NUR101 Human Biological Science I Introduction of Anatomy & Physiology & Chemistry of Living Things PDF

Summary

This document is an introduction to human biological science, specifically covering anatomy and physiology, as well as the chemistry of living things. It includes course outlines, teaching team details, course requirements, and learning objectives.

Full Transcript

NUR101 Human Biological Science I

Introduction of Anatomy & Physiology
&

Chemistry of Living Things
Ms. Cissy Soong
Reg. MLT I, RN

Course Introduction

Course Outline
Contents

Lecture

Tutorial

4 hours

Laboratory
Session
3 hours

Introduction to human anatomy and physiology

Anatomy and physiology

Chemistry level of living organisms

Cellular level of living organisms

Tissue level of living organisms
Anatomy and physiology of the following human body
systems:

Neurological system

Endocrine system

Musculoskeletal system

Integumentary system

Ophthalmic system

Oto-rhino-laryngeal system

25 hours

6 hours

4 hours

2 hour

Teaching Team
Name of teacher

Office

Telephone
no.

Email

Ms. Cissy Soong
(Course Coordinator)
Ms. Anna Tang (CoTeacher)
Dr. Sara Poon

A812

3653 6764

[email protected]

A318-B

3653 4422

[email protected]

A821

3702 4246

[email protected]

Dr. Martin Leung

Rm 619

3702 4595

[email protected]

Ms. Ellen Ku

A825

3702 4256

[email protected]

Ms. Grace Wan

A824

3702 4425

[email protected]

Mr. Wing Ching Ko

A508

[email protected]

Ms. Ivy Lai

Rm 619

[email protected]

Course Requirement/ Assessment
Tasks
1. Attendance

>80%

2. Continuous assessment (40%)
• Test

19 Oct 2023

• Laboratory report

15 Dec 2023

3. Summative Assessment (60%)
Examination

Examination Period

Course Timetable

Course Timetable

Course Timetable

Course Timetable

Course Timetable

Learning
Objectives

01

Define anatomy and physiology, explain the
relationship between. Identify major levels of
organization in organisms, and major components of
each organ system

02

Describe different body regions, sections, relative
positions, and body cavities. Explain the concept of
homeostasis.

03

Understand the basic chemistry concepts from atoms
to matter. Distinguish between organic and inorganic
compound

04

Explain how the chemical properties of water make life
possible, the importance of pH and acid-base balance.
Understand different types of organic compounds in
human body

Introduction of Anatomy & Physiology

Anatomy
• The study of internal and
external of body
structures and their
physical relationship
among other body parts
• E.g. Structure of heart

• The study of body functions
• Biochemistry
• Genetics
• Study of
• Functions of anatomical
structures
• Individual and cooperative
functions
• E.g. Pumping of the heart

Physiology

• Structure determines the functions
• The principle of complementarity of
structure and functions
• The hierarchy of structural
relationship
• What they are made of
• Where they are located
• Associated structures

• The homeostasis, the
tendency toward internal
balance

Types of Anatomy
Gross Anatomy (Macroscopic Anatomy)Study of structure without using a microscope
• Surface anatomy- exterior features, e.g.
surface marking
• Regional anatomy- body areas, e.g. head
• Systemic anatomy- organ systems, e.g.
cardiovascular system
• Clinical anatomy- medical specialties, e.g.
surgical anatomy
• Developmental anatomy- from conception to
death, e.g. embrology
Microscopic AnatomyStudy of structure with magnification using a
microscope
• Cytology- study of cells and their structures
• Histology- study of tissues and their
structures

Cell PhysiologyStudy of cellular functionProcess within and between cells,
e.g. function of cardiac cell

Organ PhysiologyStudy of organ function- e.g. heart
function
Systemic PhysiologyStudy of system function- e.g.
function of cardiovascular system
Pathological PhysiologyStudy of physiology and effects in
certain diseases- e.g. physiology of
heart failure

Types of Physiology

The Importance of Studying “A & P”
The Study of “Life”
• To discover the unity and the patterns that
underlie this diversity
• To identify problems when the body gets sick

Anatomical Problem

Physiological Problem

E.g. Cardiomegaly
(Enlarged heart)

E.g. Heart failure, ischemic
heart disease, pericardial
effusion, endocarditis,
myocardial infraction

History of A&P Development
Andreas Vesalius
(1514-64)

Aristotle
(384-322 B.C.)

