Gold nanorod vaccine for respiratory syncytial virus.

Respiratory syncytial virus (RSV) is a major cause of pneumonia and wheezing in infants and the elderly, but to date there is no licensed vaccine. We developed a gold nanorod construct that displayed the major protective antigen of the virus, the fusion protein (F). Nanorods conjugated to RSV F were formulated as a candidate vaccine preparation by covalent attachment of viral protein using a layer-by-layer approach. In vitro studies using ELISA, electron microscopy and circular dichroism revealed that conformation-dependent epitopes were maintained during conjugation, and transmission electron microscopy studies showed that a dispersed population of particles could be achieved. Human dendritic cells treated with the vaccine induced immune responses in primary human T cells. These results suggest that this vaccine approach may be a potent method for immunizing against viruses such as RSV with surface glycoproteins that are targets for the human immune response.

Proteolytic surface functionalization enhances in vitro magnetic nanoparticle mobility through extracellular matrix.

Steric barriers such as collagen I sharply limit interstitial delivery of macromolecular and nanoparticle (NP) based therapeutic agents. Collagenase-linked superparamagnetic NPs overcame these barriers and moved through in vitro extracellular matrix (ECM) at 90 microm h(-1), a rate similar to invasive cells, under the influence of a magnetic field. NP migration in ECM diminished linearly over 5 days. The collagenase-NP construct overcame two of the most significant barriers to nano- and microscale therapeutics deployment: proteolytic enzyme stability was maintained during a clinically useful time frame by immobilization on the NP surface and degradation of interstitial barriers to tissue biodistribution was enabled by the conjugated microbial protease.

Characterization of superparamagnetic nanoparticle interactions with extracellular matrix in an in vitro system.

Controlled dispersion of therapeutic agents within liquid- and gel-filled cavities represents a barrier to treatment of some cancers and other pathological states. Interstitial delivery is compromised by the poor mobility of macromolecules and larger nanoscale structures. We developed an in vitro system to quantify the suitability of superparamagnetic nanoparticles (SPM NPs) as a site-specific therapeutic vehicle for delivery through fluid- and gel-based systems. SPM NP motion was induced by an external magnetic field. NP migration was modulated by NP concentration and surface coating. 135 nanometer radius PEGylated NPs moved through the extracellular matrix with an average velocity of 1.5 mm h(-1), suitable for some clinical applications. Increasing the SPM NP radius to 400 nm while maintaining the same per NP magnetic susceptibility resulted in a greater than 1,000-fold reduction in magnetic mobility, to less than 0.01 mm h(-1). The critical influence of NP size on gel permeation was also observed in silica-coated 135 nm SPM NPs that aggregated under the experimental conditions. Aggregation played a critical role in determining the behavior of the nanoparticles. SPM NPs allow significant free-solution mobility to specific sites within a cavity and generate sufficient force to penetrate common in vivo gels.