Transport Across Cell Membranes PDF

Summary

This document discusses transport across cell membranes, including passive and active transport mechanisms. It explores how solutes and water move across the lipid bilayer and examines the importance of transport in cellular functions. The text also touches upon the role of circulation in transporting essential substances to and from cells.

Full Transcript

Transport across cell membrane I
Describe how solutes or water can cross a lipid bilayer
How do solutes and H2O cross cell membrane?

Transport Across Cell Membranes

Cell membranes are selectively permeable, meaning they regulate what substances can
enter and leave the cell. The transport of solutes and water (H2O) across the membrane
is essential for many physiological processes, such as nutrient uptake, waste removal,
and maintaining the cell's internal environment.

What is a Solute?

A solute is any substance that is dissolved in a solvent (usually water). Examples of
solutes include:

Ions (e.g., Na⁺, K⁺, Ca²⁺, Cl⁻)

Small molecules (e.g., glucose, amino acids, vitamins)

Drugs (e.g., antibiotics, painkillers)

Gases (e.g., O₂, CO₂)

Why is it Important for Solutes to Cross Membranes?

1. Oxygen for Respiration:

o Cells need oxygen (O₂) for aerobic respiration, a process that generates
energy. Oxygen needs to diffuse across the cell membrane from the
bloodstream into the cell to be used in mitochondria for energy production.

2. Food Through the Gut:

o The gut absorbs nutrients like glucose, amino acids, and vitamins into the
bloodstream. These nutrients must cross the intestinal cell membranes for
absorption.

3. Maintaining Membrane Potential:

o Membrane potential refers to the difference in charge across the cell
membrane. The distribution of ions (e.g., Na⁺, K⁺) across the membrane is
crucial for maintaining the cell's resting membrane potential, which is
essential for functions like nerve impulse transmission and muscle
contraction.

4. Changing Membrane Potential:

o Changes in the ion concentrations across the membrane can alter the
membrane potential, which is vital for processes like action potential
generation in neurons and muscle cells. The movement of ions like Na⁺ and
K⁺ is key to transmitting signals in the nervous system.
How Do Solutes and H2O Cross Cell Membranes?

There are different methods of transport across the cell membrane, depending on the
size, charge, and polarity of the solute:

1. Passive Transport (No Energy Required):

o Simple Diffusion: Small, non-polar molecules like oxygen (O₂) and carbon
dioxide (CO₂) can pass directly through the lipid bilayer.

o Facilitated Diffusion: Solutes (e.g., glucose, ions) that are too large or
polar to pass through the lipid bilayer use transport proteins (e.g.,
channels or carriers) to move across the membrane along their
concentration gradient.

o Osmosis: The movement of water (H₂O) through the membrane. Water
moves through aquaporins (special water channels) or directly through
the membrane via osmosis, from areas of low solute concentration to
areas of high solute concentration.

2. Active Transport (Requires Energy):

o Primary Active Transport: Uses ATP to pump solutes against their
concentration gradient via a pump protein (e.g., the Na⁺/K⁺ pump, which
moves Na⁺ out of the cell and K⁺ into the cell).

o Secondary Active Transport: Involves the use of an ion gradient (created
by primary active transport) to move other solutes against their
concentration gradient. This doesn't directly use ATP but relies on the
energy stored in ion gradients.

Summary of Key Concepts:

Solute: Any substance dissolved in a solvent, like Na⁺, glucose, or drugs.

Importance of Solute Transport:

o Supplies oxygen and nutrients to cells for processes like respiration and
digestion.

o Maintains and regulates membrane potential and allows changes in
potential for cell signaling.

Transport Mechanisms:

o Passive Transport: No energy required, solutes move down their
concentration gradient (diffusion, facilitated diffusion, osmosis).

o Active Transport: Energy required, solutes move against their
concentration gradient (primary and secondary active transport).

Understanding how solutes and water cross membranes is crucial for understanding
basic cellular functions and physiological processes.
Circulation and Transport in the Blood

The circulatory system is responsible for the movement of substances, such as oxygen,
nutrients, and waste, throughout the body. It works in tandem with cell membranes to
maintain homeostasis by ensuring the necessary exchanges between the blood and the
cells. Let's break it down:

Circulation: Movement in the Blood

Blood carries oxygen, nutrients, hormones, and waste products to and from the
cells.

Blood flows through a network of arteries, veins, and capillaries, which is the
heart of the circulatory system.

Transport Across Cell Membranes

Cells are the functional units of the body, and for them to maintain their internal
balance, they need continuous input of essential nutrients and the removal of
waste products.

The movement of substances from the blood to the cells (and vice versa) happens
through cell membranes by various transport mechanisms.

Nutrients In

The blood brings essential nutrients to the cells, which are transported across the cell
membranes through various processes:

1. Glucose: The primary energy source for most cells. It enters cells through
facilitated diffusion via specific transport proteins (e.g., GLUT transporters).

2. Amino acids: These are transported into the cells via active transport, using ATP
to move them against their concentration gradients.

3. Vitamins and minerals: These essential molecules are transported into cells either
by facilitated diffusion or active transport depending on the type of nutrient and
its concentration gradient.

Waste Out
Cells generate waste products as by-products of metabolism, and these need to be
transported out of the cells to be excreted from the body. These include:

1. Carbon dioxide (CO₂): A waste product of cellular respiration, which is
transported out of the cells via simple diffusion across the cell membrane and
carried by the blood to the lungs for exhalation.

2. Urea: A waste product from protein metabolism, which is transported out of the
cells by active transport and carried in the blood to the kidneys for excretion.

3. Excess ions (e.g., potassium, sodium): These are also transported out of cells via
active transport, like the Na⁺/K⁺ pump, to maintain ion balance.

Blood-Circulation-Cell Interaction

Blood serves as the transport medium that carries these essential substances to
the cells and removes waste products.

The capillaries, the smallest blood vessels, are the primary sites where exchange
between blood and cells happens.

o Oxygen and nutrients from the blood pass through the thin capillary walls
into the cells.

o Waste products (like CO₂ and urea) diffuse from the cells into the blood to
be transported to organs (lungs, kidneys) for removal from the body.

Summary

Circulation: Blood moves through the body to deliver nutrients to cells and remove
waste.

Transport Across Cell Membranes: Essential nutrients (glucose, amino acids,
vitamins) enter the cell, while waste products (CO₂, urea, excess ions) exit.

Blood and Cells: The blood carries substances to and from the cells via the
circulatory system, using various transport mechanisms to maintain homeostasis.

The interaction between blood circulation and cell membrane transport is crucial for
sustaining life by ensuring cells receive what they need and dispose of waste effectively.
★ Circulation and Transport of Glucose:

Glucose, a critical energy source, must undergo a series of steps to move from the
intestine to muscle cells. These steps involve crossing several lipid membranes (cell
membranes) and interstitial spaces, both during absorption and delivery to the muscle.
Here's a breakdown of the process:

1. From the Intestine to the Blood:

Glucose first needs to cross several barriers to enter the bloodstream from the intestine:

1. Intestinal Lumen (Inside the Intestine):

o Glucose is absorbed from the intestinal lumen (inside the gut) into the
epithelial cells of the intestinal lining. This process occurs via active
transport using sodium-glucose cotransporters (SGLT1), which transport
glucose against its concentration gradient by coupling it with the
movement of sodium ions (Na⁺) down their gradient.

o Membranes involved: The glucose crosses the apical membrane (the side
facing the intestinal lumen) of the epithelial cell.

2. Epithelial Cell (Intestinal Cell) Cytoplasm:

o Once glucose enters the epithelial cell, it moves across the cytoplasm to
the basolateral membrane (facing the blood). The movement from the
cytoplasm to the blood is via facilitated diffusion through GLUT2
transporters, which allow glucose to pass down its concentration gradient.

3. Basolateral Membrane (Epithelial Cell to Blood):

o The glucose crosses the basolateral membrane of the epithelial cell and
enters the interstitial fluid (the fluid in the space between cells). This is a
simple diffusion process via the GLUT2 transporter.

4. Interstitial Space (Between Intestinal Cells and Blood Vessels):

o The glucose now moves through the interstitial space to enter the blood
capillaries. The interstitial space contains extracellular fluid that allows
 glucose to diffuse from the intestinal cells into the capillaries.

5. Into the Bloodstream:

o The glucose enters the bloodstream, where it is carried through the
circulatory system to its target organs, including the muscles.

2. Circulating in the Bloodstream:

Once glucose enters the bloodstream, it is transported through the body via the
circulatory system. The glucose can be directed to various organs, including the muscles.

The bloodstream serves as a delivery system, transporting glucose to areas where
it is needed, including tissues with high energy demands like muscle cells.

3. From the Blood to Muscle Cells:

After circulating in the blood, glucose needs to exit the blood and enter muscle cells. This
process involves crossing three more lipid membranes:

1. Endothelial Cells of Capillaries:

o Glucose first crosses the capillary endothelial cell lining the blood vessels
via facilitated diffusion through GLUT4 transporters, which are present in
the muscle tissue endothelial cells. This is the first membrane that glucose
crosses in order to leave the blood and enter the muscle.

2. Interstitial Space (Between Capillaries and Muscle Cells):

o After leaving the blood, glucose moves across the interstitial space (which
contains extracellular fluid) to the muscle cell membrane. Glucose diffuses
through this space toward the muscle cells.

3. Muscle Cell Membrane (Plasma Membrane):

o The final barrier is the muscle cell membrane. Glucose enters the muscle
cell via GLUT4 transporters, which are activated in muscle cells in response
to insulin. In the presence of insulin, GLUT4 transporters are inserted into
the muscle cell membrane, facilitating glucose uptake into the cell.

o Insulin, released from the pancreas in response to high blood glucose
levels, signals muscle cells to increase the number of GLUT4 transporters
on the plasma membrane, promoting glucose entry into the cell.

