Human Anatomy & Physiology I Course Notes Wk 2 Fall 2024 PDF

Summary

These course notes cover the basics of human anatomy and physiology, focusing on cells and their functions. The document describes cell structure, characteristics of living organisms, and levels of structural organization in the body.

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Biology 1103/1109 Human Anatomy & Physiology I Course Notes Wk 2 Fall 2024

WEEK 2 Unit 4: Cell Structure and Function

Readings: OpenStax Textbook unit 4

I. Specify the characteristics associated with life and explain why the cell is the basic unit
of life.

No single characteristic defines life, rather, there is a set of general characteristics which
matter must possess before it is considered to be living. In this objective, we will examine
these characteristics and consider why they are applied to a cell.

First, living organisms exchange materials with their immediate environment. Some materials
are taken in and other materials are released. Our cells take in nutrients and respiratory gases,
and release wastes, on an ongoing basis. All of our cells absorb needed materials from, and
deposit waste materials into, the extracellular fluid.

Secondly, living matter can obtain energy from organic molecules. For example, cells take in
sugars and metabolize these sugars to obtain cellular energy which can then be used to perform
cellular activities.

Thirdly, living matter can synthesize complex organic molecules. For example, proteins
and fats are only found in living cells or organisms or in situations where living cells have
deposited the molecules.

The fourth characteristic of living matter is that it can reproduce.

The fifth characteristic is that living organisms can respond to stimuli present in the
environment. For example, cells and organisms respond to cold temperatures by moving to a
warmer environment, or by altering their physiology to make more heat.

The cell is considered the basic unit of life because a cell is the simplest structure that
possesses all the basic characteristics of living matter. Many of these characteristics are more
appropriately assigned to individual cells, rather than the whole organism.

II. Describe the levels of structural organization in the body.

Cells are the basic structural and functional units in the body. They are composed of chemical
substances, organelles, and membranes that are necessary to maintain life. The major
chemicals are organic and inorganic molecules.

Although cells are the basic unit of life they do not exist independently of each other. Rather, in
order to carry out their functions, they are organized together into groups called tissues. A
tissue is a group of similar cells and their associated extracellular materials, which have a
similar origin and perform special functions. Because the cells perform the same function
and have a similar origin and appearance.

The tissues in turn are organized into organs. An organ is a structure with a definite form and
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 Biology 1103/1109 Human Anatomy & Physiology I Course Notes Wk 2 Fall 2024

function composed of two or more tissues.

In both cases the organs contain multiple tissue types. Each tissue is in a different location
and is different in composition and structure, which reflects the different functions each
tissue performs in fulfilling the general function as a whole, which is to digest and store food
in the case of the stomach or pump blood throughout the body in the case of the blood vessel.

Organs, in turn, are arranged into organ systems, which consist of a group of organs
that interact to perform a general function. Finally, all of these organ systems collectively
comprise the body as a whole.

III. Describe the structure and the functions of major components of a cell.

Organelles are structures within cells that have specialized functions. Table 1 summarizes the
basic structures and functions of the organelles.
a. The cell membrane (plasma membrane) surrounds the cell and its primary
functions are to regulate what materials enter and leave the cell, and to allow
communication with the extracellular environment.
b. The endoplasmic reticulum is a series of interconnected tubes and membranes that
extend through the cytoplasm. There are two distinct kinds of endoplasmic reticuli (ER)
- the rough ER and the smooth ER.
The rough ER possesses membranes studded with attached ribosomes. The rough ER
represents a transport system involved in processing and sorting proteins for export
to the Golgi apparatus. The rough ER also produces some distinct groups of proteins
(see “bound ribosomes” below).
The smooth ER is a continuation of the rough ER, but its membranes do not carry
any ribosomes. The smooth ER has a number of functions, such as:
(i) lipid synthesis, metabolism and transport; (ii) sex steroid hormone
synthesis (in certain cells); and (iii) drug detoxification.
c. Ribosomes provide the sites where information from the DNA is used to make proteins.
There are two types of ribosomes: free ribosomes, which float in the cytoplasm; and
attached ribosomes, which are attached to the membranes of the endoplasmic
reticulum. Attached ribosomes are also sometimes called “bound” or “fixed” ribosomes.
Free ribosomes produce proteins that are used immediately in the cytosol of the cell.
Attached ribosomes produce three distinct groups of proteins: (i) proteins to be exported
out of the cell; (ii) cell membrane proteins; and (iii) proteins to be used inside
membranous organelles.
d. The Golgi apparatus (Golgi complex) consists of a stack of flattened membranous
sacs. The function of the Golgi apparatus is to take the proteins