• Anatomist
• Barber- surgeon
removed the odorous
organs form the
cadaver and held them
up for the students to
see
• Published the first
atlas of anatomy

• Greek philosopher
• Write an anatomy
book- “On the Parts
of Animals”

Hippocrates
(460-375 B.C.)
• Greek Physician
• Father of Medicine
• “Hippocratic Oah”- code of
ethic for physicians
• Urges the attribution to
diseases to natural causes,
instead of gods and
demons

Claudius Galen
(129-216 A.D.)
• Greek physician
• Dead body dissection was
banned at that time
• Wrote the most influential
medical textbook
• Based on his guessing of
human anatomy of
gladiators and animal
dissections

Charles Darwin (1809-82)
• Origin of Species by Means of
Natural Selection (1859)Theory of evolution,
restructured biology and
changed the view of our origin,
nature, and place in universe
• The Descent of Man (1871)Emphasized the features of
anatomy and behavior that
reveals how humans related to
other animals

Basic Building
Block of
Medical
Terminology

•

Lots of medical terms come from Greek or Latin
Example

Prefix
(Place at the beginning of
a word)

A-/An-

No or without (e.g. Anaemia, Afebrileno fever)

BiTri-

Two (e.g. Biventricular failure)
Three (e.g. Triceps)

Root
(Central part of a word)

Cardio-

Heart (e.g. Cardiogenic shock)

Pulmo-

Lung

Nephro-

Kidney

Neuro

Nerve

Osteo-

Bone

-otomy

Incision (e.g. Craniotomy)

-ostomy

Get an opening or hole (e.g.
Colostomy)

-ectomy

Removal (e.g. Thyroidectomy)

-itis

Inflammation (e.g. Gastritis)

-megaly

Enlargement (e.g. Cardiomegaly)

Suffix
(The ending part of a
word)

General Orientation of
Human Biology

Characteristics of Life
Metabolism

The Cell
• The smallest unit that can be alive

Differentiation
• Each cell is differentiated into
different structure and function from
its precursor cell

• Catabolism: Chemical reactions
that break down complex
substances into simpler molecules
• Anabolism: Chemical reactions
that build up simple molecules into
complex substance

Excretion
• Removal of waste by metabolic
reaction

Intake & Utilization
• Build of one or more cells
• Intake and utilize energy and
materials

Grow & Reproduction
• Living things can reproduce and
glow

Life
Responsiveness/ Regulation
• Respond to changes in the
environment e.g. Homeostasis

Change Position & Location
• Can occur at all levels of structural
organization

Requirements of Organisms

O2
Water
• Most important chemical in
all living systems
• Require for many metabolic
processes and provide an
environment for them to take
place
• Important in regulating
temperature
• Inside the cells with
substances dissolved to
constitute the intracellular
fluid
• Outside the cells, including
the tissue fluid and the
plasma as extracellular fluid

Oxygen
Food / Nutrients
• Substances that
provide the body
with necessary
02 chemicals in addition
to water
• To provide energy for
the organism

Pressure
Heat

• Used to release
energy from food
substances
• The energy drives
the metabolism

• A form of energy
• Product of metabolic
reactions
• The degree of heat
present partly determines
the rate at which these
reactions occur
• Temperature is a
measure of the degree of
heat
• The more heat, the more
chemical reactions take
place