Summary:

1. From Intestine to Blood:

o Glucose crosses the intestinal epithelial cell membrane via active
transport (SGLT1).

o Then, glucose crosses the basolateral membrane and enters the interstitial
space by facilitated diffusion (GLUT2).

o Glucose enters the bloodstream.

2. From Blood to Muscle:
 o Glucose moves from the bloodstream into the muscle via facilitated
diffusion (GLUT4) across the endothelial cells of the capillaries, through
the interstitial space, and finally into muscle cells.

This multi-step process ensures glucose is efficiently absorbed, transported, and
delivered to muscle cells where it can be used for energy.

Challenges of Transport Inside Cells

Cells are highly organized structures with multiple intracellular membranes that
compartmentalize various cellular functions. These membranes serve as barriers and
regulate the transport of molecules, ions, and gases within the cell. The challenge of
transport inside cells involves the efficient movement of substances across these various
internal membranes to maintain cellular functions.

1. Multiple Intracellular Membranes

The presence of multiple membranes inside cells means that substances must cross
several barriers to reach their final destination, whether it's the nucleus, mitochondria,
or other organelles like the sarcoplasmic reticulum. Each membrane type has unique
transport mechanisms and specific permeability characteristics.

Some examples of intracellular membranes include:

Nuclear Membrane (Nucleus)

Mitochondrial Membrane (Mitochondria)

Sarcoplasmic Reticulum Membrane (Muscle Cells)

Endoplasmic Reticulum Membrane (Endoplasmic Reticulum)

Plasma Membrane (Cell Membrane)

2. Transport Across Internal Membranes

Each of these membranes has distinct characteristics, and transport across them is
tightly regulated to ensure that the correct substances are delivered to the right
location at the right time.

Here’s a look at how substances cross some of these key intracellular membranes:

A. Mitochondrial Membrane

The mitochondria are known as the powerhouses of the cell, where ATP is produced
through oxidative phosphorylation. Substances that need to enter the mitochondria, such
as pyruvate (for energy production) and oxygen (for cellular respiration), must cross
the mitochondrial membrane.

Outer membrane: This is permeable to small molecules (e.g., pyruvate, ATP, ions)
due to porins, large protein channels that allow molecules to diffuse through.

Inner membrane: This is much more selective and requires specific transporters
or carriers to move molecules in or out, such as:
 o Mitochondrial pyruvate carrier (MPC) for pyruvate entry.

o ATP/ADP translocase to exchange ATP and ADP between the mitochondria
and cytosol.

The inner membrane also houses the electron transport chain and ATP synthase, which
are involved in energy production, so it is highly specialized for energy production and
proton gradients.

B. Nuclear Membrane

The nuclear envelope consists of two lipid bilayers that separate the nucleus from the
cytoplasm. Transport across the nuclear envelope is essential for processes like gene
expression and protein synthesis.

Nuclear pores: These large complexes in the nuclear membrane regulate the
exchange of substances (e.g., RNA, proteins) between the nucleus and cytoplasm.

o Import: Proteins are imported into the nucleus through specific importins
that recognize nuclear localization signals (NLS) on the proteins.

o Export: RNA molecules (like mRNA) are exported out of the nucleus into the
cytoplasm through exportins.

This system ensures that the necessary proteins and RNA molecules are able to move into
or out of the nucleus in a regulated manner, while preventing the uncontrolled passage
of other molecules.

C. Sarcoplasmic Reticulum (SR)

The sarcoplasmic reticulum (SR) is an organelle in muscle cells that regulates calcium
ion (Ca²⁺) storage and release, which is crucial for muscle contraction.

Calcium channels: The SR membrane contains specific calcium release channels,
such as the ryanodine receptor (RyR), that allow the release of Ca²⁺ from the SR
into the cytoplasm during muscle contraction.

Calcium pumps: Sarcoplasmic/endoplasmic reticulum Ca²⁺-ATPase (SERCA)
pumps are responsible for pumping Ca²⁺ back into the SR during muscle
relaxation. These pumps require ATP to function, ensuring that calcium is
maintained at the correct concentrations for muscle function.

D. Other Membranes in the Cell

Endoplasmic Reticulum (ER): The ER is involved in protein folding and lipid
synthesis. The smooth ER lacks ribosomes and is responsible for lipid metabolism,
while the rough ER has ribosomes on its surface and is involved in protein
synthesis. Molecules can cross these membranes via transport proteins that
facilitate the movement of proteins and lipids between the ER and other parts of
the cell.

Golgi Apparatus: The Golgi processes and sorts proteins and lipids received from
the ER. Molecules such as proteins are packaged into vesicles and transported
 across the Golgi membranes to their final destinations.

Challenges of Transport

The transport of molecules across intracellular membranes is often limited by:

1. Selective permeability: Most intracellular membranes are selectively permeable
to ensure the integrity and functionality of organelles.

2. Energy requirements: Active transport (e.g., calcium pumps in the SR) requires
ATP to move substances against concentration gradients.

3. Molecular size and charge: Large or charged molecules, like proteins or RNA,
often require special transporters (e.g., nuclear pore complexes, vesicles) to
cross membranes.

4. Compartmentalization: The internal membranes create separate compartments
for specific functions (e.g., energy production in mitochondria), which requires
careful regulation of transport processes to maintain homeostasis.

Summary

The challenge of transport inside cells arises from the need to move molecules, ions, and
gases across multiple intracellular membranes. These membranes serve as barriers that
regulate the flow of substances based on the needs of the cell. Mechanisms such as active
transport, facilitated diffusion, and specialized transporters ensure that substances like
glucose, calcium ions, RNA, and proteins reach their correct locations for proper cellular
function.

Permeability and electrochemical gradient
★ Cell Membranes: Selectively Permeable Barriers

Cell membranes act as selectively permeable barriers, meaning they allow certain
substances to pass while blocking others. The ability of a substance to cross the
membrane depends on two main factors:

1. Permeability

2. Electro-Chemical Gradient

1. Permeability

Permeability refers to the ease with which a substance can pass through a membrane. It
depends on the physical properties of the membrane (lipid bilayer) and the properties
of the substance being transported.

Factors Affecting Permeability:

Size of the molecule: Small, non-polar molecules like oxygen (O₂) and carbon
dioxide (CO₂) can diffuse across the membrane easily. Larger molecules,
especially those that are polar (e.g., glucose), require specialized transport
mechanisms.
 Polarity: Non-polar molecules (like lipids) can easily pass through the lipid
bilayer, whereas polar molecules (like ions, water, glucose) have a harder time
crossing unless they have specific channels or carriers.

Charge of the molecule: Ions (e.g., Na⁺, K⁺, Cl⁻) have a harder time crossing the
membrane directly because the lipid bilayer is hydrophobic. Transport proteins
(e.g., ion channels, pumps) are required for their movement across the membrane.

Membrane composition: The presence of cholesterol, phospholipids, and
membrane proteins can alter membrane permeability. For example, membrane
proteins (e.g., aquaporins, ion channels) allow specific molecules (like water or
ions) to cross more easily.

2. Electro-Chemical Gradient

The electro-chemical gradient is a combination of two factors that determine the
direction of ion movement across the membrane:

Concentration Gradient (Chemical Gradient): The difference in concentration of
a substance between the inside and outside of the cell. Substances tend to move
from areas of high concentration to low concentration.

Electrical Gradient (Membrane Potential): The difference in charge across the
membrane. This influences the movement of charged particles (ions) due to
electrostatic forces. For example, positively charged ions (cations) are attracted
to the negative side of the membrane, while negatively charged ions (anions) are
attracted to the positive side.

Net Force on a Substance:

The electrochemical gradient results from the combined effect of both the
concentration gradient and the electrical gradient.

If a substance has both a high concentration outside the cell and a negative
charge inside, it will be drawn into the cell, and the movement will be facilitated
by both gradients (electrical and chemical).

Conversely, if the concentration is higher inside the cell or the electrical gradient
opposes the movement, the substance will be repelled or require additional energy
for transport.

Summary of Factors Affecting Transport:

Thus, the ability of a substance to cross the membrane depends not just on the
membrane’s permeability, but also on the concentration and electrical differences
across the membrane.
Chemical Gradient and Diffusion

The chemical gradient refers to the difference in the concentration of a substance
between two areas, such as inside and outside the cell. This gradient determines the
direction and movement of substances across cell membranes.

Chemical Gradient Force:

Outward Gradient (Higher concentration outside the cell):

o When the concentration of a substance is higher outside the cell than inside,
there is a force pushing the substance out of the cell.

o Substances tend to move from areas of higher concentration to areas of
lower concentration via diffusion. This movement is driven by the chemical
gradient.

Inward Gradient (Higher concentration inside the cell):

o When the concentration of a substance is higher inside the cell, there is a
force pushing the substance into the cell.

o The substance will move from areas of high concentration inside the cell
to areas of low concentration outside the cell, again via diffusion.

Diffusion and Flux:

Diffusion is the passive movement of molecules or ions from an area of higher
concentration to an area of lower concentration. This movement continues until
equilibrium is reached, where the concentration of the substance is uniform
across both sides of the membrane.

Flux: The rate of movement of a substance across the membrane. The flux is
greater when the concentration gradient is steeper (i.e., the difference between
the concentrations is larger).
Flux Arrow Representation:

The Flux Arrow visually represents the direction and strength of diffusion:

o Widest part of the arrow indicates the area of highest concentration.

o The narrowest part of the arrow indicates the area of lowest
concentration.

o The direction of the arrow shows the direction of movement: from high
concentration to low concentration.

