I ran into something at the bedside that didn’t make sense at first.

We had a patient on higher ECMO flows, and the pressure drop across the oxygenator (delta P) was elevated but appropriate for the settings we were running. About a week later, we had weaned the flow down, and the delta P dropped.

Looking at the numbers, it looked like an improvement.

But the oxygenator didn’t look better. If anything, it looked worse, fibrin on the faceplate, thrombus starting to show in the corners.

That created a mismatch I couldn’t ignore. The circuit looked worse, but the number looked better.

The Problem With Delta P Alone

I was taught that delta P is tied to flow. If you increase flow, the delta P increases. If you decrease the flow, delta P decreases.

So when we lowered the flow, the drop in delta P didn’t necessarily mean the oxygenator improved. It just meant we were asking less of it.

The Question We Always Ask

When delta P starts to rise, experienced ECMO specialists usually ask:

• “Is the flow the same?”

That’s the right question. Because if flow increases, a higher delta P may mean nothing at all. But here’s the problem: most of the time, that’s where the conversation ends. We acknowledge that flow matters, but we don’t have a simple way to account for it at the bedside.

So we’re left guessing:

• Was the change in delta P expected because of the change in ECMO flow?

• Or is the circuit actually getting worse?

Adding One Simple Layer

Out of curiosity, I started looking at delta P relative to flow:

• delta P ÷ ECMO flow = mmHg/LPM

At the start, this value was around 6 mmHg/LPM. About a week later, even though delta P had decreased, that number had risen to around 10 mmHg/LPM.

That changed the picture.

The circuit now required more pressure per unit of flow than before. And that matched what I was seeing.

What That Suggests

As an oxygenator develops clot or fibrin buildup, blood flow becomes less efficient. Pathways narrow, resistance increases, and more pressure is needed to move the same amount of blood.

If flow is decreased at the same time, that increase in resistance can be hidden. The raw delta P looks better, but the underlying problem may still be progressing.

Keep It in Perspective

This isn’t a perfect measurement. Hematocrit, temperature, and viscosity all affect the delta P.

And it doesn’t replace what we already watch: gas exchange, hemolysis, or visual inspection of the circuit.

But it adds one useful question:

• Is the circuit requiring more pressure than it used to for the same flow?

Bedside Takeaway

A lower delta P doesn’t always mean a better oxygenator, especially if flow has changed.

Sometimes you have to look one step deeper.

Learn more

For more practical ECMO articles and study tools, visit ECMO 143: AI-Assisted Journey.

I also built AI ECMO Educator, a free-to-use tool that provides evidence-based ECMO and ECPR guidance for ICU clinicians and trainees, covering physiology, cannulation, anticoagulation, circuit management, and troubleshooting. It draws from sources such as ELSO, PubMed, AmSECT, and leading centers.

Disclaimer

This content is for educational purposes only and does not replace clinical judgment, institutional protocols, or consultation with your ECMO team.