Solubility & Membrane Transport PDF - Ajman University

Summary

This document is a lab session on solubility and membrane transport. The material covers topics such as homogenous vs heterogeneous mixtures, solvents, solutes, and solutions. The document also covers concepts of hydrophilic and hydrophobic substances and properties of water. The presentation is appropriate for a university-level biology or chemistry course.

Full Transcript

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Solubility &
Membrane Transport Lab Session 3

Amine BAHI, PhD

September 17, 2024

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Main Objectives
Differentiate between homogenous & heterogenous mixtures
Understand the concept of solubility and identify the solvent and solute
Distinguish between hydrophilic and hydrophobic substances with relation to water
molecules
Recall and understand the different mechanisms involved in cell membrane transport
Understand the structure, function, and importance of the blood-brain barrier in
maintaining brain health by regulating substance exchange between the bloodstream
and the brain

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Homogenous vs. Heterogenous
Homogeneous mixtures have uniform composition
Homogenous matter − has identical properties throughout (Salt water, coffee…)
Heterogeneous mixtures have non-uniform composition
Heterogeneous matter − has parts with different properties (soil, cookies…)

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Solvent, Solute, & Solution
Solvent − substance that dissolves a solute, resulting in a solution
Solute − substance that is dissolved in the solvent
Together, this combination (solute & solvent ) creates a uniform homogeneous
mixture where the solute is distributed evenly within the solvent

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Solubility
Ability of a substance/solute to dissolve in a solvent to form a homogeneous
solution
Typically expressed as the maximum amount of solute that can dissolve in a
given amount of solvent at a particular temperature
Temperature − Solubility of solids usually increases with temperature
Nature of solute and solvent − Polar solutes dissolve better in polar
solvents, and nonpolar solutes dissolve in nonpolar solvents.

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Solubility

Solubility is directly affected by the nature of the solvent & the solute

according to the rule: “Like Dissolves In Like”

Polar compounds dissolve polar compounds

Nonpolar compounds dissolve nonpolar compounds

Polar and nonpolar do not dissolve in each other

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Polar vs. Nonpolar
Polar molecules − electrons are not equally shared
One part of the molecule is more negative than the other part
The molecule has positive and negative “poles” like a battery
These molecules are called hydrophilic (water-loving)
Nonpolar molecules − electrons are equally shared
None of the part of the molecule is distinctly negative or positive “no poles”
These molecules are called hydrophobic (water-fearing)

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Water − The Universal Solvent
One of the most valuable properties of water is its dissolving ability
Oxygen is more electronegative than Hydrogen
It has a greater tendency to gain electrons
Oxygen has a partially negative charge
Hydrogen has partially positive charges
Unequal charge distribution − water is polar having
positive & negative partial charges on its ends

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Hydrophilic vs. Hydrophobic
Charged molecules (Ionic and Polar) are
Hydrophilic (water-loving, water soluble)
Example: water & salt
Uncharged molecules (non-polar) are
Hydrophobic (water-fearing, not water soluble)
Example: water & foil
Hydrophobic & Hydrophilic substances
DON’T MIX
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Hydrophilic vs. Hydrophobic

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Drug Dissolution & Absorption
Drugs taken orally will pass through a variety of
organs before reaching the general circulation
they will face several barriers retarding their
absorption and their bioavailability
Rate at which the drug enters systemic
circulation, thereby accessing the site of action
Drugs will first pass through the stomach &
intestine

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Cell Membrane Structure
Cell membrane separates living cell from nonliving surroundings (8 nm thin barrier)
Controls traffic in & out of the cell
Selectively permeable − allows some
substances to cross more easily than
others (hydrophobic vs. hydrophilic)
Major components: phospholipids,
proteins & other macromolecules

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Cell Membrane Structure
The membrane − a lipid barrier with small holes through

The pore size & distribution is not uniform between different parts of the body

Small lipid molecules should readily cross this membrane

Larger lipid insoluble molecules couldn’t

Small polar compounds could slowly cross the membrane

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Mechanisms of Membrane Transport
Molecules are transported across the cell membrane by different mechanisms:
Passive diffusion
Pore transport
Carrier-mediated transport
Facilitated diffusion
Active transport
Endocytosis