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Biology 1103/1109 Human Anatomy & Physiology I Course Notes Wk 2 Fall 2024

made by bound ribosomes and modify, concentrate, package, and ship the proteins to their
final destinations (outside the cell, in the cell membrane, or inside membrane-bound organelles).
e. Lysosomes are small sacs bounded by a single membrane. They contain enzymes which can digest
all the different types of organic molecules found inside of cells. Lysosomes perform a number
of functions including: (i) the breakdown of bacteria, viruses, and toxins brought into the cell by
phagocytosis;
(ii) the breakdown old organelles, activating the release of stored molecules; and
(iii) autolysis (apoptosis), which is the self-destruction of injured or dying cells.
f. Mitochondria are generally bean-shaped structures; although their shape may change. They are
surrounded by very distinctive double membranes, with the inner membrane being highly folded.
Mitochondria are the sites of cellular respiration-a process which breaks down glucose and
produces adenosine triphosphate (ATP) for the cells to use as an energy source. The number
of mitochondria per cell may vary widely, from about 100 to several thousand.
g. Vesicles (vacuoles) are membrane bound sacs that may contain food particles, other solids or
liquids. Vesicles function in storing, importing or exporting materials.

The nucleus houses the DNA, which contains the information required to make proteins. By
determining which proteins will be made, the nucleus regulates all cellular activities. Most cells
possess a single nucleus although larger cells (like skeletal muscle cells) may possess several nuclei,
and one type of cell (red blood cells) does not have a nucleus.
h. The nuclear envelope is a double membrane with pores that regulate the passage of material into
and out of the nucleus (Figure 3.26 Marieb & Hoehn 11th ed.; Figure 4.6 OpenStax).
i. chromosomes
When a cell prepares to divide, the chromatin in the nucleus coils and condenses to form short, rod-
like structures called chromosomes. As the nucleus disappears, chromosomes appear, and vice
versa. Chromosomes carry genes which transmit genetic information from one generation to the
next (Figure 3.27 Marieb & Hoehn 11th ed.; Figure 4.6 OpenStax).
j. nucleolus
Inside the nucleus are normally one or two darker regions called the nucleolus, or nucleoli,
respectively. The function of the nucleoli is to produce the basic subunits of ribosomes. The
ribosomal subunits are then transferred to the cytoplasm, and ribosomes are assembled in the
cytoplasm (Figure 3.26 Marieb & Hoehn 11th ed.; Figure 4.6 OpenStax).

IV. Define metabolism, and distinguish between anabolism and catabolism.

Cell metabolism is the sum total of all the chemical processes that go on in a cell and these chemical
processes can be divided into two types-anabolic reactions and catabolic reactions. Anabolic reactions
are building up processes, as when complex molecules are built up from simpler building block
molecules. Catabolic reactions are break down processes, as when complex molecules are broken down
into simpler building block molecules. So the sum total of all anabolism and all catabolism is
metabolism. A distinguishing feature between anabolism and catabolism is that, in anabolic reactions,
energy is utilized whereas in catabolic reactions, energy is released. For example, when glucose is
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Biology 1103/1109 Human Anatomy & Physiology I Course Notes Wk 2 Fall 2024

broken down, energy is released. However, energy is used when starch is made from glucose subunits.

V. Describe the cellular processes involved in the growth of the human body from a fertilized egg
to an adult.

A number of basic cellular changes occur as an individual grows from a fertilized egg. The most
important process is cell division. All of the trillions of cells in our bodies arose through cell
reproduction starting from a single fertilized egg.
Once cells divide, they grow and increase in size. For example, nerve cells first appear as relatively
small cells but then they elongate to become extremely long cells. Similarly, muscle cells grow to
become extremely long cells as muscles are formed.

Very early in life, cells in different parts of the body specialize and take on particular structures and
functions. Some embryonic cells become liver cells; other cells become nerve cells, and so on. Cells
develop along different pathways as different sets of genes are activated in different cells early in
development. The development of specific and distinctive features in cells is called cell differentiation.

