Abstract: A multi-arm, star-shaped polymer composition can be configured for drug delivery and imaging applications in vivo. The star polymer architecture can be synthesized using living radical polymerization techniques, including reversible addition-fragmentation chain transfer and macromolecular design via the interchange of xanthates with a broad range of reaction conditions and functional groups. The star-shaped polymeric carriers can be tailored for preferential delivery of chemotherapeutics into the tumor-draining lymphatics via subcutaneous, peritumoral or intratumoral injections. The carriers can be loaded with the chemotherapeutic agents from about 10% to about 25% w/w. In addition, the carriers can be loaded with imaging agents from about 5% to about 10% w/w. The molecular weights of the polymeric carriers can be about 40 kDa to about 130 kDa. The chemotherapeutics can be cisplatin, geldanamycin or nitric oxide-donating prodrugs. The imaging agent can be a near-infrared dye, such as IR820.

Abstract: A chemotherapeutic composition can be configured for subcutaneous administration for preferential intralymphatic accumulation while also providing a therapeutic systemic concentration that is not toxic. The composition can include a pharmaceutically acceptable carrier, and a nanoconjugate configured for preferential intralymphatic accumulation after subcutaneous administration. The nanoconjugate can include a nanocarrier configured for preferential intralymphatic accumulation after subcutaneous or interstitial administration, and a plurality of chemotherapeutic agents coupled to the nanocarrier. The nanoconjugate can have a dimension of about 10 nm to about 5 nm. Also, the nanoconjugate can be loaded with the chemotherapeutic agents from about 10% to about 50% w/w. The nanocarrier can be a hyaluronan polymer of about 3 kDa to about 50 kDa. Alternatively, the nanocarrier can be a dendrimer.

Abstract: A chemotherapeutic composition can be configured for subcutaneous administration for preferential intralymphatic accumulation while also providing a therapeutic systemic concentration that is not toxic. The composition can include a pharmaceutically acceptable carrier, and a nanoconjugate configured for preferential intralymphatic accumulation after subcutaneous administration. The nanoconjugate can include a nanocarrier configured for preferential intralymphatic accumulation after subcutaneous or interstitial administration, and a plurality of chemotherapeutic agents coupled to the nanocarrier. The nanoconjugate can have a dimension of about 10 nm to about 50 nm. Also, the nanoconjugate can be loaded with the chemotherapeutic agents from about 10% to about 50% w/w. The nanocarrier can be a hyaluronan polymer of about 3 kDa to about 50 kDa. Alternatively, the nanocarrier can be a dendrimer.

Abstract: The invention provides 17 AAG encapsulated in micelle particles. The micelles can be comprised of safe poly(ethylene glycol)-block-poly(lactic acid) (PEG-PLA). A significant advantage of PEG-PLA as a carrier is that it is less toxic than Cremophor® EL or DMSO. Additionally, PEG-PLA micelles are easier to handle than DMSO and they do not possess foul odors, which is a problem associated with 17-AAG formulations currently in clinical trials. The invention also provides methods of preparing active agents encapsulated micelles and therapeutic methods of using the micelles and their corresponding formulations, such as for the inhibition of Hsp 90, and/or for the treatment of cancer.

Abstract: A chemotherapeutic composition can be configured for subcutaneous administration for preferential intralymphatic accumulation while also providing a therapeutic systemic concentration that is not toxic. The composition can include a pharmaceutically acceptable carrier, and a nanoconjugate configured for preferential intralymphatic accumulation after subcutaneous administration. The nanoconjugate can include a nanocarrier configured for preferential intralymphatic accumulation after subcutaneous or interstitial administration, and a plurality of chemotherapeutic agents coupled to the nanocarrier. The nanoconjugate can have a dimension of about 10 nm to about 50 nm. Also, the nanoconjugate can be loaded with the chemotherapeutic agents from about 10% to about 50% w/w. The nanocarrier can be a hyaluronan polymer of about 3 kDa to about 50 kDa. Alternatively, the nanocarrier can be a dendrimer.