Thanks! Good luck on your exam!

Sam Black Thanks so much for pointing that out! It's challenging to keep these videos up to date when medicine keeps changing! On vacation right now, but will try to remember to add a clarifying annotation once I can access the site with something other than a smartphone. Thanks again!

@@StrongMed 11:32

CO2 seems to be the driving factor for O2 extraction from the alveoli ; where the metabolic needs for O2 is estimated via the RQ of the food metabolized , the CO2 produced in blood ; that is eventually released in the alveoli ! But CO2 seems too to determine the amount of O2 extracted by the body tissues from the arterial blood in the same manner ! In case of hypoventilation ; the associated hypercapnia leads to a PROPORTIONATE reduction in both PAO2 & PaO2 as there is a proportionate increase in O2 extraction determined by the CO2 concentration in both the alveoli & the blood ! So a normal A-a gradient is achieved !

Did you finish it bro. It is been 8 years . Time flies

Aa gradient determines how much of all the inspired oxygen reaches the circulation. If elevated= some lung parenchyma issues, which is VQ mismatch, Diffusion issue or Shunt. If normal, then whatever inspired fraction of O2 had no problem getting into the circulation because of a good functioning lung parenchyma. If patient is hypoxic with a normal AA gradient, then primary problem is outside the lung parenchyma causing either reduce ventilation e.g. COPD, OSA, etc

CO2 seems to be the driving factor for O2 extraction from the alveoli ; where the metabolic needs for O2 is estimated via the RQ of the food metabolized , the CO2 produced in blood ; that is eventually released in the alveoli ! But CO2 seems too to determine the amount of O2 extracted by the body tissues from the arterial blood in the same manner ! In case of sepsis ; the tissue hypo perfusion associated with the septic shock results in hypercapnia , hypercapnia leads to a PROPORTIONATE reduction in both PAO2 & PaO2 as there is a proportionate increase in O2 extraction determined by the CO2 concentration in both the alveoli & the blood ! So a normal A-a gradient is achieved ! Lord knows best !

The alveolar membrane permeability to CO2 is nearly 26 times that to O2 ! That's why CO2 in blood & alveoli rapidly equilibrate , without creating a gradient for CO2 , i.e : PA co2 = Pa co2 . The RQ itself refers to a kind of gaseous equilibrium for the alveolar exchange between O2 & CO2 , in which the metabolic needs for O2 is determined by the kind of food metabolized , the estimated CO2 produced in blood & eventually released in the alveoli ! CO2 seems to be the driving factor for O2 extraction from the alveoli ! In case of tachypnea the Pa CO2 is progressively reduced with time without necessarily achieving adequate rise in Pa O2 ! The wide A-a gradient in that dementia patient reflects an impaired gas diffusion that affects O2 more than CO2 due to the difference in alveolar permeability between the 2 gases ! A chest X - ray should also be considered in that dementia patient to rule out any possible aspiration pneumonia !

In common usage the terms hyperventilation and hypoventilation usually refer to how fast someone is breathing (i.e. how many breaths per minute), but they mean something more specific in medicine. CO2 levels are dependent upon something called alveolar ventilation, which you can think of as how much "fresh air" the alveoli see each minute. Alveolar ventilation = (Tidal volume - dead space) x respiratory rate. Tidal volume is the volume of air in each breath, and dead space is the volume of the lungs which is not participating in gas exchange because it's either in airways not lined by capillaries, or because it's in alveoli that aren't receiving good blood flow. In COPD, particularly during acute exacerbations, patients have low tidal volumes and may have increased dead space. So the value of (tidal volume - dead space) becomes much smaller than normal. So even if the respiratory rate is higher than normal, the overall alveolar ventilation may still be low, leading to high CO2 levels in the arteries.

In other words : In COPD , the chronic reduction in Tv outweighs the acute increase in RR during exacerbations ! [ Low minute ventilation = Very very low tidal volume X High respiratory rate ] ! In summary the PAo2 value is the driving factor for the PaO2 value !

Remember that in shunt, there is and increase in perfusion and a decrease in ventilation. Where there is ventilation, but no perfusion; you don't get gas exchange. What does this look like? For instance, you have a patient breathing 50% oxygen at sea level. ABGs show PaO2 of 50 and PCO2 of 50. SpO2 is 98% After some calculation, the patient's PAO2 is 294. Thus, giving you an estimated 244mmHg Aa gradient. How do we interpret this? Well we see that SpO2 is unaffected; yet our ABGs are abnormal. (recall that shunt will not respond to 100% O2) Ahhh there must be a ventilation issue. This is essentially this definition of shunt.

Thank you Jawan, however I do understand the definition and the mathematical formula by which the Aa gradient rises, it is the theory behind it which bothers me, in simple terms the Aa gradient represents difference in Alveolar and arterial oxygenation, the thing I'm asking is why in the presence of hypoxemia AND low alveolar ventilation the Aa gradient rises if both values go down the difference shouldn't rise, but remain the same. To make myself clear let's make a ridiculous example, imagine if there was a 0mmHg pressure of oxygen in both the alveoli and the arteries, we, in this case agree that there is hypoxemia and low ventilation, if in this case the perfusion remained constant it would be a case of Shunt, and the Aa gradient should go up, in fact if you calculate by the formula, it may very well go up, because the Alveolar Pressure is calculated not directly but by some other variables like CO2.... But then again, remember the terms I state at the beginning, a pressure of 0 in both the arteries and the alveoli, if the Aa gradient would really be just a difference between these two measures the difference between a completely hypoxemic artery and a completely hypoxemic alveoli (by shunt) would not be elevated, would be in fact 0

Dude a shunt isn´t "ventilation, but not perfusion" thats and example of blood obstruction with an "infinite"V/Q mismatch since you have a number divided by cero; the best example could be an pulmonary embolism. And as you said, this condition its partially improved by O2

A-a increases because in your V/Q equation the ventilation (V) will be cero (ei: tumor obstruccion). You must remember that in lung when its a low 02 pressure, there is a vasoconstriction to allow blood goes to better oxygenated alveoli. So there you will have that in those alveoli there wont exist difussion and increasing A-a gradient

Alejandro López ok so in case the alveolus pAO2 is 0 and the paO2 is 50----> A-a gradient is 0 - 50??

I'm very sorry, the PPTs that accompanied these videos were 3 hard drives ago. I'm no longer able to locate them.

Pack years = Years smoked x avg packs/day. So if a person starts smoking at 26, and averages 2 packs per day for the next 30 years, they'll end up with 60 pack years by the age of 56. (It's not a common term to hear outside of medicine)

@@StrongMed That's something that got me on several questions--thanks for the answer!