Human Physiology Silverthorn 7e Chapter 5 Membrane Dynamics

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Osmolarity

# of osmotically active particles (ions or intact molecules)/Liter of solution Expresses number of particles Must take two things into consideration: Penetrating solutes (glucose) Non-penetrating solutes (sodium, potassium, chloride) dissolve in solution but don't cross membrane

3 ways to enter a cell

(1) Cross lipid bi-layer (2) Passive Transport (3) Active Transport

Transport Proteins pg139

ABC and SLC

Simple diffusion

Diffusion directly across the phopholipid bilayer of a membrane

Carrier-Mediated Transport

Facilitated Diffusion and Active Transport

Table 5.6 Rules for Diffusion of Uncharged Molecules pg135

Know this table for exam

Diffusion

Movement from high to low concentration

Isotonic Saline

Normal Saline

Figure 5.17 Transporter saturation and competition (c) pg146

Saturation

Hypokalemic

Someone can possible have a heart attack with this situation, they are treated with a hypertonic solution

Figure 5.14 The Sodium-potassium Pump pg143

When going against a gradient ATP used

Apical Membrane

contains sodium glucose transporter on surface

Transporting epithelia are polarized

microvilli always face the lumen

"tonic"

tells what cells will do at the end of the solution

Membrane Proteins have 4 major functions

(1) Structural (2) Enzymes (3) Receptors (4) Transport Proteins

Rules for predicting tonicity

(1)Cell has higher concentration of nonpenetrating solutes than solutoin--water moves into cell--swells. Solution hypotonic (2)Cell has lower concentration of nonpenetrating solutes than solution--water moves out--shrinks. Solution hypertonic (3)Concentration of nonpenetrating solutes are same in cell and solution--no water movement--Solution isotonic

Transepithelial Absorption of Glucose

1. Na+ glucose sumporter brings glucose into cell against its gradient using energy stored in the Na+ concentration gradient. 2.GLUT transporter transfers glucose to ECF by facilitated diffusion 3. Na+-K+-ATPase pumps Na+ out of the cell, keeping ICF na+ concentration low. Ouabain (medication) blocks sodium potassium pump)

Extracellular Fluid (ECF)

1/3 of the total body water volume. Consists of Interstitial fluid and blood plasma Concentration of Na+, Cl-, and HCO3-

Percent Total body water Fig 5.1 Body Fluid Compartments Compartment Volumes for "Standard" 70kg man

28L Intracellular Fluid (2/3 of total body water volume) 14L Extracellular Fluid (1/3 of total body water volume) Plasma (25%) and Interstitial Fluid (75%)

Carrier-Medicated Transport pg140

3 different forms Uniport Symport Antiport (one in and one out)

Normal Person Homeostatic Concentration in body

300mOsM

What is a person's total blood water volume?

42L

Hypertonic

5mM potassium given to someone who is hyperkalemic

Concentration gradient

A difference in the concentration of a substance between two places. Also known as a chemical gradient. The larger the concentration gradient, the faster diffusion takes place.

If you have a 1 M solution of sodium chloride, how much is found to be dissociated in water? pg126

About 1.8 osmolarity of sodium chloride ions are found dissociated (not all) when added to water 1.8 X 6.023-10^-23 (Avogadro's Number)

The body is mostly water, we see a greater variation of water content in humans according to what factors?

Age-- decreases as people grow older than 60. Infants have more water content than adults Sex-- Women have less water per kilogram of body mass than men because women have more adipose tissue.

What does tonicity compare?

Always compares a solution and a cell. Used to describe only the solution--for example "Solution A is hypotonic to red blood cells."

Epithelial Transport Mechanism

Apical Membrane (Mucosal membrane) Basal Membrane (serousal membrane) Paracellular Transport (Through junctions between adjacent cells) Transcellular Transport (through cells themselves and transcytosis with vesicular transport)

Table 5.2 Comparing Osmolarities pg.127

Be able to tell how a solution relates to another solution.

Electricity Review

Because they are opposite charge (positive and negative) to separate them requires energy.

How does water move?

By traversing water filled ion channels and special water channels created by protein aquaporin (AQP)

All Living cells have a membrane potential

Can be measured with pipette and voltmeter

Caveolae

Can participate in signalling Important in uptake of viruses In two different forms of multiple sclerosis we have abnormal caveolae

Cell membranes are selectively permeable

Cell membrane restriction Whether or not a substance enters a cell depends on the properties of a cell membrane and those of the substance.

Hypercholesteremia

Cells fail to take up LDLs and person has a-lot of cholesterol in their blood.