• An application of force to
something
• Atmospheric pressure- the
force on the outside of the
body due to the weight of air
• Important in breathing
• Hydrostatic pressure- a
pressure a liquid exerts due
to the weight of water above
them
• Blood pressure- heart action
forces blood to flow through
blood vessels

Levels of Organization
The System Level

The Chemical Level

The Chemical Level

The Cellular Level

The Organ Level

The Tissue Level

The Organ Level
The Cellular Level

The Organ System Level
The Tissue Level

The Organism Level

The Organism Level

(Shier, 2015)

The Chemical Level
Atoms
• Compose of Proton, electron, and
neutron
• The smallest chemical units of elements
like Hydrogen, Carbon, Chloride

Molecules
• Group of atoms bond and working
together

The Cellular Level
Cells
• Groups of atoms, molecules
and organelles work together
• Basic structural and functional
units of an organism

Organelles
• Special structures like nucleus,
mitochondria, lysosomes
(Martini, 2015)

• Groups of similar cells
working together to
perform a particular
function
• 8 types of tissues- blood,
bone, epithelial tissue,
cartilage tissue, adipose
tissue, connective tissue,
muscle tissue, and
nervous tissue

The Tissue Level

The Organ Level
Organs
• Groups of tissues work together
• Usually
• Have a recognizable shape
• Composed of 2 or more
types of tissues
• Have specific functions

(Martini, 2015)

The Organ Systems Level
• Groups of related organs working together to have a common function
• Humans have 11 organ systems- Integumentary System, Skeletal System, Muscular System,
Nervous System, Endocrine System, Cardiovascular System, Lymphatic System, Respiratory
System, Digestive System, Urinary System, and Reproductive System

The Organism Level

•All systems of the body
combine to form an organism
•A human is an organism

(Martini, 2015)

S u p e r f i c i a l
A n a t o m y
•

Locating structures on or near the body surface

01

The Anatomical Position
•
•
•
•

02

Stands erect facing the observer
Head level and eyes facing forward
Feet are flat on the floor and directed forward
Hands at sides with palms facing forward

Supine
• Lying down with face up

03

Prone
• Lying down with face down

Anatomical Directions
Anterior/ Ventral
• The front surface
• The belly side
Posterior/ Dorsal
• The back surface
Superior/ Superficial
• At near or relatively close to the body
surface
Inferior
• Towards the superior of the body
• Deep from the surface
Lateral
• Away from the midline

Medial
• Toward to the midline
(Martini, 2015)

Proximal
• Toward the point of the
attachment of the limb to the
trunk
Distal
• Away from the point of
attachment of the limb to the
trunk

Left & Right

(Martini, 2015)

Anatomy Lines
• Anterior View
• Anterior Median Line/
Mid-Line
• Midclavicular Lines

• Lateral View
• Anterior Axillary Line
• Midaxillary Line
• Posterior Axillary Line

• Posterior View
• Posterior Median Line
• Scapular Line

A n a t o m i c a l
Regions/ Landmarks
Major Anatomical Regions
01

Head
• Include skull, face

02

Neck
• Cervical region

03

Trunk
• Three major regions
• Thoracic region
• Abdominal region
• Pelvic region

04

Appendicular
• Upper limbs- arm, forearm,
wrist, hands, and fingers
• Lower limbs- thigh, leg, ankle,
foot, and toes

(Martini, 2015)

Body Regions

(Martini, 2015)

• Abdominopelvic quadrants
• Formed by two perpendicular lines
• Divided into 4 parts• Left upper quadrant (LUQ)
• Right upper quadrant- (RUQ)
• Left lower quadrant- (LLQ)
• Right lower quadrant- (RLQ)

• Abdominopelvic quadrants
• Formed by four perpendicular lines
• Divided into 9 parts• Epigastric region
• Left hypochondriac region
• Right hypochondriac region
• Umbilical region
• Left lumbar region
• Right lumbar region
• Hypogastric region
• Left inguinal region
• Right inguinal region

