Interactions of stealth conjugated polymer nanoparticles with human whole blood.

Photoluminescent conjugated polymeric nanoparticles (CPNs) exhibit favourable properties as fluorescent probes due to their brightness, high photostability, tunable emission spectra and ease of surface modification. Potential cellular and clinical applications of these new diagnostic agents are easily envisioned, providing a rationale to study CPN biocompatibility. Here, stealth formulations of poly phenylene vinylene (PPV) and poly phenylene ethinylene (PPE) were manufactured and their interactions with human blood components assessed. CPNs were colloidally stable in isotonic fluids, but showed photoluminescence quenching in whole blood and plasma at levels as low as 10% supplementation. At concentrations >150 µg mL-1, stealth CPNs caused ∼10% erythrocyte haemolysis, which was likely due to unbound pegylated surfactant present in the formulation. Incubation of CPNs with both whole blood and isolated platelets showed no platelet activation, increases in platelet-monocyte aggregates or induction of platelet aggregation. Interestingly, PPE-CPN formulations inhibited adenosine diphosphate (ADP)-induced platelet aggregation in a dose-dependent manner, while PPV-CPNs did not show this effect. In conclusion, stealth CPN formulations exhibiting neutrally charged, pegylated surfaces do not stimulate platelet activation or aggregation, but may induce a low degree of haemolysis in the presence of free surfactant and can inhibit physiological mediators of platelet aggregation, such as ADP.

Gd-containing conjugated polymer nanoparticles: bimodal nanoparticles for fluorescence and MRI imaging.

Aqueous bifunctional semiconductor polymer nanoparticles (SPNs), approximately 30 nm in diameter (as measured from electron microscopy), were synthesised using hydrophobic conjugated polymers, amphiphilic phospholipids and a gadolinium-containing lipid. Their fluorescence quantum yields and extinction coefficients were determined, and their MRI T1-weighted relaxation times in water were measured. The bimodal nanoparticles were readily taken up by HeLa and murine macrophage-like J774 cells as demonstrated by confocal laser scanning microscopy, and were found to be MRI-active, generating a linear relationship between T1-weighted relaxation rates and gadolinium concentrations The synthesis is relatively simple, and can easily result in milligrams of materials, although we fully expect scale-up to the gram level to be easily realised.