Chemical disequilibrium

Chemical differences between inside and outside of cell. Some solutes more concentrated in one of the two body compartments. Energy is required to return solutes to the compartment they left (example Sodium-potassium pump)

Figure 5.16 Sodium-glucose cotransport pg145

Chemical gradients carry energy to promote events. From high sodium to low sodium High sodium binds to high affinity site for glucose Glucose binding changes carrier conformation so that binding sites now face the ICF Na+ released into cytosol

Figure 5.17 Transporter saturation and competition (d) pg146

Competition

How is Osmolarity a colligative property?

Depends strictly on the number of particles per liter of solution.

Fick's Law of Diffusion

Diffusion rate increases when surface area, the concentration gradient, or the membrane permeability increase.

Primary Active Transport

Direct Transport uses ATP

Homeostasis

Does not equal equilibrium It is disequilibrium

Osmotic equilibrium and the two disequilibria are in what type of state?

Dynamic Steady State

Receptor Mediated Endocytosis

Dynemin pinches the top off of the vesicle during endocytosis to allow for the vessicle to move around freely. Vessicle loses its clatherin. Vessicle can travel through the cells using ravs and SNAIREs Ligands released Vessicles return to surface of cell fuse with cell membrane for exocytosis and recycling of receptors Ligands either got to lysozomes or to golgi apparatus

Secretion

ECF back to lumen inside/out

Figure 5.23 Membrane Potential (a) pg154

ECF has a slight excess of cations (+) ICF has a slight excess of anions (-)

TRUE or FALSE Material moving into and out of the ICF does not need to cross the cell membrane.

FALSE Must cross the cell membrane.

TRUE OR FALSE Without water, life as we know it is able to exist.

FALSE No, life cannot exist without water.

Osmotic equilibrium

Fluid concentrations equal on both sides (ICF and ECF) Due to the free movement of water.

Intracellular Fluid (ICF)

Fluid within the cells 2/3 of the total body water volume. Concentration of K+ ions

Osmotic Pressure Figure 5.2 pg126

Force that moves the water that is applied to exactly oppose osmosis Can be measured using a chamber If you have non-penetrating solutes, water can move across the membrane.

Glucose Transporters

GLUT

Fluids

Gases--compressible Liquids-not compressible

Atherosclerosis

Hardening of arteries

What are the two distinct fluid compartments of the body?

ICF-intracellular fluid--CELLS ECF-extra cellular fluid--FLUID THAT SURROUNDS THE CELLS

Permeable

If a membrane allows a substance to pass through it, the membrane is said to be permeable to that substance.

Impermeable

If a membrane does now allow a substance to pass, the membrane is said to be impermeable to that substance.

Transcytosis across lumen of the intestine

In our intestine we are making IgA that binds to things we do not want in our bodies.

Secondary Active Transport

Indirect Uses potential energy of another molecules uses downhill gradient from one ion or molecule to power the uphill movement

Phagocytosis

Integrins C3bi

The body compartments are in a state of chemical disequilibrium. The cell membrane is a selectively permeable barrier between the ECF and ICF.

Intracellular fluid Interstitial Fluid- High level of Na+ and Cl- Interstitial Fluid-high level of Na+ and Cl- Plasma- High level Na+, Cl-, and proteins

What purpose does the Extracellular Fluid have?

It is the buffer between the cells and the environment outside the body.

Table 5.5 Intravenous Solutions

Know whether they are receiving isotonic or hypotonic solutions, based on non penetrating or penetrating

Where does the interstitial fluid (IF) lie?

Lies between the circulatory system and the cells. Between the tissues.

What are the factors affecting the rate of diffusion through a cell membrane?

Lipid solubility Molecular size Concentration gradient Membrane surface area Composition of lipid layer

Figure 5.11 The Structure of Channel Proteins pg 141

Lipophillic outside and a polar core that allows for movement of ions

Figure 5.15 Mechanism of the Na+-K+-ATPase pg144

Loads on low concentration side See Abigail's recording

LDLs

Low Density Lipoproteins bind to cholesterols

Absorption

Lumen to ECF outside/in

Molarity

Moles/Liter Moles of dissolved solute per liter of solution Expresses concentration

Bulk Flow

Most general form of biological transport of fluids within a compartment. Presure gradient--flow of fluid from regions of higher pressure to regions of lower pressure.

