Hypoxia

Last updated: February 23, 2023

Hypoxia

Pulm

Pulm

Respiratory system anatomy and physiology
Anatomy of the lungs and tracheobronchial tree
Anatomic and physiologic dead space
Anatomy clinical correlates: Pleura and lungs
Anatomy clinical correlates: Thoracic wall
Lung volumes and capacities
Alveolar surface tension and surfactant
Airflow, pressure, and resistance
Ventilation
Ventilation-perfusion ratios and V/Q mismatch
Hypoxia
Development of the respiratory system
Alveolar gas equation
Carbon dioxide transport in blood
Oxygen binding capacity and oxygen content
Gas exchange in the lungs, blood and tissues
Oxygen-hemoglobin dissociation curve
Respiratory alkalosis
Pulmonary hypertension
Sleep apnea
Apnea, hypoventilation and pulmonary hypertension: Pathology review
Restrictive lung diseases
Restrictive lung diseases: Pathology review
Pleural effusion
Pleural effusion: Clinical
Pneumothorax
Pneumothorax: Clinical
Pleural effusion, pneumothorax, hemothorax and atelectasis: Pathology review
Cystic fibrosis
Cystic fibrosis: Pathology review
Cystic fibrosis: Clinical
Lung cancer
Mesothelioma
Lung cancer and mesothelioma: Pathology review
Lung cancer: Clinical
Asthma
Asthma: Clinical
Obstructive lung diseases: Pathology review
Chronic obstructive pulmonary disease (COPD): Clinical
Emphysema
Chronic bronchitis
Pneumonia
Pneumonia: Pathology review
Pneumonia: Clinical
Bronchodilators: Leukotriene antagonists and methylxanthines
Bronchodilators: Beta 2-agonists and muscarinic antagonists
Diffuse parenchymal lung disease: Clinical
Bronchiectasis
Sarcoidosis
Idiopathic pulmonary fibrosis
Acute respiratory distress syndrome
Pulmonary embolism
Pulmonary edema
Superior vena cava syndrome
Pulmonary corticosteroids and mast cell inhibitors
Zones of pulmonary blood flow
Venous thromboembolism: Clinical
Deep vein thrombosis and pulmonary embolism: Pathology review
Tuberculosis: Pathology review
Acute respiratory distress syndrome
Acute respiratory distress syndrome: Clinical
Respiratory distress syndrome: Pathology review
Upper respiratory tract infection
Cor pulmonale
Metabolic and respiratory alkalosis: Clinical
Respiratory alkalosis
Respiratory acidosis
Upper respiratory tract infection
Metabolic and respiratory acidosis: Clinical

Transcript

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So by this point, you’re probably aware that your body needs oxygen to survive, right?

In fact, every cell in your body needs that precious oxygen.

Those cells use the oxygen to produce energy in the form of ATP, or adenosine triphosphate, a super super important molecule, sometimes even called “the molecular unit of currency”.

The cells use it to basically pay the molecules inside the cell to do their specific jobs.

It’s like one big factory with a bunch of workers that all have specific jobs needed to run the factory, and they only take ATP as payment.

Now the mitochondrion of the cell takes in oxygen and makes ATP to pay the workers, through a process called oxidative phosphorylation, the mitochondrion’s like the factory’s payroll department, right?

When the cell doesn’t get enough oxygen, and so payroll can’t produce the ATP that they need to pay the workers to do their jobs, the whole cellular factory can be damaged or even die, and we call that process hypoxia, where hypo means “less than normal” and oxia means “oxygenation”.

When the oxygen comes in, typically it goes straight to payroll, specifically to the inner mitochondrial membrane where oxidative phosphorylation takes place.

Oxygen’s used in one of the last steps, and serves as an electron acceptor, and this allows the process to finish and produce ATP.

So without oxygen, we can’t finish oxidative phosphorylation and produce ATP.

But why does the whole factory fall apart when payroll stops making ATP? Why don’t they just pause for a bit? Take a little break?

Well, when certain workers stop doing their jobs...things get a little out of hand.

One super important worker is the sodium potassium pump on the cell’s membrane, pretty much like the bouncer that makes sure there isn’t too much sodium diffusing into the cell, basically by pumping it back out every time it diffuses in and maintaining a concentration gradient, this process also keeps too many water molecules from passively diffusing into the cell; think of it like this: water molecules want to go every which way and are constantly moving back and forth, inside and outside the cell, but the all these sodium ions on this side tend to physically block more of them from leaving that side, so over time more water molecules get retained, or almost trapped, on the side with more sodium—in short, the more sodium molecules: the more water molecules.

But, our pump doesn’t do all this for free, and it needs ATP.

So without ATP, it stops pumping sodium back out, and sodium diffuses in...and keeps diffusing in and the concentration gradient goes away, now with less sodium particles on the outside blocking the water molecules from going into the cell, water follows sodium in, which causes the cell to swell up.

When the cell swells up, a couple things happen.

First, usually you have these really tiny microvilli on the cell’s membrane, which look sort of like little fingers that help increase the cell’s surface area and therefore help the cell absorb more things, when the cell swells up and gets all bloated, the water sort of fills these little fingers and reduces the surface area, which makes it harder to absorb molecules since there’s less surface area, right?

Also, sort of along the same lines, the cell can bleb, or bulge outward from all this water, this is a sign that the cell’s cytoskeleton or this structural framework is beginning to fail, and is letting water slip through.

Sources

  1. "Harrison's Principles of Internal Medicine, Twentieth Edition (Vol.1 & Vol.2)" McGraw-Hill Education / Medical (2018)
  2. "CURRENT Medical Diagnosis and Treatment 2020" McGraw-Hill Education / Medical (2019)
  3. "Yen & Jaffe's Reproductive Endocrinology E-Book" Elsevier Health Sciences (2017)
  4. "Bates' Guide to Physical Examination and History Taking" LWW (2016)
  5. "Robbins Basic Pathology" Elsevier (2017)
  6. "The laws of combination of haemoglobin with carbon monoxide and oxygen" The Journal of Physiology (1912)
  7. "Cellular Stress Responses: Cell Survival and Cell Death" International Journal of Cell Biology (2010)
  8. "Oxygen enrichment of room air to relieve the hypoxia of high altitude" Respiration Physiology (1995)