Example:

If we consider oxygen (O₂):

o In the lungs: There is a high concentration of O₂ in the air and a lower
concentration in the blood, so O₂ diffuses into the blood.

o In the tissues: The concentration of O₂ is lower inside the cells (because
it's used in cellular respiration), so O₂ diffuses from the blood into the cells.

Key Points:

Inward Gradient (High concentration inside): Forces substances to move into the
cell.

Outward Gradient (High concentration outside): Forces substances to move out
of the cell.

Diffusion: Movement of molecules or ions from high to low concentration driven
by the chemical gradient.

Flux Arrow: Represents the direction and strength of diffusion, with the widest
part indicating the highest concentration.

This principle is fundamental to passive transport processes, where no energy is
required, and the movement of substances depends solely on the concentration gradient
across the membrane.

★ Electrical Gradient and Resting Membrane Potential

The electrical gradient refers to the difference in electrical charge across a membrane.
In most cells, the inside of the cell is negative relative to the outside, creating an
electrical potential difference. This difference in charge contributes to the movement of
charged particles (ions) across the membrane.
Key Concepts:

1. Electrical Gradient (Voltage Gradient):

o The inside of the cell is negatively charged relative to the outside. This
means that the outside of the cell is more positively charged (due to the
presence of positive ions like Na⁺ and K⁺).

o Negative ions (such as Cl⁻) are generally forced outward because they
are repelled by the negative charge inside the cell.

o Positive ions (such as Na⁺ and K⁺) are attracted inward due to the
negative charge inside the cell. They move toward the area with the
opposite charge.

2. Resting Membrane Potential:

o The resting membrane potential of most cells is around -70 mV (millivolts).
This means that the inside of the cell is 70 millivolts more negative than
the outside of the cell.

o This resting potential is primarily established by the distribution of ions
across the membrane, especially K⁺ (potassium), Na⁺ (sodium), and Cl⁻
(chloride), and the selective permeability of the membrane to these ions.

How the Electrical Gradient Affects Ion Movement:

The electrical gradient works together with the chemical gradient (concentration
gradient) to determine the overall force acting on ions, known as the
electrochemical gradient.

Positive ions (e.g., Na⁺, K⁺) are attracted into the cell because the inside is
negative, and the electrochemical gradient favors the inward movement.

Negative ions (e.g., Cl⁻) are pushed out of the cell due to the negative internal
environment, which repels negatively charged particles.

Flux Arrow Representation for Ions:

The Flux Arrow is used to represent the direction and strength of ion movement
across the membrane due to the combined effects of both the chemical gradient
and the electrical gradient.

o The widest part of the arrow indicates the highest concentration or
strongest electrochemical driving force for that ion.

o The direction of the arrow shows whether ions are moving into or out of
the cell. For example:

▪ Positive ions (e.g., Na⁺) are attracted to the negative inside of the
cell, so the flux arrow points inwards.

▪ Negative ions (e.g., Cl⁻) are repelled by the negative inside, so the
flux arrow points outwards.

Summary of Electrical Gradient:
 The electrical gradient is a result of the charge difference between the inside and
outside of the cell, with the inside typically being more negative than the outside.

This negative charge inside the cell attracts positive ions in (e.g., Na⁺, K⁺), and
repels negative ions out (e.g., Cl⁻).

The resting membrane potential of -70 mV reflects this charge imbalance and is
crucial for many cellular processes, including action potentials in neurons and
muscle contraction.

By working together with the chemical gradient, the electrical gradient helps to regulate
the movement of ions across the cell membrane, which is essential for maintaining cell
function and homeostasis.

A selectively-permeable barrier

Conditions for Spontaneous Movement Across a Membrane

For an ion or molecule to move across a cell membrane spontaneously, two main
conditions must be met:

1. Movement Down (or with) its Electrochemical Gradient:

o Electrochemical gradient is the combined effect of both the chemical
gradient (difference in concentration) and the electrical gradient
(difference in charge).

o An ion or molecule will only move spontaneously if it is moving from a
region of higher concentration to lower concentration (for chemical
gradient) and/or in a direction where its electrical charge is driven (for
electrical gradient).

▪ For ions: If an ion is moving from an area of high concentration to
low concentration, or in the direction that aligns with its electrical
gradient (e.g., positive ions moving towards a negative area), the
movement will occur spontaneously.

▪ For molecules: Similarly, molecules will move down their
concentration gradient if there is no opposing force.
 2. Membrane Permeability:

o The cell membrane must be permeable to the ion or molecule in question.
If the membrane is impermeable to a substance, it cannot cross the
membrane, even if the electrochemical gradient is favorable.

o Permeability is determined by factors like:

▪ Size of the molecule: Small molecules like oxygen and carbon
dioxide can easily diffuse through the lipid bilayer.

▪ Charge of the ion: Charged ions (e.g., Na⁺, K⁺, Cl⁻) generally need
specific ion channels or transporters to cross the membrane, as the
lipid bilayer is not permeable to charged particles.

▪ Presence of transport proteins: Channels, carriers, or pumps may
be required for a substance to pass through the membrane,
especially for polar molecules or charged ions.

Summary:

Spontaneous Movement: For an ion or molecule to move spontaneously across a
membrane:

o It must be moving down or with its electrochemical gradient (increasing
the entropy and moving toward equilibrium).

o The membrane must be permeable to that specific substance, either via
simple diffusion or through specific transport mechanisms like ion
channels or carriers.

Without both conditions being met, movement across the membrane will not happen
spontaneously.

Passive Diffusion of Gases & Hydrophobic Substances

Passive diffusion refers to the spontaneous movement of substances across a membrane
without the need for metabolic energy or carrier proteins. This occurs down the
electrochemical gradient, meaning that molecules move from an area of high
concentration to low concentration (or according to their electrical gradient for
charged particles). Some substances can pass through the cell membrane directly by this
method due to their chemical properties.
Substances That Cross by Passive Diffusion:

1. Gases:

o Oxygen (O₂)

o Carbon dioxide (CO₂)

o Nitric oxide (NO)

These gases are small, non-polar, and hydrophobic, which allows them to easily pass
through the lipid bilayer of the cell membrane via passive diffusion.

2. Hydrophobic Molecules:

o Steroid Hormones:

▪ These molecules are lipid-soluble and can diffuse across
membranes without requiring transport proteins.

▪ Examples include cortisol, testosterone, estrogen, and
progesterone.

o Ethanol (C₂H₅OH):

▪ Ethanol is also small and hydrophobic, allowing it to easily cross
the cell membrane through passive diffusion.

Key Points about Passive Diffusion:

No Energy Required: Passive diffusion does not require energy from ATP or other
cellular energy sources. It is driven by the concentration gradient (molecules
move from an area of higher concentration to lower concentration).

No Carrier Proteins: Unlike facilitated diffusion or active transport, passive
diffusion does not need carrier proteins or ion channels to assist the movement
of molecules across the membrane.

Driven by Chemical & Electrochemical Gradients: Gases and hydrophobic
substances move down their chemical gradients (from high to low concentration),
and in the case of charged molecules, their movement can also be influenced by
the electrical gradient.

Summary:

Gases (O₂, CO₂, NO) and hydrophobic molecules (steroid hormones, ethanol) can
cross the cell membrane by passive diffusion, moving spontaneously from high to
low concentration.

This process does not require metabolic energy or the involvement of carrier
proteins. It is driven purely by the electrochemical gradient.
Ions and Hydrophilic Substances: Challenges in Crossing the Membrane

While ions and hydrophilic (polar) molecules cannot spontaneously cross the membrane
through passive diffusion (even if there is an electrochemical gradient), they can still
move across the membrane with the help of specific membrane transport mechanisms.
This is due to the hydrophobic nature of the lipid bilayer of the membrane, which acts as
a barrier to charged and polar substances.

Types of Substances that Cannot Cross Spontaneously:

1. Ions (Charged Particles):

o Examples: K⁺, Na⁺, Cl⁻

o Problem: These ions are charged, and the lipid bilayer of the membrane is
hydrophobic, which repels charged particles.

o Solution: Ions can cross the membrane only via specialized channels or
transporters, which allow them to move through the membrane along their
electrochemical gradient (from high to low concentration or based on the
electrical gradient).

2. Hydrophilic (Polar) Molecules:

o Examples: Glucose, Amino Acids, Water

o Problem: These molecules are polar (have partial positive and negative
charges), making it difficult for them to pass through the lipid bilayer,
which is hydrophobic.

o Solution: Polar molecules need carrier proteins (for facilitated diffusion)
or channels (for ion transport) to help them cross the membrane. In some
cases, aquaporins help water cross the membrane.

3. Proteins & DNA (Negatively Charged):

o Examples: Proteins, DNA

o Problem: Large molecules like proteins and nucleic acids are typically
 negatively charged and too large to diffuse across the lipid bilayer.

o Solution: These molecules need specific transport systems, such as
vesicular transport (endocytosis or exocytosis), or carrier-mediated
active transport.

Transport Mechanisms for Ions & Hydrophilic Molecules:

1. Ion Channels:

o Proteins that form pores in the membrane, allowing ions like K⁺, Na⁺, Cl⁻
to move in or out of the cell.

o Ion channels can be gated, meaning they open or close in response to
specific signals (e.g., voltage-gated or ligand-gated).

2. Carrier Proteins:

o These proteins facilitate the transport of larger, polar molecules like
glucose and amino acids across the membrane via facilitated diffusion or
active transport.

o Facilitated diffusion: Passive transport that moves molecules down their
concentration gradient (no energy required).

o Active transport: Requires energy (usually ATP) to move substances
against their concentration gradient.

3. Aquaporins:

o Specialized channel proteins that allow water molecules to move across
the membrane efficiently.

