Resting membrane potential

Last updated: February 23, 2023

Resting membrane potential

Term 1

Term 1

Glycolysis
Electron transport chain and oxidative phosphorylation
Glycogen metabolism
Citric acid cycle
Gluconeogenesis
Pentose phosphate pathway
Fatty acid oxidation
Fatty acid synthesis
Cholesterol metabolism
Ketone body metabolism
Amino acids and protein folding
Enzyme function
Amino acid metabolism
Nitrogen and urea cycle
Protein structure and synthesis
Cellular structure and function
Cell membrane
Selective permeability of the cell membrane
Extracellular matrix
Cell-cell junctions
Endocytosis and exocytosis
Osmosis
Resting membrane potential
Cell signaling pathways
Nuclear structure
Cytoskeleton and intracellular motility
Inflammation
Ischemia
Free radicals and cellular injury
Atrophy, aplasia, and hypoplasia
Metaplasia and dysplasia
Hyperplasia and hypertrophy
Oncogenes and tumor suppressor genes
DNA structure
Transcription of DNA
Translation of mRNA
DNA replication
DNA damage and repair
Cell cycle
Mitosis and meiosis
DNA mutations
Mendelian genetics and punnett squares
Inheritance patterns
Gene regulation
Epigenetics
Independent assortment of genes and linkage
Polymerase chain reaction (PCR) and reverse-transcriptase PCR (RT-PCR)
Gel electrophoresis and genetic testing
DNA cloning
Galactosemia
Homocystinuria
Phenylketonuria (NORD)
Tay-Sachs disease (NORD)
Pyruvate dehydrogenase deficiency
Kwashiorkor
Marasmus
Folate (Vitamin B9) deficiency
Vitamin B12 deficiency
Down syndrome (Trisomy 21)
Patau syndrome (Trisomy 13)
Edwards syndrome (Trisomy 18)
Turner syndrome
Klinefelter syndrome
Ehlers-Danlos syndrome
Marfan syndrome
Myocardial infarction
Iron deficiency anemia
Alpha-thalassemia
Beta-thalassemia
Sickle cell disease (NORD)
Glucose-6-phosphate dehydrogenase (G6PD) deficiency
Autoimmune hemolytic anemia
Introduction to pharmacology
Pharmacokinetics: Drug metabolism
Cystic fibrosis
Osteomalacia and rickets
Septic arthritis
Rheumatoid arthritis
Juvenile idiopathic arthritis
Gout
Osteoarthritis
Osteoporosis
Diabetes mellitus
Gestational diabetes
Lower urinary tract infection
Insomnia
Major depressive disorder
Selective serotonin reuptake inhibitors
Serotonin and norepinephrine reuptake inhibitors
Suicide
Generalized anxiety disorder
Anxiety disorders: Clinical
Social anxiety disorder
Panic disorder
Obsessive-compulsive disorder
Endocrine system anatomy and physiology
Acromegaly
Insulin
Glucagon
Growth hormone deficiency
Hunger and satiety
Wound healing
Anticoagulants: Direct factor inhibitors
Platelet plug formation (primary hemostasis)
Cartilage structure and growth
Oxygen-hemoglobin dissociation curve
Karyotyping
Fluorescence in situ hybridization
Bone histology
Nasal cavity and larynx histology
Adrenal gland histology
Bronchioles and alveoli histology
Cartilage histology
Thyroid and parathyroid gland histology
Pancreas histology
Skeletal muscle histology
Trachea and bronchi histology
Arteriole, venule and capillary histology
Sympathetic nervous system
Parasympathetic nervous system
Nervous system anatomy and physiology
Cholinergic receptors
Muscle contraction
Muscle weakness: Clinical
Skin anatomy and physiology
Psoriasis
Epidermolysis bullosa
Albinism
Vitiligo
Acne vulgaris
Skin cancer
Alopecia areata
Sunburn
Actinic keratosis
Burns
Cell-mediated immunity of CD4 cells
Cell-mediated immunity of natural killer and CD8 cells
Pneumonia
Vaccinations
Introduction to the immune system
Monoclonal antibodies
Antibody classes
B-cell activation, differentiation, and contraction
B-cell development
Body temperature regulation (thermoregulation)
Cluster headache
Tension headache
Migraine
Meningitis
Brain abscess
Hashimoto thyroiditis
Thyroid hormones
Euthyroid sick syndrome
Human development week 2
Human development days 4-7
Human development week 3
Ectoderm
Mesoderm
Endoderm
Adrenal cortical carcinoma
Primary adrenal insufficiency
Congenital adrenal hyperplasia
Adrenocorticotropic hormone
Synthesis of adrenocortical hormones
Ornithine transcarbamylase deficiency
Neuron action potential
Fats and lipids
Innate immune system
T-cell development
Cytokines
T-cell activation
MHC class I and MHC class II molecules
B- and T-cell memory
Graves disease
Asthma
Polymerase chain reaction (PCR) and reverse-transcriptase PCR (RT-PCR)
Williams syndrome
Calcium pyrophosphate deposition disease (pseudogout)
Osteomalacia
Lipid-lowering medications: Statins
Hyperlipidemia
Blood brain barrier
Cerebrospinal fluid
Guillain-Barre syndrome
Raynaud phenomenon
Myasthenia gravis
Muscular dystrophy
Subarachnoid hemorrhage
Diabetic retinopathy
Hypopituitarism
Hyperpituitarism
Kallmann syndrome
Phosphate, calcium and magnesium homeostasis
Parathyroid hormone
Calcitonin
Vitamin D
Hypercalcemia
Hypocalcemia
Hyperparathyroidism
Hypothyroidism
Hyperthyroidism
Cushing syndrome

