Melissa D. Howard scite author profile

Targeted nanomedicine holds promise to find clinical use in many medical areas. Endothelial cells that line the luminal surface of blood vessels represent a key target for treatment of inflammation, ischemia, thrombosis, stroke, and other neurological, cardiovascular, pulmonary, and oncological conditions. In other cases, the endothelium is a barrier for tissue penetration or a victim of adverse effects. Several endothelial surface markers including peptidases (e.g., ACE, APP, and APN) and adhesion molecules (e.g., ICAM-1 and PECAM) have been identified as key targets. Binding of nanocarriers to these molecules enables drug targeting and subsequent penetration into or across the endothelium, offering therapeutic effects that are unattainable by their nontargeted counterparts. We analyze diverse aspects of endothelial nanomedicine including (i) circulation and targeting of carriers with diverse geometries, (ii) multivalent interactions of carrier with endothelium, (iii) anchoring to multiple determinants, (iv) accessibility of binding sites and cellular response to their engagement, (v) role of cell phenotype and microenvironment in targeting, (vi) optimization of targeting by lowering carrier avidity, (vii) endocytosis of multivalent carriers via molecules not implicated in internalization of their ligands, and (viii) modulation of cellular uptake and trafficking by selection of specific epitopes on the target determinant, carrier geometry, and hydrodynamic factors. Refinement of these aspects and improving our understanding of vascular biology and pathology is likely to enable the clinical translation of vascular endothelial targeting of nanocarriers.

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PEGylation of Nanocarrier Drug Delivery Systems: State of the Art

Howard¹,

Jay²,

Dziubla³

et al. 2008

j biomed nanotechnol

181

134

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"PEGylation" has become the most widely used method for imparting stealth properties to drug nanocarriers. PEGylation of nanoparticles provides a steric barrier to the adsorption of opsonin proteins due to the neutrality, hydrophilicity, flexibility, and capacity for hydration of the PEG moiety. PEGylation of particle surfaces can be achieved by simple adsorption or through the covalent attachment of PEG to activated functional groups on the surface of the particles. PEG molecules have also been modified to enhance their uptake by specific targets (e.g., tumors) and to achieve the controlled release of entrapped therapeutic agents. Accompanying the prevalence of PEGylation has been the development of a wide variety of characterization techniques and the increasing use of mathematical modeling to guide formulation development. This review summarizes the theories behind PEGylation, PEGylation methodology, the characterization of PEGylated particles, and related mathematical modeling as well as how it can be utilized in the optimization of nanocarrier drug delivery systems. The current successes and failures of PEGylation are evaluated in order to provide a vision for the future of nanocarrier PEGylation and nanomedicine in general.

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Endothelial targeting of liposomes encapsulating SOD/catalase mimetic EUK-134 alleviates acute pulmonary inflammation

Howard

Greineder

Hood

et al. 2014

Journal of Controlled Release

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Production of excessive levels of reactive oxygen species (ROS) in the vascular endothelium is a common pathogenic pathway in many dangerous conditions, including acute lung injury, ischemia-reperfusion, and inflammation. Ineffective delivery of antioxidants to the endothelium limits their utility for management of these conditions. In this study, we devised a novel translational antioxidant intervention targeted to the vascular endothelium using PEG-liposomes loaded with EUK-134 (EUK), a potent superoxide dismutase/catalase mimetic. EUK loaded into antibody-coated liposomes (size 197.8±4.5 nm diameter, PDI 0.179±0.066) exerted partial activity in the intact carrier, while full activity was recovered upon liposome disruption. For targeting we used antibodies (Abs) to platelet-endothelial cell adhesion molecule (PECAM-1). Both streptavidin-biotin and SATA/SMCC conjugation chemistries provided binding of 125-150 Ab molecules per liposome. Ab/EUK/liposomes, but not IgG/EUK/liposomes: i) bound to endothelial cells and inhibited cytokine-induced inflammatory activation in vitro; and, ii) accumulated in lungs after intravascular injection, providing >60% protection against pulmonary edema in endotoxin-challenged mice (vs <6% protection afforded by IgG/liposome/EUK counterpart). Since the design elements of this drug delivery system are already in clinical use (PEG-liposomes, antibodies, SATA/SMCC conjugation), it is an attractive candidate for translational interventions using antioxidant molecules such as EUK and other clinically acceptable drugs.

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Melissa D. Howard

Vascular Targeting of Nanocarriers: Perplexing Aspects of the Seemingly Straightforward Paradigm

PEGylation of Nanocarrier Drug Delivery Systems: State of the Art

Endothelial targeting of liposomes encapsulating SOD/catalase mimetic EUK-134 alleviates acute pulmonary inflammation

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