4. Vesicular Transport:

o Large molecules like proteins and DNA can be transported through the
membrane by vesicles (e.g., endocytosis to bring molecules into the cell or
exocytosis to export molecules from the cell).

Summary:

Ions (K⁺, Na⁺, Cl⁻), polar molecules (glucose, amino acids, water), and large
charged molecules (proteins, DNA) cannot spontaneously cross the lipid bilayer
because they are charged or polar, and the membrane is hydrophobic.

These substances require specialized transport mechanisms, including ion
channels, carrier proteins, aquaporins, and vesicular transport, to move across
the membrane either down or against their electrochemical gradients.

Ions and Hydrophilic Substances: Crossing the Membrane with Carrier Proteins

As you correctly mentioned, ions and hydrophilic (polar) substances cannot
spontaneously cross the lipid bilayer of the membrane even if there is an electrochemical
gradient. This is due to the hydrophobic nature of the lipid bilayer, which acts as a
barrier to charged and polar molecules.
However, these molecules can cross the membrane with the help of carrier proteins
embedded in the membrane. These proteins make the membrane permeable to these
substances, allowing them to move down their concentration gradient or in some cases
against it (via active transport).

Substances that Require Carrier Proteins to Cross the Membrane:

1. Ions (Charged Particles):

o Examples: K⁺, Na⁺, Cl⁻

o Mechanism: Ions are charged and cannot pass through the hydrophobic
lipid bilayer without assistance. They move across the membrane via ion
channels or carrier proteins.

▪ Ion Channels: Allow ions to pass through the membrane down their
electrochemical gradient.

▪ Ion Pumps (Active Transport): Some ion transporters (e.g., Na⁺/K⁺
pump) use ATP to move ions against their concentration gradients.

2. Hydrophilic (Polar) Molecules:

o Examples: Glucose, Amino Acids, Water

o Mechanism: Polar molecules (such as glucose and amino acids) are
hydrophilic and cannot pass directly through the membrane. They rely on
carrier proteins for facilitated diffusion or active transport.

▪ Facilitated Diffusion: Carrier proteins allow molecules to move
down their concentration gradient (no energy required).

▪ Active Transport: In some cases, energy (ATP) is required to move
molecules against their concentration gradient (e.g., sodium-
glucose cotransporter).

3. Large Charged Molecules (Proteins, DNA):

o Examples: Proteins, DNA
 o Mechanism: Large molecules like proteins and nucleic acids are too large
to diffuse across the membrane. They rely on vesicular transport
mechanisms like endocytosis or exocytosis to move into or out of the cell.

Types of Transport via Carrier Proteins:

1. Facilitated Diffusion:

o Definition: A form of passive transport where molecules move down their
concentration gradient via a carrier protein.

o Example: Glucose transport into cells via the GLUT (glucose transporter)
proteins.

2. Active Transport:

o Definition: Movement of molecules against their concentration gradient,
requiring energy (usually ATP).

o Example: The Na⁺/K⁺ pump that moves sodium and potassium ions across
the membrane against their electrochemical gradients.

3. Symport and Antiport (Types of Active Transport):

o Symport: Both molecules move in the same direction across the membrane
(e.g., sodium-glucose cotransporter).

o Antiport: Molecules move in opposite directions across the membrane (e.g.,
Na⁺/H⁺ exchanger).

Summary:

Ions (K⁺, Na⁺, Cl⁻), polar molecules (glucose, amino acids, water), and large
charged molecules (proteins, DNA) cannot cross the cell membrane spontaneously
due to the hydrophobic nature of the lipid bilayer.

These substances require carrier proteins for transport, which facilitate their
movement across the membrane.

Transport can occur via facilitated diffusion (passive transport) or active
transport (which requires energy, typically ATP).

Specialized proteins such as ion channels, symporters, and antiporters help
transport ions, while aquaporins aid in the transport of water.
★ Fick’s Law of Diffusion for Biologists

★ Are nerve impulses send by diffusion

No, nerve impulses are not sent by diffusion alone, as diffusion alone would be far too
slow for the rapid transmission of nerve impulses.

Reason: Diffusion and Nerve Impulse Transmission

Nerve impulses are transmitted via action potentials, which are electrical signals that
propagate along the axon of a neuron. These impulses involve the rapid movement of
ions across the membrane through voltage-gated ion channels rather than simple
diffusion. This allows the nerve signal to travel at speeds much faster than what would
be possible through diffusion alone.
Diffusion Times for Ions and Molecules:

The diffusion times you provided show that diffusion is very slow over longer distances.
For example:

As you can see, diffusion over even small distances (e.g., 1 mm or 1000 µm) takes a
significant amount of time (500 seconds or about 8 minutes), and over large distances
(like 1 meter), diffusion would take 15 years!

Action Potential and Nerve Impulse Transmission:

Nerve impulses, however, are electrically mediated, and the action potential travels at
speeds of up to 100 meters per second in some large, myelinated neurons, much faster
than the rate at which diffusion can occur. The rapid transmission of the action potential
is aided by:

1. Voltage-gated ion channels: These channels allow for the quick influx of sodium
ions (Na⁺) and efflux of potassium ions (K⁺) to create the electrical impulse that
travels along the neuron.

2. Myelination: In myelinated neurons, the action potential jumps between nodes of
Ranvier, where ion channels are concentrated, speeding up the transmission.

3. Saltatory conduction: This method of action potential propagation along a
myelinated axon is much faster than diffusion-based transmission.

Conclusion:

While diffusion is important in the context of ion movement across cell membranes (e.g.,
for generating action potentials), nerve impulses themselves are not sent by simple
diffusion. They are electrical signals that are rapidly propagated by voltage-gated ion
channels, ensuring fast transmission of information over long distances in the body.

You are correct that processes in normal cells that rely on diffusion can only occur over
small distances because diffusion is a relatively slow process, as demonstrated by the
diffusion times provided.

Diffusion Times and Distance
From the data you provided, we see that the time it takes for molecules or ions to achieve
99% equilibrium increases dramatically with distance:

This demonstrates how diffusion is inefficient over long distances. For instance, to
diffuse across just 1 meter, it would take 15 years. This is far too slow for many
physiological processes that require rapid transport over large distances, such as the
transmission of nerve impulses.

Diffusion in Normal Cells:

In normal cells, diffusion can be an important mechanism for processes like the
movement of gases (O₂ and CO₂), small molecules, and ions across the cell membrane.
However, as the distances within a single cell can range from a few micrometers to
millimeters, diffusion can only occur efficiently over short distances (usually up to a
few micrometers) where it is fast enough to support biological functions.

Why Nerve Impulse Transmission Doesn’t Rely on Diffusion:

Nerve impulses are electrical signals that travel along axons, and they do not occur
through simple diffusion. The action potential mechanism, which is the basis for nerve
impulse transmission, involves the movement of ions (like sodium and potassium) across
the neuron membrane through voltage-gated ion channels. This process is far faster
than diffusion, and allows for the rapid transmission of signals across long distances
(e.g., from the brain to the extremities).

In myelinated neurons, the action potential "jumps" between nodes of Ranvier, which
speeds up the process even further, making it possible for signals to travel at speeds of
up to 100 m/s (or even faster in some cases), much faster than what diffusion alone
could achieve.

Conclusion:

While diffusion is a key process in cellular functions, it is only effective over short
distances. In larger, multicellular organisms, processes like nerve impulse transmission
rely on electrical signaling (action potentials) rather than diffusion, because diffusion
would be far too slow to transmit information efficiently over long distances.

Part I – Summary

Spontaneous Movement of Ions or Molecules: Ions or molecules naturally move
across a lipid bilayer, which serves as a barrier, depending on the membrane's
permeability and the electrochemical gradient.
 Membranes as Selectively Permeable Barriers: Cell membranes are selectively
permeable, meaning they allow certain molecules or ions to pass while restricting
others. This selectivity is crucial for maintaining cellular function and
homeostasis.

Membrane Permeability: A membrane must be permeable to a substance for it to
move across. If a substance cannot pass through the lipid bilayer on its own,
carrier proteins or channels may facilitate its transport, making the membrane
selectively permeable to that substance.

Electrochemical Gradient: Movement of ions across membranes is driven by an
electrochemical gradient, which combines the concentration gradient (difference
in solute concentrations) and the electrical gradient (difference in charge across
the membrane).

Diffusion: Solutes move across membranes through diffusion, a process driven by
concentration differences. The rate of diffusion can be quantified by Fick’s law,
which considers the permeability of the membrane and the electrochemical
gradient.

Diffusion Rate: Diffusion occurs rapidly over short distances, allowing small
molecules (like gases or small ions) to cross membranes quickly. However, over
long distances, diffusion becomes much slower, making it inefficient for long-
range transport within larger organisms.

Key Concepts:

Selective permeability of membranes is essential for regulating the internal
environment of the cell.

Carrier proteins facilitate transport when molecules can't pass through the lipid
bilayer directly.

Electrochemical gradients drive the movement of ions and molecules.

Diffusion is effective over short distances but inefficient over long distances,
which is why larger organisms rely on specialized systems like the circulatory
system for transport.

Passive versus active transport– different carrier proteins
Channels and Transport Across Membranes

Channels Form "Pores" in the Membrane: Channels create specific pores in the cell
membrane that allow certain substances (such as ions or water) to pass through.
Each type of channel is often selective, meaning it only permits the passage of a
single substance (e.g., Na⁺ channels or aquaporins for water).

Flux is Passive: The movement of ions or water through channels occurs passively,
meaning it does not require energy input from the cell. Instead, the flow is driven
by the electrochemical gradient—the difference in concentration (for ions) or
osmotic pressure (for water) across the membrane.

o Electrochemical Gradient: This combines two forces: the concentration
gradient (difference in concentration of a substance on either side of the
membrane) and the electrical gradient (potential difference due to charge
differences across the membrane).

o Passive Movement: Because the movement is passive, substances move
from areas of higher concentration (or higher electrochemical potential)
to areas of lower concentration, following the gradient without the need
for energy expenditure.

