"Sweet tooth"-oriented SN38 prodrug delivery nanoplatform for targeted gastric cancer therapy.

Most cancer cells employ overexpression of glucose transports (GLUTs) to satisfy glucose demand ("Sweet Tooth") for increased aerobic glycolysis rates. GLUT1, one of the most widely expressed GLUTs in numerous cancers, was identified as a prognosis-related biomarker of gastric cancer via tissue array analysis. Herein, a "Sweet Tooth"-oriented SN38 prodrug delivery nanoplatform (Glu-SNP) was developed for targeted gastric cancer therapy. For this purpose, a SN38-derived prodrug (PLA-SN38) was synthesized by tethering 7-ethyl-10-hydroxycamptothecin (SN38) to biocompatible polylactic acid (PLA) with the appropriate degree of polymerization (n = 44). The PLA-SN38 conjugate was further assembled with glycosylated amphiphilic lipid to obtain glucosamine-decorated nanoparticles (Glu-SNP). Glu-SNP exhibited potent antitumor efficiency both in vitro and in vivo through enhanced cancer cell-specific targeting associated with the overexpression of GLUT1, which provides a promising approach for gastric cancer therapy.

A PEGylated alternating copolymeric prodrug of sulfur dioxide with glutathione responsiveness for Irinotecan delivery.

In this study, an enhanced anticancer strategy combining the chemotherapy from antineoplastics with the oxidative damage from a sulfur dioxide (SO2) prodrug is presented. Based on the characteristics of a high glutathione (GSH) level in the tumor microenvironment, a novel GSH-responsive SO2 polymeric prodrug mPEG-b-P(PA-alt-GDNs) was designed and synthesized via a ring-opening alternating copolymerization and "click" reaction. The GSH-sensitive mechanism of the polymer was investigated in detail. Furthermore, Irinotecan was loaded into the polymeric prodrug nanoparticles by a self-assembly method with a drug loading content of 12.3 wt% and a loading efficiency of 42.2%. The drug-loaded nanoparticles showed a sensitive response to high concentrations of GSH in the tumor cells and rapidly released both Irinotecan and SO2. The depletion of GSH and the release of SO2 were supposed to increase the level of reactive oxygen species in the tumor cell, which, in combination with the released Irinotecan, exerted an enhanced anti-proliferative effect against HepG2 cells. Finally, Irinotecan-loaded nanoparticles exhibited a stronger antitumor effect than free antineoplastics in HepG2 cells. Thus, these results indicated that our polymeric prodrug SO2 is a promising candidate for chemotherapeutic drug delivery and would be a new weapon in anticancer treatment.

Design, Synthesis, and Biological Evaluation of HSP90 Inhibitor-SN38 Conjugates for Targeted Drug Accumulation.

Herein, a series of HSP90 inhibitor-SN38 conjugates through ester and carbamate linkage in the 20-OH and 10-OH positions of SN38 were developed for improving the tumor-specific penetration and accumulation of SN38 via extracellular HSP90 (eHSP90)-mediated endocytosis. Mechanistic analyses confirmed that these novel conjugates could bind to eHSP90 and be selectively internalized into the tumor cells, which led to prolonged tumor regression in multiple models of cancer. Among all studied conjugates, compound 18b showed excellent in vitro activities, including acceptable HSP90α affinity and potent antitumor activity. Moreover, compound 18b exhibited superior antitumor activity and low toxicity in HCT116 and Capan-1 xenograft models. Pharmacokinetic analyses in HCT116 and Capan-1 xenografts further confirmed that compound 18b treatment could lead to effective cleavage and extended SN38 exposure at tumor sites. All these encouraging data indicate that this compound is a promising new candidate for cancer therapy and merits further chemical and biological evaluation.

Design, synthesis and antitumor activity of a novel PEG-A6-conjugated irinotecan derivative.