Cell Membrane Enables separation of Electrical Charge in the Body

Movement of K+ ions out of the cell according to chemical gradient Negative ions cannot follow because the membrane is impermeable to anions Electrical gradient established Electrochemical gradient- combination of electrical and concentration gradient Equilibrium potential Eion is the membrane potential that oppposes the concentration gradient (caluculated using Nernst equation)

Osmosis

Movement of water across a membrane in response to a solute concentration gradient Fluids can be liquid or gas, but not ions, not polar or large proteins (these are not permeable) Permeability depends on lipids and proteins

Tonicity

Of a solution, describes the volume change of a cell at equilibrium. Same osmolarity on both sides of membranes allows for retaining of tension Depends on the concentration of the nonpenetrating solutes.

Hyperosmotic solution

One solution has a higher osmolarity (contains more particles per unit volume, more concentrated) than the other solution. One side is higher (hyperosmotic) than the other (hyposmotic)

Hyposmotic Solution

One solution has fewer osmoles per unit volume it is considered this. Always hypotonic

What can move across membranes by simple diffusion?

Only lipids, steroids, and small lipophilic molecules. (non-polar molecules that are lipid soluble (lipophilic) can dissolve in the central lipid core of a membrane. Excepetion is water (although polar) which can diffuse slowly across some phopholipid membranes because of its small size.

How do we establish resting membrane potential?

Overall body is electrically neutral Chemical disequilibrium between ICF (net negative) and ECF (net positive)

Nonpenetrating solutes

Particles that cannot cross the cell membrane Most important in physiology NaCl (functionally nonpenetrating)

Vesicular Transport for Thursday

Phagocytosis Endocytosis Caveolae Exocytosis

Probenicid Medication

Prevents the re-absorption of Uric Acid Flushed out in Uric acid Note: Uric acid pump is competable, saturable, and specific

Active Transport pg133

Requires the input of energy from some outside source, such as the high energy phosphate bond of ATP.

All living cells have a membrane potential

Resting Membrane potential difference (membrane potential) Resting is the steady state Potential energy stored in the electrochemical gradient Difference in electric charges inside and outside of the cell There are two forces competing the concentration gradient pushing potassium out because more inside than outside - but then the positive environment on the outside pushes potassium back in because there are more positive outside.

Figure 5.24 Measuring Membrane Potential pg157 ****Must know this for exam*****

Resting membrane potential of a Cell -70 mV Polarized to start Hyperpolarize- moving farther away from zero Depolarize-moving closer to zero Repolarization- back to resting Leak channels maintain membrane potential.

Figure 5.22 Transcytosis across the capillary endothelium pg153

Review in book

Figure 5.16 Sodium-Glucose Cotransport pg 145

SGLT-Sodium Glucose Transporter

What are the two properties of a molecule that influence its movement across cell membranes?

Size and lipid solubility.

Figure 5.6 Diffusion Experiment

Small substances diffuse more rapidly than large substances

Penetrating solutes

Solute particles (ions or molecules) that can enter the cell by crossing the cell membrane.

Table 5.3 Tonicity of Solutions

Solution is hypotonic-water wants to move into the cell "swells" Solution is Isotonic-Cell doesn't change Solution is hypertonic-water wants to move out cell "shrinks"

Functions of Membrane Proteins

Structural proteins Enzymes Membrane receptor proteins Transporters Channel proteins Carrier proteins

TRUE or FALSE Body is mostly water

TRUE

TRUE or FALSE Everything that enters or leaves most cells passes through the ECF (extracellular fluid).

TRUE

TRUE or FALSE In osmosis, water moves to dilute the more concentrated solution. Once concentrations are equal, net movement of water stops.

TRUE

TRUE or FALSE Ions move in response to combined electrical and concentration gradients, or electrochemical gradients.

TRUE

TRUE or FALSE Membranes with high cholesterol content are less permeable to water than those with low cholesterol content, presumably because the lipid-soluble cholesterol molecules fill spaces between fatty acid tails of the lipid bilayer and thus exclude water.

TRUE

TRUE or FALSE The ECF and ICF are in osmotic equilibrium but in chemical and electrical disequilibrium.

TRUE

TRUE or FALSE The lipid and protein composition of a give cell membrane determines which molecules will enter the cell and which will leave.

TRUE

TRUE or FALSE Tonicity depends on the concentration of nonpenetrating solutes only.

TRUE

TRUE or FALSE Very large lipophobic molecules cannot be transported on proteins and must enter and leave cells in vesicle.

TRUE

TRUE OR FALSE Most water movement across membranes takes place through protein channels.

TRUE Example: Cells insert special water channel proteins into the phospholipid bilayer in parts of the kidney which would otherwise be impermeable to water.

TRUE or FALSE Number of particles determines movement of water

TRUE The important factor for osmosis is the number of osmotically active particles in a given volume of solution, not the number of molecules. Because some molecules dissociate into ions when they dissolve in a solution, the number of particles in solution is not always the same as the number of molecules.