Specialized cells are arranged, according to function, into tissues and subsequently organs, organ systems
and finally a complete human being.

VI. Define cell specialization and describe its importance to an organism.

All cells have a similar structure early in development. Initially the human body begins as a single
cell, a fertilized egg. This cell divides many times, producing thousands of cells. The process
continues until eventually a whole new individual is produced. At first the cells are identical. However,
they eventually divide unevenly, producing a size difference, and then take on different shapes.
Cell specialization is defined as the tendency of a particular cell type to have a special shape or
structure which is related to the special functions the cell carries out. This process of cell
specialization at first occurs during embryonic and fetal development, but continues throughout life as
certain specialized cells are produced by other non-specialized cells which are dividing. The importance
of cell specialization is that it increases the efficiency of the body. The same cell type cannot be
expected to perform all of the body’s various functions efficiently. Different shapes and internal
structure are better suited to carry out different functions. Having different cell types for different
functions allows for a greater speed of activity and a greater effectiveness in performing the
various activities. This will be further illustrated in the next objective.

VII. Describe the general characteristics of each of the following cell types and relate their
characteristics to their functions: nerve cell, muscle cell, red blood cell (erythrocyte), white blood
cell (leukocyte).

These four cell types are shown in Figure 1. Notice how they are markedly different from each other in
size and appearance.

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Biology 1103/1109 Human Anatomy & Physiology I Course Notes Wk 2 Fall 2024

Skeletal
muscle

Smooth
muscle Erythrocyte
Leucocyte
Neuron

Figure 1. Examples of Different Cell Types

The cell on the far left is a nerve cell (Figure 1A). The function of a nerve cell is to conduct an
electrical impulse from one part of the body to another part. It acts as a communication line. Notice that
the cell has numerous processes around its body. These processes will receive impulses from another
cell - either a receptor or another nerve cell. The longer process extending below will then relay the
impulse somewhere else. Such a cell structure is well suited for receiving and transmitting impulses.
The next pair of cells consists of a striated muscle cell and a smooth muscle cell (Figure 1B & C). A
muscle is designed to pull on a bone or to collapse a tube or sac. In order to create such a movement a
muscle cell is elongated, allowing a maximum amount of movement when the cell contracts.
Shown in Figure 1D is a red blood cell (erythrocyte). The cell on the left is viewed from the top
surface, and the one on the right is viewed from the side. The shading in the center of the cell on the
left is not a nucleus, but rather demonstrates the depressed center of the cell, giving it a doughnut
shaped appearance (without the hole). A major feature of the mature red blood cell is the lack of a
nucleus (notice that the other cell types illustrated here each have nuclei). This suggests that the red
blood cell has a reduced metabolism and as a result, it uses little oxygen. The function of the red blood
cell is to carry oxygen to different parts of the body and it is important that it does not use up much of
the oxygen it must deliver. The shape of the red blood cell (flattened) also increases its surface area
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Biology 1103/1109 Human Anatomy & Physiology I Course Notes Wk 2 Fall 2024

relative to its volume, which allows for a greater movement of gases across its surface.
Finally, the cell on the far right is a white blood cell (leucocyte; Figure 1E), in particular one
which ingests foreign materials. It is large, which allows it to surround and ingest bacteria. It also has
a flexible shape which is related to its role in engulfing bacteria.

Unit 5: Cell Biology: Membrane Transport

Readings: OpenStax Textbook unit 5

I. Describe the “fluid mosaic” model of membrane structure including the membrane
components.

The Singer-Nicholson model is also known as the fluid mosaic model of the cell membrane (see pp.
64-65 Marieb and Hoehn 11th ed.; Figure 5.3 OpenStax). The backbone of the membrane is
formed by two layers of phospholipid molecules arranged to form a bilayer. Proteins are inserted into
the lipid bilayer. The proteins are divided into two categories, integral proteins and peripheral
proteins, based on the way they associate with the membrane. Integral membrane proteins penetrate
directly within the lipid bilayer, either completely spanning the membrane or being partially embedded
in the membrane. Those integral proteins that span the membrane, or the transmembrane proteins,
play an important role as transport proteins. Some transport proteins have a hydrophilic channel
through which certain molecules or atomic ions pass to cross the membrane. Others move their
“passengers” across the membrane by changing their conformation (see Objective 4). In both cases,
transport proteins are specific for the substances they translocate.