A novel PEG-A6-conjugated irinotecan derivative 8 was designed and synthesized as antitumor agent by the PEGylation and A6-peptide modification of irinotecan. In vivo antitumor activity screening assay revealed that 8 exhibited better in vivo antiproliferation activity than irinotecan and its previous PEG-cRGD-conjugated derivative BGC0222 in MIA PaCa-2, NCI-H446, MDA-MB-231, HT-29 and NCI-N87 xenograft models, while the tumor of one in six mice in NCI-H446 assay and the tumors of two in six mice in MIA PaCa-2 assay completely subsided and disappeared within the 21-day period of 8-treatment, indicating that 8 should be a potential antitumor agent.

Preparation and Evaluation of Irinotecan Poly(Lactic-co-Glycolic Acid) Nanoparticles for Enhanced Anti-tumor Therapy.

Irinotecan (IRT), the pro-drug of SN-38, has exhibited potent cytotoxicity against various tumors. In order to enhance the anti-tumor effect of IRT, we prepared IRT-loaded PLGA nanoparticles (IRT-PLGA-NPs) by emulsion-solvent evaporation method. Firstly, IRT-PLGA-NPs were characterized through drug loading (DL), entrapment efficiency (EE), particle size, zeta potential, transmission electron microscopy (TEM), and differential scanning calorimetry (DSC). We next studied the in vitro release characteristics of IRT-PLGA-NPs. Finally, the pharmacokinetics and pharmacodynamics profiles of IRT-PLGA-NPs were investigated. The results revealed that IRT-PLGA-NPs were spherical with an average size of (169.97 ± 6.29) nm and its EE and DL were (52.22 ± 2.41)% and (4.75 ± 0.22)%, respectively. IRT-PLGA-NPs could continuously release drug for 14 days in vitro. In pharmacokinetics studies, for pro-drug IRT, the t1/2ß of IRT-PLGA-NPs was extended from 0.483 to 3.327 h compared with irinotecan solution (IRT-Sol), and for its active metabolite SN-38, the t1/2ß was extended from 1.889 to 4.811 h, which indicated that IRT-PLGA-NPs could prolong the retention times of both IRT and SN-38. The pharmacodynamics results revealed that the tumor doubling time, growth inhibition rate, and specific growth rate of IRT-PLGA-NPs were 2.13-, 1.30-, and 0.47-fold those of IRT-Sol, respectively, which demonstrated that IRT-PLGA-NPs could significantly inhibit the growth of tumor. In summary, IRT-PLGA-NPs, which exhibited excellent therapeutic effect against tumors, might be used as a potential carrier for tumor treatment in clinic.

Hydrophobized SN38 to redox-hypersensitive nanorods for cancer therapy.

The clinical application of SN38 (7-ethyl-10-hydroxy-camptothecin) is severely restricted by its extremely low water solubility. Nanoaggregates formed by amphiphilic SN38 prodrugs have been widely used for the delivery of SN38. In this study, we used a hydrophobized SN38 prodrug, rather than a typical SN38 amphiphile, to construct rod-shaped nanoaggregates for efficient SN38 delivery. The hydrophobized SN38 was synthesized by conjugating SN38 with oleic acid using disulfanyl-ethyl carbonate as the linker. Interestingly, the resulting prodrug self-assembled into nanorods with high drug loading capacity (45%) and colloidal stability. Moreover, these nanorods displayed an impressively high redox-sensitivity to release 100% SN38 within 1 h in 10 mM DTT, versus 1% in phosphate buffer (pH 7.4). The efficient drug release resulted in an uncompromised in vitro cytotoxicity, which was comparable to free SN38 and nearly 93-fold more potent than CPT-11. Most importantly, these novel prodrug nanoaggregates exhibited potent antitumor activity in the CT26 colorectal cancer xenograft. The nanoaggregates of such redox-hypersensitive hydrophobized SN38 represent an effective alternative strategy for developing novel SN38 nanomedicines.