• Organs insides
• Liver
• Gallbladder
• Stomach
• Spleen
• Large intestine
• Small intestine
• Appendix
• Urinary bladder

Planes and Sections
• Plane• A three-dimensional
axis
• Section• A slice parallel to a
plane

• Used to visualize internal
organization and structure
• Important in radiological
techniques
• MRI
• CT
• PET
(Martini, 2015)

Body
Cavities
•

• Essential Functions• Protect organs from accidental shocks
• Permit changes in size and shape of internal organs
• Serous Membranes• Line body cavities and cover organs
• Consists of parietal layer and visceral layer
• Parietal layer- lines cavity
• Visceral layer- covers organ

7 Body Cavities include•
•

AMET,

Dorsal body cavity with Cranial
cavity & Vertebral cavity
Ventral body cavity consists of
• Thoracic cavity- Superior
mediastinum, Pleural cavity,
Pericardial cavity
• Abdominalpelvic cavityAbdominal cavity & Pelvic
cavity

(Shier, 2015)

•
•
•
•
•

(Martini, 2015)

The Thoracic Cavity
• Consists of two (Left & Right) pleural
cavities separated by mediastinum
Each Pleural Cavity
• Contain a lung
• Lined with a serous membrane
The Pleura consists of Two layers
• Parietal Pleura
• Visceral Pleura
Pleural Fluid
• Lubricates space between two layers
Mediastinum
• Upper portion filled with blood vessels,
trachea, esophagus, and the thymus
• Lower portion contains pericardial
cavity

Thoracic & Pleural Cavities

Abdominalpelvic Cavity
Peritoneal Cavity- Chamber within the
abdominopelvic cavity

Text Here
Easy to change
colors, photos and
Text.

• Parietal peritoneum: lines the internal body wall
• Visceral peritoneum: cover the organs

Abdominal Cavity- Superior Portion

Text Here

Text Here

Easy to change
colors, photos and
Text.

Easy to change
colors, photos and
Text.

Text Here

Text Here

Text Here

Easy to change
colors, photos and
Text.

Easy to change
colors, photos and
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Easy to change
colors, photos and
Text.
(Martini, 2015)

• Diaphragm to top of pelvic bones
• Contains digestive organs
• Retroperitoneal space- contain pancreas, kidneys,
ureters, and parts of the digestive tract

Pelvic Cavity- Inferior Portion
• Within pelvic bones
• Contains reproductive organs, rectum, and bladder

Coordination, Homeostasis & Feedback Systems
Received, Coordination & Response

ack
b
ed
e
F

k
bac
ed
Fe

Pos
i
t
i
ve

• The response of the effector
increases change of the stimulus

Nega
t
i
ve

Positive Feedback

is
as
t
s

Co
or

tion
na
di

• All body systems working together to
maintain a stable internal environment
• Dynamic equilibrium- internal
conditions fluctuate within a limited
range
• Essential to survival

Ho
me
o

Equilibrium

• Systems receive, coordinate and respond to
external and internal changes
• Autoregulation (Intrinsic)- response in a cell,
tissue, or organ to some environment change
• Extrinsic regulation- responses controlled by
nervous and endocrine systems
• 3 components- Receptor, Control Centre &
Effector

Negative Feedback
• The response of the effector negates
the stimulus

Homeostatic Mechanism

Homeostatic Mechanism
Receptor (Sensor/ Detector)
Stimulus
• A stimulus is any disruption or change in a
controlled condition or environment
• E.g. Change in temperature, sound, pH

• A sensor which sense for environmental
changes and stimulus
• Send information by nerve impulses or chemical
signals to control center
• E.g. Nerve endings in the skin, ear, and eye

Control Center

Response
• Response/ effect that responds to the
commands of the control center
• Responds to the stimulus
• E.g. Sweating, regulation

• Receive the information from the receptor
• Sets the range of values that a controlled
condition should be maintained
• Evaluate the input received from the receptorsCoordinate and regulation
• Generate the output commands to an effector if
needed
• E.g. Brain

