INTRO Physiology.pdf

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COURSE: INTRODUCTION TO PHYSIOLOGY

Dr. (Mrs.) A. A Bayo-Olugbami
 Suggested textbooks and resources …..
Medical Physiology (Guyton and Hall) Review of Medical Physiology, 23th Ed. (W.F. Ganong)

Vander’s Human Physiology, 11th Ed. (Widmaier, Raff,
Strang)
 DEFINITIONS
 Physics + Biology = Physiology
 The branch of science dealing with the basic functions of living
organisms.
 Science of “function”
 Physiological: “Normal”; not pathological. It means proper ties
belonging to normal functions of tissues, organs or body...
 It is the scientific study of body functions and mechanisms
 Physiology is the science of life. It is the branch of biology that aims to
understand the mechanisms of living things, from the basis of cell
function at the ionic and molecular level to the integrated behaviour of
the whole body and the influence of the external environment.
 Physiology is an experimental scientif ic discipline and is of central
importance in medicine and related health sciences. It provides a
thorough understanding of normal body function, enabling more
effective treatment of abnormal or disease states.
 Physiology is the study of animal (including human) function and
can be investigated at the level of cells, tissues, organ systems
and the whole body. The underlying goal is to explain the
fundamental mechanisms that operate in a living organism and
how they interact.
WHY PHYSIOLOGY?
Research in physiology helps us to understand how the body works in health and
how it responds and adapts to the challenges of everyday life;
it also helps us to determine what goes wrong in disease, facilitating the
development of new treatments and guidelines for maintaining human and animal
health.
The emphasis on integrating molecular, cellular, systems and whole body function is
what distinguishes physiology from the other life sciences.


 What do physiologists do?
All over the world, physiologists are working in universities, in research
institutions, in biotechnology companies and in the pharmaceutical industry to
advance our understanding of how the body functions.
Physiology is an exciting and dynamic discipline that underpins translational
and clinical medicine. It also provides the interface between the physical
sciences and the life sciences.
Physiologists study every aspect of the way human and other animal bodies
work. Some physiologists investigate the behavior of individual proteins in
single cells. Others are researching the interaction of cells in tissues, organs
and systems or study the integration of these systems to control the whole
complex organism.
They provide the foundation for many biological and clinical sciences,
including medicine and veterinary science.
They work alongside elite athletes, helping to improve their performance
and avoid injury, or they investigate how the body adapts to extreme
environmental challenges, such as deep sea diving or prolonged space flight.
Physiology is recognized globally.
 Physiologists can travel the world to conferences and meetings to present their
f indings to other scientists. Some physiologists report scientif ic developments for
newspapers, journals and other media, or play an advisory role to Government or
charitable organizations.
Physiologists also use their skills in the legal arena, engaging in complex issues of
patent law, or in education, inspiring and nurturing the next generation. Studying
physiology opens doors to employment in all these areas and more.
Physiology involves many vital concepts, and homeostasis is one of them. It is the
process through which a nearly stable internal environment is maintained in the
body so that cellular functions can proceed at maximum efficiency.
Every body structure contributes in maintaining the internal environment within a
normal range. Changes in the normal range in the body due to infection, or disease
lead to symptoms and outward clinical signs.
A l t e r a t i o n s i n h o m e o s t a s i s c a n b e e f f e c t o f a d i s e a s e.

Understanding the control of homeostasis is very vital to pinpoint the root cause of
any disease.
Not all physiologists are found in research laboratories, though. Physiologists also
work with patients in hospital clinics, helping with the diagnosis and management
of disease.
 HISTORY OF PHYSIOLOGY
The study of physiology traces its roots back to ancient India and Egypt.
As a medical discipline, it goes back at least as far as the time of
Hippocrates, the famous “father of medicine” – around 420 BC.
Hippocrates coined the theory of the four humors, stating that the body
contains four distinct bodily f luids: black bile, phlegm, blood, and yellow
bile. Any disturbance in their ratios, as the theory goes, causes ill health.
Claudius Galenus (c.130-200 AD), also known as Galen, modif ie d
Hippocrates’ theory and was the f irst to use experimentation to derive
information about the systems of the body. He is widely referred to as the
founder of experimental physiology.
It was Jean Fernel (1497-1558), a French physician, who first introduced the
term “physiology,” from Ancient Greek, meaning “study of nature, origins.”
Another leap forward in physiological knowledge came with the publication
of William Harvey’s book titled An Anatomical Dissertation Upon the
Movement of the Heart and Blood in Animals in 1628.
 HISTORY CONT…
Harvey was the first to describe systemic circulation and blood’s journey
through the brain and body, propelled by the heart.
From here on in, the field of physiology opened up, and progress was made
quickly:
Joseph Lister, 1858: initially studied coagulation and inf la mmation
following injury, he went on to discover and utilize lifesaving antiseptics.
Ivan Pavlov, 1891 – conditioned physiological responses in dogs.
August Krogh, 1910 – won the Nobel Prize for discovering how blood f low
is regulated in capillaries.
Andrew Huxley and Alan Hodgkin, 1952 – discovered the ionic mechanism
by which nerve impulses are transmitted.
Andrew Huxley and Hugh Huxley, 1954 – made advances in the study of
muscles with the discovery of sliding filaments in skeletal muscle.
Structural and functional hierarchy
Physiological terms;
Function:
Things to do...
Mechanism:
How to do...
Organization of life:
Cell is the basic unit of life.
Hierarchical organization of life:
Cells, tissues, organs, organ, systems
and organism
 Organization of the Body
Structural Hierarchy
Atoms: oxygen, carbon, hydrogen
Molecules: water, sugar, peptides
Macromolecules: proteins, polysaccharides
Organelles: compartments within cell that cannot survive in
isolation
Cells: structural and functional unit of organisms
Tissues: organization of cells with a common function
Organs: structures composed of at least 2 tissues
Organ Systems: organs operating to accomplish a common
function
Organ-system
Cardiovascular System
Respiratory System
Digestive System
Urinary System
Reproductive System
Musculoskeletal System
Nervous System
Endocrine System
Immune System