Peripheral membrane proteins are not inserted into the lipid bilayer, but are associated with the inner or
outer surfaces of the membrane. The outer surface of the plasma membrane also has a glycocalyx. The
glycocalyx is a sugar coating formed by short or long chains of sugars attached to proteins (which are
then called glycoproteins and proteoglycans) as well as sugars attached to lipids (which are then called
glycolipids). The glycocalyx helps protect the cell from mechanical and chemical damage and also plays
an important role in cell to cell recognition. It is like a fingerprint and helps cells recognize other cells
of the same kind to form tissues and to reject foreign cells. In many ways, a cell’s glycocalyx serves as
its “identification”. For example, people who have the same blood type (A, B, AB, or O) all have a
particular array of glycoproteins on the surface of their red blood cells.

II. Describe how the structure of the cell membrane affects membrane permeability.

The hydrophobic interior of the phospholipid bilayer is a barrier to most hydrophilic molecules.
Lipid bilayers are generally impermeable to ions and charged molecules, no matter how small.
On the other hand, they are permeable to hydrophobic molecules. The rate at which
molecules diffuse across the membrane varies depending on the molecule’s size and solubility
properties. The smaller the molecule and the more hydrophobic or nonpolar the molecule is,
the faster it will diffuse across the membrane. S m a l l hydrophobic molecules such as
molecular oxygen and carbon dioxide can rapidly diffuse across the lipid bilayer. Larger
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Biology 1103/1109 Human Anatomy & Physiology I Course Notes Wk 2 Fall 2024

uncharged molecules (such as glucose), because of its size, hardly diffuses at all through the
lipid bilayer. Water moves through the lipid bilyayer via specific protein channels called
aquaporins.

In order for cells to take up nutrients and get rid of wastes, cell membranes must allow the
passage of many molecules which will not diffuse across the lipid bilayer. The way these
molecules cross the membrane is through specialized transport proteins. Transport proteins
function in various ways, and two major classes of membrane transport proteins can be
distinguished: carrier proteins and channel proteins. Carrier proteins bind to the molecule they
are transporting on one side of the membrane and physically transport them to the other side.
Channel proteins form tiny hydrophilic pores through which solutes can move.

These physical characteristics of the membrane, that is, both the presence of the lipid bilayer
as well as the specific transport proteins make it selectively permeable (semipermeable).

III. Describe the following passive processes: diffusion, facilitated diffusion and osmosis. Explain
the function of each in a cell.

A solution is a mixture of a solvent and a solute (or solutes). A solute is simply a substance
that dissolves in a solvent, while a solvent is the substance into which the solute
dissolves. For example, if salt is added to water, the salt dissolves. In this example, water is
the solvent, and salt is the solute. In cells, water is always the solvent.

The water inside a living cell contains many dissolved materials including sugars and proteins.
Water outside a cell also contains various solutes.

Diffusion is defined as the movement of solute molecules from an area of high solute
concentration to an area of lower solute concentration. In gases, liquids, or solids,
molecules move about at random. They do so because they possess internal kinetic energy
and they move on their own. Consequently, molecules move in all possible directions until
they become evenly distributed in a given space. Even though the solute molecules are
moving in all directions, the net flow is from an area of high solute concentration to an area of low
solute concentration. See also Figures 3.5 & 3.6 in Marieb and Hoehn (11th ed.; Figure 5.4 OpenStax).

Diffusion occurs within a solution, but diffusion is also very important in transporting solutes across the
cell membrane. In this case, the solute must travel through a selectively permeable cell membrane.