TRUE or FALSE The body is in a state of osmotic equilibrium

TRUE Water is able to move freely between cells and ECF, distributing itself until concentrations are equal throughout the body.

If Ouabain blocks sodium potassium ATPase, what effect will it have on the glucose on the lumen?

The concentration of the glucose would increase because there would be no gradient (Na+ concentration gradient engery) for it to use to move in, thereby increasing the concentration of the glucose in the lumen, since it is not moving in.

Electrical disequilibrium

The ionic imbalance that results from the ICF being slightly negative relative to ECF being slightly positive. Changes in this disequilibrium creates electrical signals Body as a whole electrically neutral

Substances moving between the plasma and interstitial fluid must cross what?

The leaky exchange epithelium of the capillary wall.

What is blood plasma?

The liquid matrix of blood found inside the circulatory system.

Osmolarity

The number of osmotically active particles (ions or intact molecules) per liter of solution.

What are the two subcompartments of the extracellular fluid (ECF)?

The plasma and the interstitial fluid (IF).

Why can't osmolarity be used to predict tonicity?

The tonicity of a solution depends not only on its concentration (osmolarity) but also on the nature of the solutes in the solution.

In the end what happens to the volume of the cells

The volume increases due to NaCl being a hypotonic solution

Why do smaller molecules and ions such as Na+ and Cl- have the same concentrations in plasma and interstitial fluid?

They are small enough to pass freely between the endothelial cells.

Why are proteins and other large anions concentrated in the plasma?

They cannot cross the leaky exchange epithelium of blood vessels, so they are mostly absent from the interstitial fluid.

TRUE or FALSE If a membrane is permeable only to water and not to any solutes, water will move by osmosis from a less concentrated (hyposmotic) solution into a more concentrated (hyperosmotic) solution.

True

True or False Chemically gated channels are normally open

True

True or False Normally gated channels are closed or inactive

True

True or False Urea is penetrating

True

True or False Men have a higher percentage of water in their bodies than females

True Females have less water and more adipose

True or False A carrier protein can move only 1,000 to 1,000,000 molecules per second, in contrast to tens of millions of ions per second that move through a channel protein

True pg141

True or False NaCl is a nonpenetrating

True, NaCl is the most important non-penetrating solute in physiology.

Isosmotic Solution

Two solutions contain the same number of solute particles per unit volume.

Hypotonic

Unusually to give to a patient because cells will break at the end of the solution. Used in lab to rupture red blood cells to count white blood cells Glucose is a penetrating solute making an IV solution of D5W hypotonic. Water will move into the cell where the ions are.

Transcellular transport of glucose

Uses membrane proteins

Protein mediated transport

Vast majority of solutes cross membranes with the help of membrane proteins because the majority of molecules in the body are either lipophobic or electrically charged and therefore cannot cross membranes by simple diffusion.

What is essentially the only molecule that moves freely between cells and the extracellular fluid?

Water

Channels

Water Channel-Aquaporin allows for osmosis to happen Ion Channels Open Channels Gated Channels Chemically gated Voltage-gated Mechanically gated (pressure sensitive)

Questions: Mother brings baby to ER because has been vomiting and diarrhea for 2 days. After weighing the baby they find that the baby has lost 2lbs. What percentage has the baby lost?

We can use the solute over volume concentration formula. 2/2.2=0.91kg of water or 0.91 L Look at example of pages 130 and 131

Since osmolarity alone does not tell you what happens to a cell when placed ina solution, what does Tonicity tell you?

What happens to cell volume at equilibrium when the cell is placed in the solution

Why is it important to allow for variability of body water content when prescribing drugs?

Women and older people have less body water and will therefore have a higher concentration of the dug in the plasma

If a woman is given a lipid soluble drug and gave a man the same, would the dosage need to be different

Yes, women will store in adipose

Facilitated diffusion

a form of passive transport does not require energy example: Osmosis A mediated transport that is passive and that moves molecules down their concentration gradient, net transport stops when concentrations are equal on both sides of the membrane.

Basolateral Membrane

contains sodium potassium ATPase

mOsM (see pg126)

milliosmoles per Liter

Passive Transport (know all of the processes in the video)

no energy required uses kinetic energy inherent in molecules and the potential energy stored in concentration gradients

Figure 535 Transport across membranes

oxygen and carbon dioxide move easily across the membrane large molecules, polar molecules do not move easily across the membrane

Dynamic equilibrium

state in diffusion where concentration has equalized throughout the system but molecules continue to move.

Active transport

transport against concentration gradients requires energy from cell (ATP) or outside source Example Sodium Potassium Transportation


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