Regulated vs. Non-Regulated Channels:

o Regulated (Gated) Channels: These channels can open or close in response
to specific signals or changes in the environment (e.g., changes in
membrane potential, binding of ligands). For example, voltage-gated
channels open in response to a change in membrane potential, while
ligand-gated channels open when a molecule (ligand) binds to them.

o Non-Regulated (Constitutive) Channels: Some channels are always open,
allowing continuous and unregulated flow of substances across the
membrane. These channels typically allow water or ions to pass through
consistently and are crucial for maintaining basic cellular functions like
volume regulation (e.g., aquaporins for water).

Summary of Key Points:

Specificity: Channels are highly selective for the substances they transport,
ensuring only certain ions or molecules can pass through.

Passive Transport: Movement through these channels follows the electrochemical
 gradient, requiring no energy from the cell.

Regulated Channels: These channels are controlled and only open or close in
response to specific signals, which helps control when and how substances enter
or leave the cell.

Constitutive Channels: These channels are always open, allowing a constant,
passive flow of substances.

Uniporters: Transport of Larger Molecules

Uniporters and Their Function:

o A uniporter is a type of transport protein that binds to a single type of
molecule (e.g., glucose) and facilitates its movement across the membrane
down its concentration gradient.

o Unlike channels, uniporters do not form a continuous pore through the
membrane. Instead, they undergo conformational changes that allow them
to bind to the molecule on one side of the membrane, transport it across,
and then release it on the other side.

o This process is passive, as the molecule moves down its concentration
gradient, meaning energy is not required.

Regulation of Uniporters:

o The activity of uniporters can be regulated through insertion or removal
of the transporter protein from the membrane. For example, the glucose
transporter (GluT1) in the kidney regulates glucose uptake by moving the
transporter into or out of the membrane, depending on the body's need for
glucose.

Example - GluT1 in the Kidney:

o GluT1 is a type of uniporter that facilitates the transport of glucose across
the cell membrane in certain tissues, like in the kidneys. It moves glucose
down its concentration gradient into cells from the extracellular space.

o The presence and activity of GluT1 can be regulated based on the body's
glucose levels, influencing how much glucose is taken up by cells. In
conditions of high glucose, more GluT1 transporters may be inserted into
the membrane, increasing glucose uptake.
Key Points:

Uniporters: Transport large molecules like glucose down their concentration
gradient, without forming an open pore.

Regulated Insertion/Removal: The number of uniporters in the membrane can be
adjusted, providing control over the rate of transport.

Passive Transport: Uniporters allow molecules to move passively, meaning no
energy is required as long as the molecules are moving down their concentration
gradient.

Uniporters: Transport of Larger Molecules

Function of Uniporters:

o Uniporters are transport proteins that bind to specific larger molecules,
such as glucose, and facilitate their movement across the cell membrane
down their concentration gradient. This means that the molecule moves
from an area of higher concentration to an area of lower concentration
without requiring energy (i.e., passive transport).

o Unlike channels that form continuous pores, uniporters do not create an
open channel at any time. Instead, they undergo a conformational change
to allow the molecule to bind on one side, cross the membrane, and then
release it on the opposite side.

Regulation of Uniporters:

o The activity of uniporters can be regulated by their insertion or removal
from the cell membrane. This allows the cell to adjust the rate of transport
depending on its needs.

o For example, in the kidneys, the glucose transporter GluT1 regulates
glucose uptake by being inserted into the membrane when needed, and
removed when glucose levels are sufficient. This helps maintain
homeostasis of glucose levels in the body.

Example - GluT1 in the Kidney:

o GluT1 is a uniporter that moves glucose across the cell membrane,
particularly in tissues like the kidney, where glucose needs to be absorbed
 from the urine back into the bloodstream.

o In the kidneys, GluT1 facilitates the movement of glucose from the tubular
fluid (urine) into the cells lining the kidney tubules, allowing the glucose
to be reabsorbed into the body.

o Regulation: The number of GluT1 transporters in the membrane can be
regulated by the cell. For instance, in response to changing glucose levels,
more transporters can be inserted into the membrane, increasing glucose
uptake when necessary.

Key Points:

Uniporters allow passive transport of larger molecules like glucose down their
concentration gradient.

No open pore: Uniporters function through conformational changes, rather than
forming an open pore in the membrane.

Regulation: The number of uniporters in the membrane can be adjusted through
insertion/removal, helping cells regulate the transport of substances according
to their needs.

why glu transporter rather than glu channel?

The choice of glucose transporters (GluT) rather than glucose channels in cells is due to
several factors related to the specific nature of glucose and the cell's requirements for
its controlled uptake:

1. Size and Hydrophilicity of Glucose:

Glucose is a relatively large and polar molecule (hydrophilic). A channel, by
definition, allows small ions or molecules to pass freely through the membrane,
typically when they are small and uncharged or very small and charged. Glucose,
however, is too large and hydrophilic to diffuse freely across the lipid bilayer,
even if a channel were available.

GluT transporters, on the other hand, are specialized proteins that recognize and
bind glucose molecules, allowing them to be transported into cells in a controlled
manner.

2. Regulation and Specificity:

Uniporters (like GluT) can be regulated in terms of their presence on the cell
membrane, allowing the cell to control how much glucose enters the cell. For
example, insulin can increase the insertion of glucose transporters (such as GluT4)
into the plasma membrane of muscle and adipose cells, enhancing glucose uptake
after meals.

A channel would be less specific in its regulation. It would allow glucose to enter
the cell freely as long as there is a concentration gradient, which could be less
desirable for maintaining homeostasis and controlling glucose levels in the body.
3. Active Transport Control:

Although GluT transporters operate by facilitated diffusion, they still allow the
cell to control the uptake process through their insertion and removal from the
membrane, protein conformational changes, and interaction with intracellular
signals.

A channel would continuously allow glucose to enter or leave the cell as long as
there is a gradient, potentially leading to uncontrolled fluctuations in glucose
levels, which could be detrimental, particularly in tissues like the brain and
muscles.

4. Directionality and Sensing:

The GluT family of transporters is capable of moving glucose in a directionally
controlled manner. Some transporters (e.g., GluT1 in the kidney) help reabsorb
glucose from the urine, while others (e.g., GluT4 in muscle cells) enable glucose
uptake after meals.

A channel would be less effective in regulating glucose movement in a controlled
direction (into or out of the cell) because it would depend only on the
concentration gradient, without the additional regulation of active processes like
carrier-mediated transport.

5. Energy Considerations:

Glucose transporters enable passive diffusion, meaning glucose can move across
the membrane down its concentration gradient without the need for energy (ATP).
However, because these transporters undergo conformational changes, they
enable a more controlled and efficient movement than what would be possible
with a simple channel, which would likely not allow for the same specificity or
regulation.

Conclusion:

The use of glucose transporters (GluT) rather than glucose channels is essential for the
controlled, regulated, and efficient uptake of glucose. Transporters are better suited to
the size, hydrophilicity, and specific regulatory needs of glucose, ensuring that glucose
is absorbed in response to the body's needs and maintaining homeostasis in various
tissues.

Exactly! If a glucose channel were used instead of a glucose transporter, the selectivity
of the cell membrane would be compromised. Here's why:

1. Loss of Selective Permeability:

Channels are typically less specific than transporters. If a glucose channel were
present, it would allow any small molecules (including ions like Na+, K+, and Cl-,
and even water) that are small enough to pass through the membrane, as long as
there is a concentration gradient.

This would be problematic because the cell membrane needs to be selectively
 permeable to maintain the internal environment. For example, allowing ions or
water to pass indiscriminately through a glucose channel could disturb the cell's
electrochemical gradients (important for processes like action potentials and
osmosis), and lead to loss of control over cell volume and membrane potential.

2. Loss of Control over Glucose Uptake:

A glucose transporter (like GluT) facilitates the controlled transport of glucose
without creating an open pore that can allow other substances to cross the
membrane.

In contrast, a glucose channel would not differentiate between glucose and other
small molecules, leading to unintended consequences, like the influx of other
solutes that might disrupt the ion balance and other important cellular processes.

3. Regulation and Specificity:

Transporters like GluT can be regulated (inserted or removed from the membrane)
in response to signals like insulin or glucose concentrations. This allows cells to
fine-tune glucose uptake and ensure it's only absorbed when necessary.

A channel, however, would be less regulable because it would simply allow glucose
(and potentially other substances) to flow through as long as a concentration
gradient exists, without considering the cell's immediate needs or the presence of
other solutes.

4. Maintaining Membrane Potential and Ion Gradients:

Channels that allow ions to pass through (like ion channels) contribute to the
maintenance of membrane potential and are critical for action potentials, nerve
signaling, and muscle contraction. If a glucose channel allowed ions to flow freely,
it would disrupt these essential functions.

By having specific glucose transporters, the membrane maintains a stable
environment where ion gradients and membrane potentials are tightly regulated.

Conclusion:

A glucose channel would indeed compromise the selectivity and integrity of the cell
membrane, allowing a range of unwanted molecules (ions and water) to cross, thus
disrupting critical cellular processes like osmotic balance and membrane potential. The
use of a glucose transporter ensures specificity and control over glucose uptake while
maintaining the cell's electrochemical gradients and overall homeostasis.
Active transport

Ions or molecules can move up/against concentration gradient, but this requires
additional energy - spontaneous diffusion won’t occur.

Active Transport: Primary (1º) Active Transport by Ion Pumps

Definition:
Primary active transport involves the direct use of energy (usually from ATP) to move
ions or molecules against their electrochemical gradient, from a region of low
concentration to a region of high concentration.