Flashcards

Resting membrane potential

0 of 7 complete

Transcript

Watch video only

Content Reviewers

Each cell in the human body is wrapped in a membrane that separates the inner environment and outer environment, and positively and negatively charged ions aren’t equally distributed on both sides of the membrane.

Fundamentally, it’s these differences in concentration and charge as well as permeability across the membrane that establishes the cell’s resting membrane potential.

Generally speaking there is a higher concentration of Na+ or sodium, Cl- or chloride, and Ca2+ or calcium on the outside of a cell, and a higher concentration of (K+) or potassium and (A-), which is just what we just write for negatively charged anions, on the inside of a cell.

These anions include a variety of amino acids and proteins that are produced by the cell.

Let’s start with the sodium-potassium pump which uses ATP to move three sodium ions out of the cell for every 2 potassium ions that it moves into the cell, this is the workhorse of the cell and it helps establish the concentration gradient for potassium and sodium.

Let’s focus on potassium, which has a concentration of 150 mMol/L on the inside of the cell and about 5 mMol/L on the outside of the cell.

With so much potassium within the cell relative to outside the cell, there will be fairly strong concentration gradient moving potassium ions out of the cell.

Although these ions can’t simply diffuse through the phospholipid bilayer membrane, it turns out that potassium can get across the membrane using potassium leak channels and inward rectifier channels that are scattered throughout the membrane.

So using those channels, the concentration gradient pushes potassium out of the cell, and that potassium brings with it some positive charge and leaves behind unpaired anions which carry negative charge because they aren’t able to go through the leak channels.

Over time as more potassium ions leave the cell, a negative charge builds up within the cell and this starts to attract positively charged potassium ions back into the cell, and this is called the electrostatic gradient.

This electrostatic gradient is established with the movement of relatively few ions, so it doesn’t upset the overall concentration gradient that was already established.

For potassium, the exact point when the potassium moving out of the cell due to the concentration gradient equals the potassium moving back into the cell due to the electrostatic gradient is called the equilibrium potential or nernst potential for potassium, and it’s about -92 mV.

In other words, -92 mV is the electric potential for attracting potassium into the cell that is needed to balance the concentration gradient that is pushing potassium out of the cell.

So the equilibrium potential of an ion is dependent on two things: the concentration gradient for the ion and the cell being permeable to that ion.

If we’re only dealing with a single ion, then the equilibrium potential for the ion equals the resting membrane potential for the cell.

Key Takeaways

The resting membrane potential (RMP) is the electrical potential difference across the plasma membrane of a cell when the cell is at rest and not undergoing any significant electrical activity. This potential difference is created by the unequal distribution of ions across the membrane, with positively charged ions (such as sodium and calcium) being more concentrated outside the cell and negatively charged ions (such as chloride and potassium) being more concentrated inside the cell.

Each ion has its own equilibrium potential, which is determined by the Nernst equation. It states that an ion's resting membrane potential (Vm) equals 61.5 times the log of the concentration of the ion outside the cell, divided by the concentration of the ion inside the cell, for an ion with a single charge like sodium, and Vm equals 30.75 times the log the concentration of the ion outside divided by the concentration of the ion inside for an ion with a double charge like calcium.

Vm = 61.5Log [ION]out[ION]in for single charged ions (E.g. Na+) Vm = 30.75Log [ION]out[ION]in for double charged ions (E.g. Ca2+) The cell's resting membrane potential will therefore be the summation of each individual ion's equilibrium potential.