The semipermeable nature of a membrane is due to its structure. As mentioned in section 2, charged
molecules or larger polar molecules cannot diffuse through the bilipid layer. Instead, they are
transported by facilitated diffusion, with the assistance of carrier or channel proteins in the cell
membrane which allow the movement of solute from an area of high solute concentration to an area of
low solute concentration. For example, as illustrated in Figure 3.6b Marieb and Hoehn (11 th ed.;
Figure 5.5 OpenStax), glucose is moved into a cell via facilitated diffusion. Glucose combines with
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Biology 1103/1109 Human Anatomy & Physiology I Course Notes Wk 2 Fall 2024

the carrier molecule in the membrane, and then the carrier molecule changes shape and carries glucose
across the membrane. The glucose is then deposited on the other side of the membrane. In this
example, it is interesting to note that facilitated diffusion for glucose is accelerated by the action of
insulin, a hormone which lowers blood sugar levels.

Facilitated diffusion is similar to simple diffusion in that it does not require an expenditure of energy
by the cell and that it moves materials along a concentration gradient. However, it differs from simple
diffusion in that it transports molecules which cannot pass through the lipid bilayer, and requires
a carrier or a channel molecule to cross a semipermeable membrane.
Osmosis refers to the diffusion of solvent (water). Osmosis is defined as the passive movement of
water molecules through a semipermeable membrane from an area of high water concentration to
an area of low water concentration; or alternatively, from an area of low solute concentration to an
area of high solute concentration.

Osmosis occurs when there is a difference in the concentration of water (solvent) on either side of a
semipermeable membrane. Water will move from an area of low solute concentration (i.e. an area
where water is in high concentration) to an area of high solute concentration (i.e. where water is in low
concentration). See Figures 3.6d & 3.7 Marieb and Hoehn 11th ed.; Figure 5.6 OpenStax). Osmosis
does not require any input of energy by the cell. However, it does require a membrane which is
selectively permeable (i.e. the membrane must be permeable to water, but not to the solute). Water moves
through the lipid bilayer via specific protein channels called aquaporins.

IV. Describe and explain the effects of placing red blood cells in hypertonic, hypotonic and isotonic
solutions, respectively.

See Figure 3.8 Marieb & Hoehn,11th ed.; Figure 5.7 OpenStax).
If an erythrocyte is placed in water containing low concentration of solutes (a hypotonic
solution), water moves into the cell by osmosis. Water pressure builds up inside the cell, and it may
burst if too much water enters the cell. Cell bursting in this manner is called lysis, and in erythrocytes it
is specifically referred to as hemolysis.

Osmosis can also produce the opposite effect and cause too much water to leave a cell. If a cell is
placed in a solution containing a high concentration of solutes which cannot cross the membrane
(a hypertonic solution), water moves from the inside of the cell to the outside. The erythrocyte
dehydrates and shrinks. This process of dehydration (water loss) is termed crenation in red blood cells.

For erythrocytes placed in water containing the same concentration of solutes inside and
outside the cells (an isotonic solution), the water molecules diffuse across the cell membranes at
an equal rate, but in opposite directions. Therefore the cells stay the same size since there is not net
gain or loss of water.

V. Describe the following active processes: primary and secondary active transport, endocyotsis (
phagocytosis, pinocytosis), and exocyotsis. Explain the function of each in a cell.
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Biology 1103/1109 Human Anatomy & Physiology I Course Notes Wk 2 Fall 2024

Active transport is defined as the movement of solute molecules through a protein pump from an
area of low solute concentration to an area of high solute concentration. See Focus Figure 3.2 p
74 & Figure 3.9 in Marieb and Hoehn (11th ed.).

Active transport differs from diffusion in several ways. One way is in the direction of movement of
solute molecules. In active transport, solute molecules move from an area of low solute concentration
to an area of high solute concentration. Recall that in diffusion, solute molecules move in the
opposite direction. In diffusion, solute molecules move from an area of high solute concentration to
an area of low solute concentration. A second difference is that active transport requires cellular
energy whereas diffusion does not require cellular energy. A third difference is that active transport
requires a protein pump, whereas diffusion does not.

Phagocytosis is an active process by which a cell can take in large pieces of solid material,
including in some cases, other cells. In phagocytosis, the cell membrane flows around a large piece
of material and engulfs it. The membrane surrounding the material then pinches off on the inside and
forms a vesicle which travels through the cytoplasm. Phagocytosis is used by some body cells to
engulf and digest bacteria and dead cells. Phagocytosis is illustrated in Figure 3.11a Marieb and
Hoehn,11th ed.; Figure 5.9 OpenStax).

