Size-controlled granular polyphosphate
(PolyP) nanoparticles were
synthesized by precipitation in aqueous solutions containing physiological
concentrations of calcium and magnesium. We demonstrate using dynamic
light scattering (DLS) that the solubility is correlated inversely
with PolyP chain length, with very long chain PolyP (PolyP1000+, more
than 1000 repeating units) normally found in prokaryotes precipitating
much more robustly than shorter chains like those found in human platelet
dense granules (PolyP80, range 76–84 repeating units). It is
believed that the precipitation of PolyP is a reversible process involving
calcium coordination to phosphate monomers in the polymer chain. The
particles are stable in aqueous buffer and albumin suspensions on
time scales roughly equivalent to catastrophic bleeding events. Transmission
electron microscopy images demonstrate that the PolyP nanoparticles
are spherical and uniformly electron dense, with a particle diameter
of 200–250 nm, closely resembling the content of acidocalcisomes.
X-ray elemental analysis further reveals that the P/Ca ratio is 67:32.
The granular nanoparticles also manifest promising procoagulant effects,
as measured by in vitro clotting tests assaying contact
pathway activity.
A large group of functional nanomaterials employed in biomedical applications, including targeted drug delivery, relies on amphiphilic polymers to encapsulate therapeutic payloads via self-assembly processes. Knowledge of the micelle structures will provide critical insights into design of polymeric drug delivery systems. Core-shell micelles composed of linear diblock copolymers poly(ethylene glycol)-b-poly(caprolactone) (PEG-b-PCL), poly(ethylene oxide)-b-poly(lactic acid) (PEG-b-PLA), as well as a heterografted brush consisting of a poly(glycidyl methacrylate) backbone with PEG and PLA branches (PGMA-g-PEG/PLA) were characterized by dynamic light scattering (DLS) and small angle X-ray scattering (SAXS) measurements to gain structural information regarding the particle morphology, core-shell size, and aggregation number. The structural information at this quasi-equilibrium state can also be used as a reference when studying the kinetics of polymer micellization.
Granular platelet-sized polyphosphate nanoparticles (polyP NPs) were encapsulated in sterically stabilized liposomes, forming a potential, targeted procoagulant nanotherapy resembling human platelet dense granules in both structure and functionality. Dynamic light scattering (DLS) measurements reveal that artificial dense granules (ADGs) are colloidally stable and that the granular polyP NPs are encapsulated at high efficiencies. High-resolution scanning transmission electron microscopy (HR-STEM) indicates that the ADGs are monodisperse particles with a 150 nm diameter dense core consisting of P, Ca, and O surrounded by a corrugated 25 nm thick shell containing P, C, and O. Further, the ADGs manifest promising procoagulant activity: Detergent solubilization by Tween 20 or digestion of the lipid envelope by phospholipase C (PLC) allows for ADGs to trigger autoactivation of Factor XII (FXII), the first proteolytic step in the activation of the contact pathway of clotting. Moreover, ADGs' ability to reduce the clotting time of human plasma in the presence of PLC further demonstrate the feasibility to develop ADGs into a potential procoagulant nanomedicine.
Platelet-sized polyphosphate (polyP) was functionalized on the surface of gold nanoparticles (GNPs) via a facile conjugation scheme entailing EDAC (N-(3-(dimethylamino)propyl)-N'-ethylcarbodiimide hydrochloride)-catalyzed phosphoramidation of the terminal phosphate of polyP to cystamine. Subsequent reduction of the disulfide moiety allowed for anchoring to the colloidal surface. The ability of the synthesized polyP-GNPs to initiate the contact pathway of clotting in human pooled normal plasma (PNP) was then assayed by quantifying changes in viscous, mechanical, and optical properties upon coagulation. It is revealed that the polyP-GNPs are markedly superior contact activators compared to molecularly dissolved, platelet-sized polyP (of equivalent polymer chain length). Moreover, the particles' capacity to mobilize Factor XII (FXII) and its coactivating proteins appear to be identical to very-long-chain polyP typically found in bacteria. These data imply that nanolocalization of anionic procoagulants on colloidal surfaces, achieved through covalent anchoring, may yield a robust contact surface with the ability to sufficiently cluster active clotting factors together above their threshold concentrations to cease bleeding. The polyP-GNPs therefore serve as a promising foundation in the development of a nanoparticle hemostat to treat a range of hemorrhagic scenarios.
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