Effector
• Receives output from the control center
• Produce a response/ effect which responds to the
commands of the control center
• E.g. Muscle, glands and organs

•
•
•

(Shier, 2015)

A process that allows constant
readjustment of physiological
variables
Negative Feedback System- the
response reverse a change of
stimulus
Positive Feedback System- the
effector produces a response that
promotes the initial change

Feedback Systems

Mechanisms of Feedback Systems
Negative Feedback Mechanism
•
•
•

In negative feedback mechanism, the process is initiated by a stimulus
cause the responses slows down or terminate the stimulus
Body is brought back into homeostasis
Normal range is achieved

Positive Feedback Mechanism
•
•
•
•

Positive feedback mechanism involves the promotion of the original
process.
The purpose is to continue the pathway or to increase its activity.
Body is moved away from homeostasis
Normal range is lost
(Martini, 2015)

Section Break
TOILET

TIME

Chemistry of the Living Things

Basic Chemistry

Atoms
•
•
•

•

The smallest and basic unit of matter
All matters (e.g. human, animals, plants,
rocks, ocean, any objects) are made up of
atoms in varying combination
Consists of 2 basic parts:
• Nucleus• Protons (+ve charge)
• Neutrons (neutral- no charge)
• At the center of atom
• Electrons (-ve charge)
• Much lighter than protons
• Surround the neutrons, may
form electron clouds
The mass of atom is mainly depending on
the number of protons and neutrons in the
nucleus

• Anything that takes up space
and mass
• Can be differentiated into pure
substance and mixture
• Mixture:
• Homogenous mixturesame properties
• Heterogeneous mixtureconsists of 2 phases of
different properties:
suspensions & colloids

Matters

•
•

•

Element

•

Elements is a pure substances composed of atoms of only one kind, e.g. O2
Atoms are the smallest particles of an element that still retain the characteristics of
that element
Each element include all the atoms of the same number of protons, and thus the
same atomic number
Cannot be changed or broke down into simpler substance

Atomic Weight
• An average of different atomic
mass & proportion of its
different isotopes
• Very close to its mass
number of most common
isotope of that element

(Martini, 2015)

Isotopes

• Atoms of the same element whose
nuclei contain a different number of
neutrons
• Different isotopes of an element
have similar chemical properties
except for mass number

Chemical Bonds, Molecules & Compound
Chemical Bond
• Atoms can attach to other atoms by
forming chemical bonds
• When atoms form chemical bonds,
electrons can be gaining, sharing or losing
• Types of bonding- Ionic bond, Covalent
bond, Hydrogen Bond, Van der Waals
Force

Molecule

O

O

• The combination when 2 or more same element
atoms share electrons, e.g. O2

O

Compound
• Substance from by two or more elements,
e.g. H2O

H

H

Types of Chemical Bonds
Hydrogen Bond
• Weak force which acts
between adjacent
molecules
• Attraction between the
slight positive charge on
the hydrogen atom of a
polar covalent bond and
a slight negative charge
of another polar
covalent bond

Van der Waals Force

Ionic Bond
• Atoms that gain (cations) or lose electrons
(anions) become electrically charged and
called ions
• The attraction between the opposite charges
of the anions and cations, forms the bonding
and becomes ionic compound

(Martini, 2015)

Covalent Bond
• Weak and brief
attractive force
generated by
random disturbances
in the electron
clouds of adjacent
atoms

• Atoms bond by sharing electrons
• Single covalent bond- share one pair of electron
• Double covalent bond- share 2 pairs of electron
• Nonpolar covalent bond- equal sharing of
electron
• Polar covalent bond- unequal sharing of
electron

State of Matters
Solid
• Atoms arranged in fixed position with shape
and volume
• Have less kinetic energy

Liquid
• Have a constant volume but do not
have definite shape
• Have more kinetic energy than solid

