Multibarrier-penetrating drug delivery systems for deep tumor therapy based on synergistic penetration strategy.

Nanotherapies, valued for their high efficacy and low toxicity, frequently serve as antitumor treatments, but do not readily penetrate deep into tumor tissues and cells. Here we developed an improved tumor-penetrating peptide (TPP)-based drug delivery system. Briefly, the established TPP iNGR was modified to generate a linear NGR peptide capable of transporting nanotherapeutic drugs into tumors through a CendR pathway-dependent, neuropilin-1 receptor-mediated process. Although TPPs have been reported to reach intended tumor targets, they often fail to penetrate cell membranes to deliver tumoricidal drugs to intracellular targets. We addressed this issue by harnessing cell penetrating peptide technology to develop a liposome-based multibarrier-penetrating delivery system (mbPDS) with improved synergistic drug penetration into deep tumor tissues and cells. The system incorporated doxorubicin-loaded liposomes coated with nona-arginine (R9) CPP and cyclic iNGR (CRNGRGPDC) molecules, yielding Lip-mbPDS. Lip-mbPDS tumor-targeting, tumor cell/tissue-penetrating and antitumor capabilities were assessed using CD13-positive human fibrosarcoma-derived cell (HT1080)-based in vitro and in vivo tumor models. Lip-mbPDS evaluation included three-dimensional layer-by-layer confocal laser scanning microscopy, cell internalization/toxicity assays, three-dimensional tumor spheroid-based penetration assays and antitumor efficacy assays conducted in an animal model. Lip-mbPDS provided enhanced synergistic drug penetration of multiple biointerfaces for potentially deep tumor therapeutic outcomes.

[Comparative study on pharmacokinetics of gentiopicroside and gentianae radix extract in rats].

OBJECTIVE: To compare the pharmacokinetics of gentiopicroside and Gentianae Radix extract in rats and assess the effect of other components in Gentianae Radix on the pharmacokinetics of gentiopicroside. METHODS: The rats were oral administrated with gentiopicroside and Gentianae Radix extract, the content of geritiopicroside was chosen as index and determined by HPLC. The pharmacokinetic parameters were calculated with DAS 2.1.1 program. RESULTS: The concentration-time curve of gentiopicroside and Gentianae Radix extract was described by two compartment model. The main pharmacokinetic parameters of gentiopicroside and Gentianae Radix extract were: C(max) (16.53 +/- 0.37) g/mL and (16.61 +/- 0.49) g/mL, T(max) 0.25 h and 1.5 h, t1/2(alpha) (0.20 +/- 0.04) h and (0.69 +/- 0. 14) h, t /2 (beta) (0.64 +/- 0.08) hand (0.80 +/- 0.11) h, AUC(0-infinity) (18.20 +/- 1.97) g x h/mL and (39.20 +/- 1.18) g x h/mL, CL( 2.75 +/- 0.32) L/(h x kg) and (1.22 +/- 0.04) L (h x kg), respectively. CONCLUSION: There are significantly differences in pharmacokinetic parameters between gentiopicroside and Gentianae Radix extract in rats.

"Felodipine-indomethacin" co-amorphous supersaturating drug delivery systems: "Spring-parachute" process, stability, in vivo bioavailability, and underlying molecular mechanisms.

Amorphous solid dispersions (ASD) are one of most commonly used supersaturating drug delivery systems (SDDS) to formulate insoluble active pharmaceutical ingredients. However, the development of polymer-guided stabilization of ASD systems faces many obstacles. To overcome these shortcomings, co-amorphous supersaturable formulations have emerged as an alternative formulation strategy for poorly soluble compounds. Noteworthily, current researches around co-amorphous system (CAS) are mostly focused on preparation and characterization of these systems, but more detailed investigations of their supersaturation ("spring-parachute" process), stability, in vivo bioavailability and molecular mechanisms are inadequate and need to be clarified. In present study, we chose pharmacological relevant BCS II drugs to fabricate and characterize "felodipine-indomethacin" CAS. To enrich the current inadequate but key knowledge on CAS studies, we carried out following highlighted investigations including dissolution/solubility, semi-continuous "spring-parachute" process, long-term stability profile of amorphous state, in vivo bioavailability and underlying molecular mechanisms (molecular interaction, molecular miscibility and crystallization inhibition). Generally, the research provides some key information in the field of current "drug-drug" CAS supersaturable formulations.