Example: Sodium-Potassium Pump (Na+/K+ ATPase)

The Na+/K+ pump is a classic example of primary active transport. It actively extrudes
sodium ions (Na+) from the cell and pumps potassium ions (K+) into the cell, both against
their electrochemical gradients. This process uses the energy provided by ATP to do the
work.

Sodium ions (Na+) are pumped out of the cell.

Potassium ions (K+) are pumped into the cell.

This pump works by binding ATP and using the energy from ATP hydrolysis (breaking
down ATP into ADP and inorganic phosphate) to move ions in the opposite direction of
their natural gradients.

Mechanism of the Na+/K+ Pump:

1. Binding: ATP binds to the pump along with 3 sodium ions (Na+) from the inside of
the cell.

2. Phosphorylation: ATP is hydrolyzed (broken down into ADP and inorganic
phosphate), and the energy is used to phosphorylate the pump protein, causing it
to change shape.

3. Transport: This shape change moves the 3 sodium ions to the outside of the cell.

4. Potassium Binding: 2 potassium ions (K+) bind to the pump from the extracellular
space.

5. Dephosphorylation: The pump is dephosphorylated (removes phosphate group),
causing it to return to its original shape and release the potassium ions inside the
 cell.

6. Reset: The pump is now ready to repeat the process.

Importance of the Na+/K+ Pump:

1. Maintains Cell Volume:

o Na+/K+ pump is crucial for maintaining the osmotic balance within the cell
by controlling the concentration of sodium and potassium ions. The
constant extrusion of sodium prevents water from flowing into the cell
excessively, thus avoiding cell swelling (cytolysis).

2. Nerve Impulses:

o The sodium-potassium pump creates the resting membrane potential and
helps repolarize neurons during action potentials. In nerve cells, the action
potential relies on the rapid movement of sodium and potassium ions
across the membrane, facilitated by this pump and ion channels.

3. Muscle Contraction:

o Similar to nerve cells, muscle cells depend on this pump to generate the
proper ion gradients needed for muscle contraction and relaxation. It
helps to restore the resting state after action potentials in muscles, which
is essential for the relaxation of muscle fibers.

4. Ion Homeostasis:

o By pumping Na+ out of the cell and K+ into the cell, the Na+/K+ pump
establishes and maintains critical ion gradients. This is vital for the proper
functioning of various cellular processes like protein synthesis, pH
balance, and the conduction of electrical signals.

ATP Requirement:

Primary active transport is ATP-dependent because energy is needed to move
ions against their concentration gradient. The pump works continuously to
maintain ion concentrations and keep the cell functioning properly.

Conclusion:

The Na+/K+ pump is a perfect example of primary active transport. It uses ATP to actively
transport sodium and potassium ions across the cell membrane, essential for maintaining
cell volume, nerve impulse transmission, and muscle contraction. Without this mechanism,
cells would not be able to maintain their proper internal environment or function
effectively.
Secondary (2º) Active Transport by Symporters and Antiporters

Definition:
Secondary active transport doesn't use ATP directly for moving substances across the
membrane. Instead, it relies on the energy stored in concentration gradients of ions
(often Na+, H+, or K+) that were created by primary active transport. The movement of
ions down their gradient provides the energy needed to move other substances against
their concentration gradient.

Types of Secondary Active Transport:

1. Symporters:

o Symporters move two substances in the same direction across the
membrane. One of these substances moves down its electrochemical
gradient, releasing energy, while the other moves against its gradient,
requiring energy.

o Example: Sodium-glucose symporter in the gut.

2. Antiporters:

o Antiporters move two substances in opposite directions across the
membrane. As one substance moves down its electrochemical gradient, the
other moves in the opposite direction against its gradient.

o Example: Sodium-calcium exchanger in heart cells.

Example: Sodium-Glucose Symporter (SGLT1) in the Gut

The Sodium-Glucose Cotransporter 1 (SGLT1) is a type of symporter that utilizes the high
concentration of Na+ ions (created by the Na+/K+ pump) in the intestinal lumen to move
glucose into the cell against its concentration gradient.

1. How it works:

o Na+ ions (high concentration in the gut due to primary active transport
by Na+/K+ ATPase) move down their concentration gradient into the cell
via the SGLT1 transporter.

o This movement of Na+ down its gradient provides the energy required to
transport glucose from the intestinal lumen into the cell, against its
concentration gradient.

2. Why it’s important:

o Glucose is absorbed from the gut into the cells lining the intestines, where
it then enters the bloodstream for distribution throughout the body.
 Without this mechanism, glucose would not be efficiently absorbed into the
body from the digestive tract.

Mechanism in More Detail:

Sodium-Potassium Pump: The Na+/K+ ATPase pump creates a high concentration
of Na+ outside the cell (in the gut) and a low concentration inside the cell.

Energy Storage: This creates an electrochemical gradient for Na+. The SGLT1
symporter takes advantage of this gradient.

Symporter Action: Na+ moves into the cell via SGLT1 down its gradient, while
glucose is transported into the cell against its gradient, using the energy from
Na+ influx.

Importance of Secondary Active Transport:

1. Energy Efficiency:

o Secondary active transport is indirectly ATP-dependent. It doesn’t require
ATP directly, but uses the energy stored in primary active transport
gradients (e.g., Na+ gradient).

2. Nutrient Absorption:

o This system is crucial for the absorption of nutrients, such as glucose and
amino acids, in the intestines and kidneys. It helps maximize absorption
while minimizing the need for energy-intensive ATP.

3. Ion Regulation:

o Secondary active transport plays a role in maintaining ion gradients and
osmotic balance by ensuring that ions like Na+, K+, Ca2+, and others are
properly distributed across cell membranes.

4. Cellular Function:

o By using secondary active transport, cells can take up essential molecules
like glucose, amino acids, and ions while maintaining low ATP consumption.
This helps cells conserve energy while fulfilling their metabolic and
structural needs.

Conclusion:

Secondary active transport uses the energy stored in ion gradients (created by primary
active transport) to move molecules like glucose against their concentration gradient.
This process is vital for nutrient absorption (like glucose from the gut) and maintaining
cellular ion balance. The symporters and antiporters make this process energy-efficient,
using ion gradients as the driving force for the transport of molecules.
Cells have a Resting Membrane Potential (RMP) of -70mV
★ Resting membrane potential (RMP) is -70 mV

Resting Membrane Potential (RMP)

The resting membrane potential (RMP) is the electrical charge difference across
the membrane of a non-excited (resting) cell.

It is typically around -70 mV (millivolts), meaning the inside of the cell
(intracellular fluid, ICF) is negative relative to the outside (extracellular fluid,
ECF).

Key Points:

1. Cell Membrane as a Barrier:

o The cell membrane is selectively permeable, meaning it controls the
movement of ions (e.g., Na+, K+, Cl-, etc.) across the membrane.

2. Ion Distribution:

o There is a difference in the concentration of ions between the inside and
outside of the cell:

▪ Na+ (sodium) is more concentrated outside the cell (ECF).

▪ K+ (potassium) is more concentrated inside the cell (ICF).

▪ Cl- (chloride) is more concentrated in the ECF.

▪ Proteins and other large molecules are generally negative and
remain inside the cell.

3. The Role of the Na+/K+ Pump:

o The Na+/K+ ATPase pump actively transports 3 Na+ ions out of the cell and
2 K+ ions in against their respective concentration gradients, consuming
ATP. This pump helps to maintain the Na+ and K+ concentration gradients
that are essential for establishing the RMP.

o This process also contributes to the overall negative charge inside the cell.

4. Permeability of the Membrane:

o The cell membrane is more permeable to K+ ions than to Na+ ions, meaning
K+ ions tend to move out of the cell more easily, contributing to the
negative charge inside the cell.

5. Establishment of RMP:

o As K+ ions diffuse out of the cell, they leave behind negative ions (like
proteins and organic anions) inside, creating a negative charge inside the
cell.

o The equilibrium is reached when the electrical pull on K+ ions back into the
cell balances the tendency of K+ to diffuse out due to the concentration
 gradient. This helps establish a stable resting membrane potential of about
-70 mV.

Graphical Representation:

Resting Potential

The resting membrane potential is measured in millivolts (mV), with the inside of
the cell being negative relative to the outside. The RMP is a balance between the
concentration gradients of ions and the permeability of the membrane to those
ions.

Summary:

The RMP of about -70 mV is essential for nerve signaling, muscle contraction, and
overall cell function.

This negative charge inside the cell is maintained by active transport mechanisms
like the Na+/K+ pump and the differential permeability of the cell membrane to
different ions.

★ Why is the Resting Membrane Potential (RMP) -70 mV?

The resting membrane potential (RMP) is typically around -70 mV because of the
distribution of ions and the way the membrane behaves with respect to those ions. Here’s
a breakdown of why this charge imbalance exists and why it doesn't "neutralize" under
normal conditions:

Key Factors Involved in the RMP:

1. Ion Distribution:

o The concentration of ions across the cell membrane is uneven:
 ▪ Inside the cell (ICF): High concentration of K+ (potassium) (about
150 mM) and negatively charged proteins (e.g., Proteins^-, Organic
Phosphate^-, ATP^4-) (much higher than outside).

▪ Outside the cell (ECF): High concentration of Na+ (sodium) (about
150 mM) and Cl- (chloride) (about 120 mM), but much lower
concentration of K+ compared to the inside.

2. Selective Permeability:

o The cell membrane is more permeable to K+ ions than to Na+ ions. This is
crucial in establishing the RMP.

▪ K+ ions tend to diffuse out of the cell down their concentration
gradient (from high concentration inside to low concentration
outside), making the inside of the cell more negative.