Gases
• Do not have a definite shape or volume
• Contain highest amount of kinetic energy
• Gases molecules is allowing move freely

Synthesis Reaction
• Chemical reaction that small molecules
assemble into larger molecules
• Synthesis of new molecules called
anabolism

Ty p e s o f

Chemical
Reaction
• Cells stay alive and functional by controlling chemical
reactions to provide energy and make up its metabolism
• In chemical reactions, chemical bond changes take place
as atoms in the reacting substance (reactants),
rearrange to form different substance (products)
• Chemical reactions are reversible

Decomposition Reaction

• Chemical reaction that breaks
a molecule into smaller
fragments
• The decomposition reaction of
molecules within human body
is called catabolism
Exchange Reactions
• Parts of the reacting molecules are
shuffled around to produce new products

Reactant

Redox Reaction
Oxidation
• The reactant loss of electron
• E.g. Gain from oxygen, Loss from
hydrogen

Product
Reduction
• The product gain of electron
• E.g. Loss from oxygen, gain from
hydrogen
H2- reducing agent
CuO- oxidizing agent

H2- reducing agent
Fe3O4- oxidizing agent

Oxidizing Agent
• Accept electron
• Oxidizing agent reduces itself to
oxidize the other

Reducing Agent
• Give electron
• Reducing agent oxidizes itself to
reduce the other

Organic and Inorganic Compound
Organic Compound
• Contain carbon and hydrogen
for forming its primary structure
• E.g. Carbohydrate, lipids,
proteins

Inorganic Compound
• Contain positive and negative
ions for forming its primary
structure
• E.g. Water, acids, bases, salts

• The most important substance in the body
• Makes up of 60% of the total body weight
• An excellent solvent• a liquid or gas in which other material (solute) has been
dissolved
• Participate in chemical reactions• An ideal medium for chemical reaction
• Absorbs and release heat very slowly
• Moderate the effect of changes in the environmental
temperature
• Help to maintain homeostasis of the body temperature
• Require large amount of heat to change status from liquid to gases
• Provide an excellent cooling mechanism
• Serve as a lubricant
• Major part of saliva, mucus, and other lubricating fluids
• Necessary in thoracic and abdominal cavities, and joints

Inorganic Compound- WATER

The Concept of pH & Acid-Base Balance

Acid
(Martini, 2015)

•
•
•
•

Dissociates in water to form
hydrogen ions (H+)
Proton (H+) donor
Strength of acid depends on
dissociation level and
concentration level
Acidosis- process increase
acidity in the blood and
other body tissues (Blood
pH<7.35)

•
•
•

•
•
•

The concentration of hydrogen ions (H+) in a solution
More H+ ions means low pH, fewer H+ ions mean
higher pH
pH scale range from 0-14
• 0 - <7 (acidic)
• 7 (neutral)
• >7- 14 (basic/alkaline)
Body fluids must contain balanced quantities of acids
and bases to ensure homeostasis
Changes in pH will disrupt the cellular and tissue
function
Blood pH: 7.35-7.45

Base/ Alkaline
•
•
•
•

Dissociates in water to form
hydroxide ions (OH-)
Proton (H+) acceptor
Strength of acid depends on
dissociation level and
concentration level
Alkalosis- process that the
blood and other body fluid
become more alkaline
( Blood pH >7.45)

Buffer System
in pH Maintenance
• A Buffer Solution is an aqueous solution
consist of mixture of weak acid and conjugate
base or a weak base and a conjugate acid
• A Buffer is a mixture whose pH change very
little when a small amount of strong acid or
base is added to the buffer solution
• The importance of moderate pH changes in
human body to maintain constant pH
conditions

• 3 buffer mechanisms in body:
• Body fluid buffer
• Respiratory buffer
• Renal buffer

Buffer
Solution

Organic Compound
in Human Body
L
Carbohydrates

Lipids

Nucleic acid- DNA
& RNA

Proteins

Adenosine Triphophate
(ATP) & Adenosine
Diphosphate (ADP)

