course, sweating. As sweat evaporates from skin, it
removes some thermal energy from the body, cooling it. Adequate water (from the
extracellular fluid in the body) is necessary to produce sweat, so adequate fluid intake is
essential to balance that loss during the sweat response. Not surprisingly, the sweat response
is much less effective in a humid environment because the air is already saturated with water.
Thus, the sweat on the skin’s surface is not able to evaporate, and internal body temperature
can get dangerously high.
Figure 1.8 Extreme
Heat Humans acclimate to some
degree to repeated exposure to
high temperatures. (credit:
McKay Savage/flickr)
Controlled Hypothermia

As you have learned, the body continuously engages in coordinated physiological
processes to maintain a stable temperature. In some cases, however, overriding this
system can be useful, or even life-saving.
Hypothermia is the clinical term for an abnormally low body temperature (hypo- =
“below” or “under”).
Controlled hypothermia is clinically induced hypothermia performed in order to reduce
the metabolic rate of an organ or of a person’s entire body.
Controlled hypothermia often is used, for example, during open-heart surgery because
it decreases the metabolic needs of the brain, heart, and other organs, reducing the
risk of damage to them. When controlled hypothermia is used clinically, the patient is
given medication to prevent shivering. The body is then cooled to 25–32°C (79–89°F).
The heart is stopped and an external heart-lung pump maintains circulation to the
patient’s body. The heart is cooled further and is maintained at a temperature below
15°C (60°F) for the duration of the surgery. This very cold temperature helps the heart
muscle to tolerate its lack of blood supply during the surgery.

Some emergency department physicians use controlled hypothermia to reduce damage to the
heart in patients who have suffered a cardiac arrest. In the emergency department, the
physician induces coma and lowers the patient’s body temperature to approximately 91
degrees. This condition, which is maintained for 24 hours, slows the patient’s metabolic rate.
Range of Atmospheric Pressure

Pressure is a force exerted by a substance that is in contact with another substance.

Atmospheric pressure is pressure exerted by the mixture of gases (primarily nitrogen and
oxygen) in the Earth’s atmosphere.

Although you may not perceive it, atmospheric pressure is constantly pressing down on your body.
This pressure keeps gases within your body, such as the gaseous nitrogen in body fluids,
dissolved. If you were suddenly ejected from a space ship above Earth’s atmosphere, you would
go from a situation of normal pressure to one of very low pressure. The pressure of the nitrogen
gas in your blood would be much higher than the pressure of nitrogen in the space surrounding
your body. As a result, the nitrogen gas in your blood would expand, forming bubbles that could
block blood vessels and even cause cells to break apart.
Atmospheric pressure does more than just keep blood gases dissolved. Your ability to breathe—
that is, to take in oxygen and release carbon dioxide—also depends upon a precise atmospheric
pressure. Altitude sickness occurs in part because the atmosphere at high altitudes exerts less
pressure, reducing the exchange of these gases, and causing shortness of breath, confusion,
headache, lethargy, and nausea. Mountain climbers carry oxygen to reduce the effects of both low
oxygen levels and low barometric pressure at higher altitudes (Figure 1.9
Narrow Range of Atmospheric Pressure

Pressure is a force exerted by a substance that is in contact with another substance.
Atmospheric pressure is pressure exerted by the mixture of gases (primarily nitrogen and
oxygen) in the Earth’s atmosphere. Although you may not perceive it, atmospheric
pressure is constantly pressing down on your body. This pressure keeps gases within your
body, such as the gaseous nitrogen in body fluids, dissolved. If you were suddenly ejected
from a space ship above Earth’s atmosphere, you would go from a situation of normal
pressure to one of very low pressure. The pressure of the nitrogen gas in your blood would
be much higher than the pressure of nitrogen in the space surrounding your body. As a
result, the nitrogen gas in your blood would expand, forming bubbles that could block
blood vessels and even cause cells to break apart.
Atmospheric pressure does more than just keep blood gases dissolved. Your ability to
breathe—that is, to take in oxygen and release carbon dioxide—also depends upon a
precise atmospheric pressure. Altitude sickness occurs in part because the atmosphere at
high altitudes exerts less pressure, reducing the exchange of these gases, and causing
shortness of breath, confusion, headache, lethargy, and nausea. Mountain climbers carry
oxygen to reduce the effects of both low oxygen levels and low barometric pressure at
higher altitudes (Figure 1.9).
HEMEOSTATIC IMBALANCE

Decompression Sickness

Decompression sickness (DCS) is a condition in which gases dissolved in the blood or in other
body tissues are no longer dissolved following a reduction in pressure on the body. This condition
affects underwater divers who surface from a deep dive too quickly, and it can affect pilots flying
at high altitudes in planes with unpressurized cabins. Divers often call this condition “the bends,”
a reference to joint pain that is a symptom of DCS.
In all cases, DCS is brought about by a reduction in barometric pressure. At high altitude,
barometric pressure is much less than on Earth’s surface because pressure is produced by the
weight of the column of air above the body pressing down on the body. The very great pressures
on divers in deep water are likewise from the weight of a column of water pressing down on the
body. For divers, DCS occurs at normal barometric pressure (at sea level), but it is brought on by
the relatively rapid decrease of pressure as divers rise from the high pressure conditions of deep
water to the now low, by comparison, pressure at sea level. Not surprisingly, diving in deep
mountain lakes, where barometric pressure at the surface of the lake is less than that at sea level
is more likely to result in DCS than diving in water at sea level.
In DCS, gases dissolved in the blood (primarily nitrogen) come rapidly out of
solution, forming bubbles in the blood and in other body tissues. This occurs
because when pressure of a gas over a liquid is decreased, the amount of gas that
can remain dissolved in the liquid also is decreased. It is air pressure that keeps your
normal blood gases dissolved in the blood. When pressure is reduced, less gas
remains dissolved. You have seen this in effect when you open a carbonated drink.
Removing the seal of the bottle reduces the pressure of the gas over the liquid. This
in turn causes bubbles as dissolved gases (in this case, carbon dioxide) come out of
solution in the liquid.
The most common symptoms of DCS are pain in the joints, with headache and
disturbances of vision occurring in 10 percent to 15 percent of cases. Left untreated,
very severe DCS can result in death. Immediate treatment is with pure oxygen. The
affected person is then moved into a hyperbaric chamber. A hyperbaric chamber is a
reinforced, closed chamber that is pressurized to greater than atmospheric pressure.
It treats DCS by repressurizing the body so that pressure can then be removed much
more gradually. Because the hyperbaric chamber introduces oxygen to the body at
high pressure, it increases the concentration of oxygen in the blood. This has the
effect of replacing some of the nitrogen in the blood with oxygen, which is easier to
tolerate out of solution.