While relatively few cells use phagocytosis, pinocytosis is a routine activity of most cells. In
pinocytosis, part of the cell membrane is drawn into the cell with the extracellular fluid and dissolved
molecules to form a pocket in the cell membrane. The pocket transforms into a small vesicle and is
transported into the cell interior, where it releases materials needed by the cell. Pinocytosis is
illustrated in Figure 3.11b of Marieb and Hoehn (11th ed.; Figure 5.9 OpenStax). Pinocytosis differes
from phagocytosis by the mechanism by which material is brought into the cell and also on a matter of
scale: Phagocytosis deals with larger objects (e.g. cell debris, bacteria), while pinocytosis much smaller
molecules (e.g. protein molecules).

In relation to the processes described in objectives 8 and 9, it should be noted that the terms
phagocytosis and pinocytosis are both processes of cellular ingestion by which material external to
the cell is brought into the cell. The general term for these processes is endocytosis. Material may
be transported out of the cell by the process of exocytosis, which is essentially a process of
cellular excretion or secretion which occurs when vesicles fuse to the outer membrane and
release material to the outside of the cell.

a) Diffusion is a process which allows cells to obtain or release a variety of materials. For
example, when air enters into the lungs, oxygen dissolves in the water on the inner surfaces of
the lungs. Then, oxygen diffuses into cells lining the lungs, and eventually diffuses further into
the blood. The movement of dissolved gases into and out of the blood is based on diffusion.
Diffusion is effective in situations where materials must be moved along a concentration
gradient that is from high concentration to low concentration of the solute.
b) Facilitated diffusion is essential in allowing the movement charged and large solute molecules
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Biology 1103/1109 Human Anatomy & Physiology I Course Notes Wk 2 Fall 2024

along a concentration gradient across the cell membrane. (For example, the transmission of a nerve
impulse depends, in part, on the opening of sodium channels which allow for the diffusion of
sodium into the cell)
c) Osmosis is the movement of water and is primarily important in maintaining the proper pressure
within cells. In humans osmosis is important in allowing us to move water into, and out of,
cells. Because osmosis is a passive process, it is not directly regulated by the cell. However,
osmosis is indirectly regulated by the cell as it controls the solute concentrations by active
transport. For example, if a cell increases its concentration of Na+ by active transport, then more
water will flow into that cell by osmosis.
d) Active transport is important because cells may require nutrients (such as sugars and salts)
to be maintained at different concentrations inside the cell than is normally present outside the
cell, or to counteract the effects of diffusion. Consequently, the cell must expend energy to
maintain solute concentration differences on either side of the membrane. Table 1 shows the
concentrations of some ions and molecules found in both the extracellular and intracellular fluids.
Notice that sodium ions (Na+) are 13 times more concentrated in the extracellular fluid than in the
intracellular fluid. The cell must expend energy to export sodium ions which enter by diffusion in
order to maintain this concentration difference. Potassium ions (K+), on the other hand, are much
more concentrated inside the cell than outside, and active transport must be used to bring this ion
into the cell, even though potassium ions might be moving out by diffusion. The cell membrane
is impermeable to sodium ions but “leaky” to potassium ions. Active transport is very important in
maintaining the concentrations of solutes necessary for normal physiology to occur and to regulate
osmosis.
e) Phagocytosis is important in humans as it is used to destroy unwanted materials or organisms.
For example, white blood cells can engulf bacteria and digest them within the cell as a mechanism
for counteracting infections.

f) Pinocytosis is a mechanism by which cells can take in larger dissolved molecules.

To summarize, cells utilize three active processes to pass materials through the cell membrane. The
differences between these processes are predominately the size of the materials brought into the cell.
In active transport, ions and small molecules are moved; in pinocytosis, large molecules dissolved in
fluid such as proteins are carried through the membrane in solution, and in phagocytosis large pieces
of material or whole cells are moved through the membrane.

A summary of transport processes is presented in Figure 1. This summary is divided into active and
passive processes. See also Tables 3.2 & 3.3 in Marieb and Hoehn (11th ed.).

Figure 1. Summary of Methods of Acquisition of Materials by the Cell.

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Acquisition is by:

Active processes (cellular
Passive processes
energy required)
(cellular energy not required)

Osmosis Diffusion Facilitated Phagocytosis Active Pinocytosis
Diffusion Transport

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