Two-step synthesis of multivalent cancer-targeting constructs.

Selective targeting of constructs to pathological cells by conjugating one or more ligands for an overexpressed receptor has been proposed to enhance the delivery of therapeutics to and imaging of specific cells of interest. Previous work in our lab has demonstrated the efficacy of targeting glioblastoma cells with a multivalent, biomacromolecular construct targeted to the alpha(6)beta(1)-integrin. However, solid-phase synthesis of this construct was inefficient in terms of cost and number of steps.

Targeted drug delivery for treatment and imaging of glioblastoma multiforme.

Glioblastoma multiforme is a grade IV astrocytic tumor with a very high mortality rate. Although current treatment often includes surgical resection, this rarely removes all primary tumor cells, so is usually followed by radiation and/or chemotherapy. Remaining migratory tumor cells invade surrounding healthy tissue and contribute to secondary and tertiary tumor recurrence; therefore, despite significant research into glioma removal and treatment, prognosis remains poor.

Optimizing delivery of multivalent targeting constructs for detection of secondary tumors.

Targeting drugs or imaging molecules to specific cells by conjugating them to antibodies or ligands for cell surface receptors may allow earlier detection of pathology, better localization for intervention, and fewer side effects. Delivery of these molecules to the target is complicated by construct size, which cannot cross typical endothelial barriers such as the vascular wall, and lack of a priori knowledge of the location of secondary tumor sites to which the construct is targeted. Here we develop mathematical models for diffusive and convection-enhanced delivery of a trivalent construct.

Temporal and spatial control of neural effects following intracerebral microinfusion.

Spatial and temporal control of neural drug delivery is critical for many therapeutic applications and analyses of brain patterns and behavior. Specifically, for localized injections that serve to deliver drug or inactivate an isolated tissue region in order to observe changes in neural activity at that site, excess distribution into surrounding regions may confound analysis or adversely affect healthy tissue. Here, we develop a mass transport model that simulates a short period of initial infusion of inactivating drug, followed by a successive convective wash with artificial cerebrospinal fluid (aCSF), while tracking the regions of tissue that are above a certain threshold concentration of inactivating agent.

Specificity and mobility of biomacromolecular, multivalent constructs for cellular targeting.

Effective targeting of drugs to cells requires that the drug reach the target cell and interact specifically with it. In this study, we synthesized a biomacromolecular, multivalent construct intended to target glioblastoma tumors. The construct was created by linking three dodecapeptides, reported to bind the alpha 6beta1 integrin, with poly(ethylene glycol) linkers.