The nanoscale plasma protein interaction with intravenously injected particulate carrier systems is known to modulate their organ distribution and clearance from the bloodstream. However, the role of this plasma protein interaction in prescribing the adhesion of carriers to the vascular wall remains relatively unknown. Here, we show that the adhesion of vascular-targeted poly(lactide-co-glycolic-acid) (PLGA) spheres to endothelial cells is significantly inhibited in human blood flow, with up to 90% reduction in adhesion observed relative to adhesion in simple buffer flow, depending on the particle size and the magnitude and pattern of blood flow. This reduced PLGA adhesion in blood flow is linked to the adsorption of certain high molecular weight plasma proteins on PLGA and is donor specific, where large reductions in particle adhesion in blood flow (>80% relative to buffer) is seen with ∼60% of unique donor bloods while others exhibit moderate to no reductions. The depletion of high molecular weight immunoglobulins from plasma is shown to successfully restore PLGA vascular wall adhesion. The observed plasma protein effect on PLGA is likely due to material characteristics since the effect is not replicated with polystyrene or silica spheres. These particles effectively adhere to the endothelium at a higher level in blood over buffer flow. Overall, understanding how distinct plasma proteins modulate the vascular wall interaction of vascular-targeted carriers of different material characteristics would allow for the design of highly functional delivery vehicles for the treatment of many serious human diseases.
The blood vessel wall plays a prominent role in the development of many life-threatening diseases and as such is an attractive target for treatment. To target diseased tissue, particulate drug carriers often have their surfaces modified with antibodies or epitopes specific to vascular wall-expressed molecules, along with poly(ethylene glycol) (PEG) to improve carrier blood circulation time. However, little is known about the effect of poly(ethylene glycol) on carrier adhesion dynamics-specifically in blood flow. Here we examine the influence of different molecular weight PEG spacers on particle adhesion in blood flow. Anti-ICAM-1 or Sialyl Lewis(a) were grafted onto polystyrene 2 μm and 500 nm spheres via PEG spacers and perfused in blood over activated endothelial cells at physiological shear conditions. PEG spacers were shown to improve, reduce, or have no effect on the binding density of targeted-carriers depending on the PEG surface conformation, shear rate, and targeting moiety.
Drug carriers have been widely explored
as a method of improving
the efficacy of therapeutic drugs for a variety of diseases, including
those involving inflammation. However, few of these formulations have
advanced past clinical trials. There are still major gaps in our understanding
of how drug carriers impact leukocytes, particularly in inflammatory
conditions. In this work, we investigated how targeted and nontargeted
drug carriers affect the function of leukocytes in blood flow. We
explored three primary mechanisms: (1) collisions in blood flow disrupt
leukocyte adhesion, (2) specific binding to the endothelium competes
with leukocytes for binding sites, and (3) particle phagocytosis alters
leukocyte phenotype, resulting in reduced adhesion. We find that each
of these mechanisms contributes to significantly reduced leukocyte
adhesion to an inflamed endothelium, and that particle phagocytosis
may be the most significant driver of this effect. These results are
crucial for understanding the totality of the impact of drug carriers
on leukocyte behavior and response to inflammation and should inform
the future design of any such drug carriers.
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