IV Catheter Physics & Clinical Complications

What happens
after you insert.

Four interactive modules on the forces, failures, and physics that govern what moves through your peripheral IV catheter — and what goes wrong when they go wrong. From pressure gradients to barotrauma, from reflux to medication surges.

← Vol. I: The Vascular Lab ← Vol. II: The Ultrasound Lab
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Reflux
Blood flowing backward into catheter and tubing when pressure gradients reverse
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Blood Draw
Drawing samples through existing IV catheters — hemolysis, deadspace, technique
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Med Surge
Concentration spikes when bolus medications flush through deadspace into circulation
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Barotrauma
Pressure-induced tissue injury from infiltration, extravasation, and compartment pressure
ΔP = P_venous − P_IV
Reflux Threshold
Q = πr⁴ΔP / 8ηL
Draw Rate (Poiseuille)
τ = 4ηQ / πr³
Hemolysis Shear Stress
C_surge = C_drug × V_dead / V_flush
Surge Concentration
P_comp = F / A
Compartment Pressure
V_inj = P × C / K
Extravasation Volume
Four Modules
01
Catheter Reflux
Pressure Reversal
& Blood Reflux
When venous pressure exceeds IV line pressure, blood flows backward — silently occluding catheters, seeding clots, and creating the conditions for catheter failure. Understand the physics of the gradient that keeps your line patent.
Pressure GradientClot FormationCoughing/Valsalva1950s
Open module
02
Blood Draw
Drawing Through
an Existing IV
Using peripheral IV catheters for blood collection — the hemolysis risk, negative pressure shear stress, gauge limitations, and the discard volume problem. Where Navi fits in the story of needle-free blood collection.
HemolysisShear StressNavi DeviceSample Integrity
Open module
03
Medication Surge
The Deadspace
Bolus Problem
When you flush an IV line, concentrated medication sitting in deadspace reaches the bloodstream as a bolus surge — before dilution. Understand why saline flushes can be as dangerous as the drug itself in critical care.
Deadspace VolumeConcentration SpikeFlush PhysicsICU Safety
Open module
04
Barotrauma
Pressure Injury
& Extravasation
The physics of fluid pressure in soft tissue — infiltration, extravasation, compartment syndrome, and vesicant injury. What pressure thresholds trigger irreversible damage, and how flow rate determines the window between a safe infusion and a surgical emergency.
Compartment PressureVesicantsExtravasation30 mmHg Rule
Open module
Historical Timeline — IV Catheter Medicine
1628
Harvey Describes Circulation
Pressure gradients as the engine of blood movement — the precondition for all IV therapy
1656
First IV Injection (Wren)
Christopher Wren injects opium into a dog's vein using a quill and bladder — first deliberate IV access
1832
Saline IV in Cholera
Thomas Latta uses IV saline in cholera patients — first therapeutic IV infusion in humans
1945
Rochester Needle (Massa)
First plastic-over-needle catheter — enables dwell times beyond a single injection
1950s
Reflux Recognition
Blood reflux into IV tubing identified as cause of catheter occlusion and clot seeding
1960s
Heparin Lock Era
Heparin flushes adopted to prevent reflux clotting — saline-vs-heparin debate continues to present day
1973
Extravasation Literature
First systematic descriptions of chemotherapy extravasation injury — barotrauma formally classified
1985
INS Standards Published
Infusion Nurses Society formalizes pressure limits, flush volumes, catheter gauges — evidence-based IV practice begins
2000s
Needleless Connectors
Positive-displacement connectors reduce reflux without heparin — but create deadspace and surge problems
2024
Navi (Venocare)
FDA 510(k) K244047 — needle-free blood collection via existing peripheral IV catheters
The Unifying Insight
Every catheter complication is a physics problem with a biological consequence.

Reflux is a pressure gradient problem. Hemolysis is a shear stress problem. Medication surge is a fluid dynamics and deadspace problem. Barotrauma is a pressure-area problem. The biology — clots, lysed cells, arrhythmias, tissue necrosis — is just what happens when the physics goes wrong at the wrong place.

Reflux Threshold
ΔP < 0 → blood flows in
Hemolysis Risk
τ > 150 Pa → RBC rupture
Surge Window
V_dead / V_flush × C_drug
Compartment Danger
P > 30 mmHg → ischemia