▪ However, because the membrane is less permeable to Na+ and other
ions, the inside of the cell doesn't become neutralized by Na+ ions
entering or by negatively charged ions leaving.

3. Electrochemical Gradient:

o K+ ions are being pushed out of the cell due to the concentration gradient
(high concentration of K+ inside and low concentration outside).

o As K+ ions leave, negatively charged ions (e.g., proteins, phosphate)
remain inside, contributing to the negative charge inside the cell.

o The electrical gradient (the attraction of positive ions to negative charges)
works to pull the K+ ions back into the cell, balancing the concentration
gradient.

4. Role of the Na+/K+ ATPase Pump:

o The Na+/K+ pump is crucial for maintaining the ion gradients across the
membrane. It actively pumps 3 Na+ ions out of the cell and 2 K+ ions in,
maintaining the high concentration of Na+ outside and the high
concentration of K+ inside.

o This process is ATP-dependent and helps counteract the natural tendency
for Na+ to leak into the cell and K+ to leak out.

5. Why Don't Ions Neutralize the Charge?

o Even though the concentrations of positive ions (like Na+) are roughly the
same on both sides of the membrane, the selective permeability of the
membrane prevents many of these ions from moving freely across the
membrane.

o Positively charged ions (Na+) don't enter the cell easily because the
membrane is much less permeable to Na+ than it is to K+.

o The negative charges (from proteins, phosphates, etc.) inside the cell are
too large to move across the membrane and thus stay inside, further
 contributing to the negative charge inside the cell.

6. Why is the RMP Negative?

o The combination of K+ efflux (leaving the cell), the negative proteins inside,
and the fact that the membrane is far more permeable to K+ than to Na+
leads to a negative charge inside the cell relative to the outside.

o The typical RMP of -70 mV reflects the electrical potential difference
created by this imbalance of ion distribution and the membrane's selective
permeability.

Summary:

Imbalance of ions (high K+ inside, high Na+ outside) creates an electrochemical
gradient.

The cell membrane is much more permeable to K+, allowing it to diffuse out,
leaving behind negative ions.

The Na+/K+ ATPase pump maintains this ion gradient by actively pumping Na+ out
and K+ in.

The inside of the cell remains negative because negative ions (proteins,
phosphates) cannot diffuse out, and the membrane is impermeable to many
positive ions (like Na+).

This results in the resting membrane potential (RMP) being -70 mV—the inside of the cell
is negative relative to the outside.

Why is the Resting Membrane Potential (RMP) -70 mV? (Two factors explain this: Fick’s
law & Na/K pump)

The resting membrane potential (RMP) of approximately -70 mV is a result of two main
factors: Fick's law and the Na+/K+ pump.

1. Fick's Law of Diffusion
How Fick's Law Contributes to RMP:

2. Na+/K+ ATPase Pump (Sodium-Potassium Pump)

The Na+/K+ pump is an active transport mechanism that moves Na+ and K+ ions against
their concentration gradients using ATP as an energy source. This pump plays a crucial
role in maintaining the resting membrane potential.

The pump actively transports:

o 3 Na+ ions out of the cell, creating a high concentration of Na+ outside the
cell.

o 2 K+ ions into the cell, creating a high concentration of K+ inside the cell.

How the Na+/K+ Pump Contributes to RMP:

The Na+/K+ pump establishes and maintains the concentration gradients of Na+
(high outside, low inside) and K+ (high inside, low outside).

Since the membrane is more permeable to K+ than to Na+, K+ ions tend to move
out of the cell, but the pump works to counteract this by continuously pumping
Na+ out and K+ in.

This active transport helps maintain the high concentration of K+ inside the cell
and the high concentration of Na+ outside, which is necessary for the resting
membrane potential to stay at about -70 mV.

Summary:

Fick's Law: The movement of ions across the membrane (especially K+) is governed
by the concentration gradient and the permeability of the membrane. The high
permeability to K+ allows it to diffuse out of the cell, making the inside of the cell
more negative.

Na+/K+ Pump: The active transport of Na+ out of the cell and K+ into the cell
establishes and maintains the concentration gradients necessary for the resting
membrane potential.

Together, these two mechanisms ensure that the inside of the cell remains negative
relative to the outside, giving the cell its resting membrane potential of approximately -
70 mV.

★ Why is the Resting Membrane Potential (RMP) –70 mV?

The resting membrane potential (RMP) of approximately -70 mV results from two key
factors: Fick’s Law and the activity of the Na+/K+ pump, along with the presence of
"trapped anions" inside the cell.

1. Fick’s Law and Membrane Permeability

2. Na+/K+ ATPase Pump
3. "Trapped Anions" Inside the Cell

Summary of RMP = –70 mV:

Fick’s Law: While the concentration gradient for negative ions is high, their
permeability (PPP) is zero. Thus, they remain trapped inside.

Na+/K+ Pump: Actively maintains the concentration gradient of Na+ and K+,
crucial for the negative RMP.

Trapped Anions: Large, impermeable anions inside the cell maintain a negative
internal environment, preventing the neutralization of the charge difference
across the membrane.

Together, these mechanisms result in the cell’s resting membrane potential of about -70
mV, where the inside of the cell remains more negative relative to the outside.

★ Why Doesn’t the Resting Membrane Potential (RMP) Become Neutral?

Explanation:

In a resting cell, Na+ channels are usually closed, making P (permeability) almost
zero, preventing Na+ from entering despite the strong concentration gradient.

As a result, Na+ ions cannot enter the cell to neutralize the negative resting
membrane potential.
What About the Occasional Opening of Na+ Channels?

You’re right that some Na+ channels do occasionally open. However, several mechanisms
prevent the neutralization of the resting membrane potential:

1. Na+/K+ Pump (Active Transport):

o Even if some Na+ ions leak into the cell through the occasional opening of
Na+ channels, the Na+/K+ ATPase pump immediately works to extrude Na+
out of the cell and bring K+ in.

o For every 3 Na+ ions pumped out, only 2 K+ ions are brought in, thus
maintaining the negative charge inside the cell.

o This pump continuously counteracts any Na+ influx, preventing the
membrane potential from neutralizing.

2. Low Na+ Channel Permeability:

o The few Na+ channels that do open occasionally are not enough to allow a
significant influx of Na+ that would neutralize the RMP.

o Most of the time, K+ channels are more permeable, allowing K+ to leave the
cell, which helps keep the inside of the cell negative.

3. Dominance of Trapped Anions:

Conclusion:

Even if a few Na+ ions manage to leak into the cell through occasional channel openings,
the Na+/K+ pump and the presence of trapped negative ions prevent the membrane
potential from becoming neutral. These mechanisms ensure that the RMP remains stable
around -70 mV.

Na+/K+ Pump and Its Role in Maintaining the Resting Membrane Potential (RMP)

The Na+/K+ pump is crucial in maintaining the resting membrane potential (RMP) of cells,
typically at -70 mV. Here's how it works:
How the Na+/K+ Pump Functions

The Na+/K+ pump is an active transport mechanism that uses ATP to move ions
against their electrochemical gradients.

For each cycle, the pump:

o Expels 3 Na+ ions from the cell (moving Na+ out).

o Imports 2 K+ ions into the cell (moving K+ in).

This process results in a net export of one positive charge per cycle.

Why the Na+/K+ Pump Is Important for RMP

The pump is described as "electrogenic" because it contributes to the negative
charge inside the cell relative to the outside.

By continuously exporting more positive ions (Na+) than it brings in (K+), the
pump helps maintain a negative internal environment.

How It Maintains -70 mV RMP

1. Constant ATP Usage:

o The pump uses ATP continuously to maintain the ion gradients, which are
essential for the RMP.

o This constant export of positive charges (Na+) ensures that the inside of
the cell remains negatively charged.

2. Balancing Ion Leakage:

o While there is some Na+ leakage into the cell due to occasional channel
openings, the Na+/K+ pump actively removes Na+ to prevent the
neutralization of the RMP.

o Similarly, it brings in K+ ions, but not enough to offset the overall negative
charge, especially since K+ leaks out through other channels more easily.

3. Maintaining the Electrochemical Gradient:

o The activity of the Na+/K+ pump is essential for establishing and
maintaining the electrochemical gradient needed for various cellular
processes, including nerve impulses and muscle contractions.

Summary

The Na+/K+ pump plays a critical role in maintaining the -70 mV RMP by using ATP to
create and sustain ion gradients, thereby ensuring that the inside of the cell remains
negatively charged relative to the outside.
Mechanism of water movement & osmotic fragility of red
blood cells
★ How Does H₂O Cross the Membrane?

Water (H₂O) moves across the cell membrane primarily through osmosis, a process driven
by differences in osmolarity. However, the membrane's permeability to water is greatly
enhanced by specialized water channels known as aquaporins.

Mechanisms of Water Movement Across Membranes:

1. Aquaporins (Water Channels):

o Aquaporins are integral membrane proteins that form channels, allowing
water to flow in and out of cells.

o These channels are highly selective for water, enabling rapid and efficient
movement without allowing ions or other solutes to pass through.

o If aquaporins are absent or closed, water movement across the membrane
is significantly slower.

2. Osmosis:

o Water moves passively by osmosis, meaning it does not require metabolic
energy (ATP).

o Osmosis occurs when there is a difference in osmolarity across the
membrane.

o Water flows from a region of low osmolarity (fewer solutes, more water)
to a region of high osmolarity (more solutes, less water).

Why Is Water Movement Important?

1. Cell Volume Regulation:

o Cells must carefully regulate their internal water content to maintain cell
volume.

o Excess water influx can cause cells to swell and potentially burst (lysis).

o Insufficient water can lead to shrinkage (crenation), impairing cell
function.