Carbohydrates
• The most important fuel or energy source for our human body
• E.g. Glucose, glycogen, starch
• Organic molecules that contain carbon hydrogen and oxygen
in a ratio of 1:2:1 (C6H12O6)
• Types of carbohydrates• Monosaccharide (Simple sugar)- E.g. Glucose, Fructose,
Galactose
• Disaccharide- E.g. Sucrose, Lactose, Maltose
• Polysaccharide- E.g. Starch

PolysaccharideStarch

L I P I D
• Hydrophobic (Insoluble in water) organic
molecule composed of carbon, hydrogen and
oxygen
• Essential structural components of all cellsmake up of cell membranes
• Important energy reserves
• Act as medium for essential vitamin dissolved
• Adipose tissue- thermal insulation and shockabsorbing cushion function for vital organ
• Classification• Fatty acids- saturated and unsaturated fat
• Phospholipids
• Steriods
(Shier, 2015)

PROTEINS
•
•
•
•
•

Polymers of the simple monomer- amino acids
Contain carbon, hydrogen, oxygen, nitrogen
Amino acids link up together and become peptide
Dipeptide, Tripeptide, Polypeptide
Different sequence of amino acids produce
different protein (great variety of protein)
• Largely responsible for the body cells structure,
e.g. enzymes, antibodies, hormones

Enzymes

• Most biochemical reactions do not take place
spontaneously or occur slowly
• Enough energy must be provided as activation energy
to start up the reaction
• Enzymes are proteins, act as catalysts which can
speed up the chemical reactions
• Promote chemical reactions by lowering the activation
energy required
• Factors affect enzyme function: Temperature, pH

(Martini, 2015)

Nucleic Acid, DNA & RNA
• Nucleic acid- huge molecule contain carbon,
hydrogen, oxygen, nitrogen, and phosphorus
• Monomers is nucleotides made with pentose
sugar-deoxyribose & ribose, phosphate group
and nitrogen bases (Adenine, Guanine,
Thymine, Cytosine, Uracil)
• 2 types of nucleic acid• DNA- Deoxyribose Nucleic Acid
• Long double helix chain of
nucleotides
• Consists of deoxyribose and bases
(A,T,G,C)
• Complementary base pairing- A
with T, G with C
• Forms the inherited genetic material
inside each human cell
• Gene- a segment of a DNA molecule
• RNA- Ribose Nucleic Acid
• Single strain of nucleotides
• Consists of ribose and bases
(A,U,G,C)
• Relays instructions from the genes to
transcript amino acids
(Martini, 2015)

A d e n o s i n e Tr i p h o s p h a t e ( AT P )
& Adenosine Diphos phate (ADP)
• Main energy source for most cellular processes
• The building blocks of ATP are carbon, nitrogen, hydrogen, oxygen &
phosphorus
• Transfer energy to power cellular activities
• ATP is used in• Muscles contraction
• Synthesis of DNA and RNA
• Movement of structures within cells
• Transport substance across cell membranes

(Martini, 2015)

REFERENCE
Marieb, E. N., & Keller, S. M. (2019). Essentials of Human
Anatomy & Physiology, Global Edition. Pearson.
Martini, F. H., Nath, J. L., Bartholomew, E. F., & Ober,
W. (2015). Fundamentals of Anatomy and
Physiology. 2001. Pentice Hall: New Jersey,
657-687.
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Reference Videos
• Atoms https://youtu.be/zGr6an_FpoI

• Ionic and Covalent Bonds https://youtu.be/_y5Tm-F82g0
• Catalysts and Enzymes https://youtu.be/E6DQZI86UIQ
• Nucleic Acids https://youtu.be/SeOrvA9ikW8
• DNA & RNA- Overview of DNA & RNA
https://youtu.be/GhABWQC3YDs

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TOILET

TIME