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Passive Diffusion
Movement molecules across a membrane that requires no energy
It is the difference in drug concentration on either side of the membrane
Movement of molecules high concentration to low concentration
Absorption of approximately 90% of drugs

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Pore Transport
Also known as bulk flow or filtration
Mechanism − through the protein channels
present in the cell membrane
Important in the absorption of low molecular
weight/size
Generally ideal for water-soluble drugs (urea,
sugars…)

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Carrier-Mediated Transport
Involves a carrier which reversibly binds to the solute and forming a solute-carrier
complex
Generally used by hydrophilic molecules
Specific proteins recognize the target molecules and transport them across the cell
Two types of carrier-mediated transport systems:
Facilitated diffusion

Active transport

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Carrier-Mediated Transport
Facilitated diffusion − form of carrier transport that doesn’t require the expenditure of
cellular energy
The driving force is concentration gradient
Movement from high to low concentration
Transport trough integral membrane proteins
Mediates the absorption of some simple sugars,
steroids, amino acids from the small intestine
and their transfer across cell membrane

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Carrier-Mediated Transport

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Carrier-Mediated Transport
Active transport− it requires a certain form of energy for molecules transport
across the membrane
Primary active transport directly uses a source of chemical energy (ATP)
Secondary active transport doesn’t use ATP but uses an electrochemical
gradient as energy source
Molecules movement across a membrane against their concentration
gradient

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Carrier-Mediated Transport
Primary active transport − one of the most important pumps in animal cells is
the sodium-potassium pump, also known as Na⁺/K⁺ ATPase
The enzyme pumps 3 Na+ out of the cell and 2 K+ that into the cell, for every
single ATP consumed  Antiport mechanism
The sodium and potassium move against the concentration gradients
The ATPase pump maintains the gradient of a higher concentration of sodium
extracellularly and a higher level of potassium intracellularly

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Carrier-Mediated Transport

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Carrier-Mediated Transport
Secondary active transport − the movement of the sodium down its gradient is
coupled to the uphill transport of other substances by a shared carrier protein
(cotransporter)
The carrier protein uses the energy of the sodium gradient to drive the transport of
glucose  symport mechanism
An electrochemical gradient refers to the combined effect of two gradients: the
concentration gradient and the electrical gradient across a membrane
It drives the movement of ions across the membrane

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Carrier-Mediated Transport

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Endocytosis
This transport system involves engulfing extracellular materials within a
segment of the cell membrane to form a vesicle (vesicular transport)
which is pinched off intracellularly
Endocytosis includes two types of processes:
Phagocytosis − cell “eating”
Pinocytosis − cell “drinking”

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Endocytosis
Phagocytosis − a process involves the uptake of large solid
macromolecules. Also called “cell eating”

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Endocytosis
Pinocytosis − “cell drinking” used for the absorption of small liquid molecules
such as dissolved fats (ex. LDL) and vitamins
Used by immune cells to “check” the extracellular fluid for antigens (toxins or
foreign substances)

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Blood Brain Barrier
The BBB is a collection of specialized cells & proteins controlling molecules
movement from blood to the central nervous system (CNS)
Endothelial cells are cemented together by protein structures called tight
junctions
They prevent diffusion of most molecules between cells
Pericytes & astrocytes serve as an additional physical barrier between the
blood vessel & brain tissue

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Blood Brain Barrier

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Blood Brain Barrier

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Blood Brain Barrier
The BBB is one of the most essential protection mechanisms in the CNS
It maintains normal brain function
The neural environment must be preserved within a narrow homeostatic range
This requires a tight regulation of transportation of molecules & ions between the
blood & the brain
It selectively allows individual molecules such as small lipid-soluble molecules to
pass through the capillary endothelial membrane while limiting the passage of
pathogens or toxins

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Blood Brain Barrier
To pass freely through the capillary wall & into the brain tissue, the tight gap allows
only:
Water
Gases (CO2, O2, N2O and volatile anesthetics…)
Small molecules (glucose, amino acids…)
Fat-soluble molecules (steroids, alcohols, fatty acids…)
Ions (Na+, Cl-, Ca++…)

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