2. Maintaining Homeostasis:

o Water balance is crucial for maintaining osmotic balance and electrolyte
concentrations within tissues.

o This balance is vital for processes like nerve impulse transmission and
muscle contraction.

3. Transport of Nutrients and Waste:

o Proper hydration ensures that cells can efficiently absorb nutrients and
 expel waste.

o Water movement helps facilitate diffusion of solutes and supports
metabolic activities.

4. Blood and Tissue Fluid Dynamics:

o Water movement between cells and the bloodstream helps maintain blood
pressure and tissue fluid balance.

By regulating water movement through aquaporins and osmosis, cells ensure they
function optimally within their surrounding environment, contributing to the organism’s
overall homeostasis.

What is Osmolarity?

Osmolarity is a measure of the concentration of solutes in a solution. It quantifies the
total number of osmoles of solute particles per liter of solution.

Definition:

Osmolarity = the amount of solute dissolved in 1 liter of water.

For example:

o If you dissolve 1 mole of glucose in 1 liter of water, you get a solution with
an osmolarity of 1 Osmolar (1 Osm).

How is Osmolarity Measured?

It is determined based on the number of solute particles present, not their size or
type.

Biological fluids typically contain a mix of ions, sugars, and other molecules that
contribute to the osmolarity.

Strictly speaking, osmolarity should be measured per 1 kilogram of water
(osmolality), but the difference is negligible in dilute biological fluids, so
osmolarity (per liter) is often used in practice.

Why is Osmolarity Important?

1. Predicting Water Movement Across Membranes:

o By measuring osmolarity on either side of a cell membrane, we can predict
which direction water will flow.

o Water moves by osmosis from a region of low osmolarity (fewer solutes,
more water) to a region of high osmolarity (more solutes, less water).

2. Maintaining Cellular and Body Fluid Balance:

o Cells must maintain the correct osmolarity to avoid swelling or shrinking,
which can lead to cellular dysfunction.
 o Osmolarity regulation is essential for processes like hydration, blood
pressure control, and organ function.

Understanding osmolarity helps in comprehending how cells interact with their
environment, particularly in maintaining homeostasis through water and solute balance.

★ What is Osmolarity… and How is It Measured for Salts?

Osmolarity is a measure of the total concentration of all solute particles dissolved in 1
liter of water. It tells us how many osmotically active particles are present, which
influences how water moves across cell membranes.

Osmolarity for Salts:

Salts, like sodium chloride (NaCl), dissociate into ions when dissolved in water.

1 mole of NaCl in 1 liter of water dissociates into 2 particles (Na⁺ and Cl⁻), so it
results in an osmolarity of:

o 2 Osmolar (2 Osm).

This means that salts contribute more to osmolarity than non-dissociating
substances like glucose because they break into multiple particles.

Key Concept:

Osmotically active ions affect how water moves through cell membranes by
creating an osmotic gradient.

Water will move from a region of lower osmolarity (fewer solute particles) to a
region of higher osmolarity (more solute particles) to balance concentrations on
both sides of a membrane.

Example:

If we measure the osmolarity on both sides of a cell membrane:

o Water will move by osmosis towards the side with higher osmolarity.

o This movement continues until equilibrium is reached or other regulatory
mechanisms (like ion pumps) adjust the balance.

Note:

Strictly speaking, osmolarity is measured per 1 kilogram of water (referred to
as osmolality), but in the context of dilute biological fluids, the difference is
minimal, so osmolarity (per liter) is often used.

Understanding osmolarity is crucial in physiology for predicting water movement,
maintaining cell volume, and ensuring proper function of tissues and organs.
What is Osmolarity… and How Is It Measured for Biological (Complex) Fluids?

Biological fluids like plasma are made up of various ions, proteins, and other molecules.
Measuring osmolarity in such complex solutions is essential for understanding water
balance in the body.

Plasma Composition Example:

Na⁺: 150 mM

K⁺: 5 mM

Ca²⁺: 2 mM

Other solutes (proteins, glucose, etc.): ~130 mM

Given the complexity, you might wonder: how do we measure the osmolarity of such a
mixture?

How Do We Measure Osmolarity in Biological Fluids?

Measuring the concentration of each solute individually and then summing them up would
be incredibly complex and time-consuming. Instead, there's a simpler way:

Method: Using the Concept of Freezing Point Depression

Osmolarity can be measured using the freezing point depression method.

The principle is that adding solutes to water lowers its freezing point.

More solutes = greater depression of the freezing point.

Why It Works:

The decrease in freezing point is directly proportional to the total concentration
of osmotically active particles in the solution, regardless of their nature (ions,
proteins, glucose, etc.).

This method provides a direct measure of osmolarity without needing to identify
and count each type of solute individually.

Practical Application:

By measuring the change in freezing point, we can quickly determine the
osmolarity of plasma or other biological fluids.

Normal plasma osmolarity is around 280-300 mOsm/L, which is critical for
maintaining cell function and fluid balance in the body.

Key Takeaway:

Instead of measuring each component separately, we use freezing point depression as a
practical, efficient method to assess osmolarity in complex fluids like blood plasma. This
helps in maintaining homeostasis, diagnosing electrolyte imbalances, and managing
conditions like dehydration or hyponatremia.
Osmolarity is Measured by Depression of Freezing Point

The freezing point of a solution decreases in proportion to the total concentration of
osmotically active particles present. This concept allows us to measure osmolarity
without knowing the exact composition of the solutes.

Key Principle:

Adding solutes to water lowers its freezing point.

One mole of any solute will depress the freezing point of water by 1.86°C.

Examples:

1. Glucose Solution:

o 1 M glucose (1 Osm) will freeze at -1.86°C.

2. Sodium Chloride Solution (NaCl):

o 0.5 M NaCl dissociates into 2 ions (Na⁺ and Cl⁻), making it 1 Osm.

o This solution will also freeze at -1.86°C.

Applying This to Plasma:

The freezing point of plasma is around -0.52°C.

To calculate the osmolarity:

Key Takeaway:

Freezing point depression provides a simple way to measure the osmolarity of
biological fluids.

This method does not require detailed knowledge of the individual solute
composition, making it practical for assessing fluid balance and electrolyte
status in medical diagnostics.

★ ICF and ECF Solute Compositions Differ…

But there is no net movement of water between the intracellular fluid (ICF) and
extracellular fluid (ECF). Let's explore why.

Differences in Solute Concentrations:

Extracellular Fluid (ECF), e.g., Plasma:
 o Na⁺: 150 mM (high)

o K⁺: 5 mM (low)

o Ca²⁺: 2 mM (high)

o Other Solutes: ~130 mM (variable)

Intracellular Fluid (ICF), e.g., Muscle Cell:

o Na⁺: 10 mM (low)

o K⁺: 150 mM (high)

o Ca²⁺: 0.0004 mM (extremely low)

o Other Solutes: ~130 mM (variable)

Why is there No Net Water Movement?

Despite the differences in specific solute concentrations, the total osmolarity of
both ICF and ECF is the same.

o Osmolarity of ECF: ~280 mOsm

o Osmolarity of ICF: ~280 mOsm

Osmolarity is the total concentration of osmotically active particles in a solution.

Water moves by osmosis from areas of low osmolarity to areas of high osmolarity.

Since the osmolarity is balanced between ICF and ECF, there is no osmotic gradient
to drive the movement of water in either direction.

Key Takeaway:

The selective permeability of cell membranes and the action of ion pumps (e.g.,
 Na⁺/K⁺ pump) maintain the solute concentration differences.

However, the total osmolarity remains the same, preventing any net movement of
water between the compartments, thereby maintaining fluid balance and cellular
stability.

★ Osmotic Fragility of Red Blood Cells (RBCs)

Key Facts:

Intracellular Fluid (ICF) of RBC: 280 mOsm

Red Blood Cell (RBC) membrane: Contains aquaporins that allow water to move
freely across the membrane.

What Happens in Plasma with 280 mOsm?

1. Is there an Osmotic Gradient?

o No, because the osmolarity of plasma is the same as that of the ICF in RBCs.

o The solutions are isosmotic (i.e., they have equal osmolarity).

2. Is there Net Osmosis?

o No, since there is no osmotic gradient.

o As a result, no net movement of water occurs across the RBC membrane.

3. What is the Effect on RBCs?

o The RBC maintains its normal size, shape, and function in an isosmotic
environment.

o This is crucial for the optimal functioning of RBCs in transporting oxygen
throughout the body.

Conclusion:

In an isosmotic solution (280 mOsm), RBCs remain stable because there is no net
movement of water across their membranes, allowing them to maintain their structural
integrity and biological function.
★ Osmotic fragility of Red Blood cells

In a 140 mM NaCl solution, the osmolarity is similar to that of plasma and the
intracellular fluid (ICF) of the RBCs. Let's break it down:

What Happens in 140 mM NaCl Solution?

1. Is there an Osmotic Gradient?

o No, because the osmolarity of the 140 mM NaCl solution is 280 mOsm (since
NaCl dissociates into Na⁺ and Cl⁻, contributing 2 osmoles per mole).

o The ICF of RBCs is also 280 mOsm, and the solution outside (plasma or 140
mM NaCl) is the same, so there is no osmotic gradient.

2. Is there Net Osmosis?

o No, because there is no difference in osmolarity between the inside of the
RBC and the outside environment.

o Since the solution is isosmotic, no net osmosis occurs.

3. Effect on RBCs:

o The RBC will maintain its normal size, shape, and function because there is
no movement of water into or out of the cell.

o The presence of aquaporins in the RBC membrane allows water to cross,
but since there is no osmotic gradient, water does not flow in or out,
keeping the cell stable.

Conclusion:

In a 140 mM NaCl solution (isosmotic with the RBC's intracellular fluid), there is no
osmotic gradient or net osmosis, so the RBC will maintain its no