Enhanced oral bioavailability and antitumor therapeutic efficacy of sorafenib administered in core-shell protein nanoparticle.

Orally delivered molecularly targeted small-molecule drugs play a significant role in managing cancer as a chronic disease. However, due to the poor oral bioavailability of some of these molecules, high-dose administration is required leading to dose-limiting toxicity especially when delivered daily for a long duration. Here, we report an oral nanoformulation for small-molecule multi-kinase inhibitor, sorafenib tosylate, showing nearly two fold enhancement in the oral bioavailability and enhanced therapeutic efficacy with a better safety profile compared to the current clinical formulation. Using a scalable process involving high-pressure homogenization, sorafenib was loaded into an albumin nanocarrier at ~ 50 w/w%. Repeated preparation of gram-scale batches (n = 7) showed an average particle size of 180 ± 9 nm, encapsulation efficiency of 95 [Formula: see text] 2%, and drug-loading efficiency of 48 [Formula: see text] 0.7%. Further, surface engineering with a mucoadhesive layer on nanoparticles (referred to as ABSORF) resulted in the final size of 299 ± 38 nm and surface charge of -54 ± 8 mV. Single-dose and multidose pharmacokinetic studies showed two fold enhancement in the plasma concentration of sorafenib compared to current clinically used tablets. Antitumor efficacy studies in the orthotopic rat liver tumor model showed significant tumor regression (p value = 0.0037) even at half dose (eqv. to 200 mg of human equivalent dose) of ABSORF compared to clinical control (eqv. to 400 mg). The biodistribution of sorafenib from ABSORF was higher in the liver; however, liver and kidney function test parameters were comparable with that of the 2 × dose of clinical control. No abnormalities and signs of toxicity were seen in the histopathological analysis for ABSORF-treated animals. In summary, we demonstrate a scalable preparation of small-molecule drug-loaded nanoformulation with approximately two fold enhancement in oral bioavailability, improved antitumor efficacy, and acceptable toxicity profile.

A magainin-2 like bacteriocin BpSl14 with anticancer action from fish gut Bacillus safensis SDG14.

Bacteriocins are gaining utmost importance in antimicrobial and chemotherapy due to their diverse structure and activity. This study centres on magainin-2 like bacteriocin with anticancer action, produced by Bacillus safensis strain SDG14 isolated from gut of marine fish Sardinella longiceps. The purified bacteriocin designated as BpSl14 was thermostable and pH tolerant. The molecular weight of BpS114 was estimated to be 6061.2 Da using MALDI-ToF MS. The partial primary sequence was elucidated by peptide mass fingerprinting using MALDI MS/MS. The tertiary structure of the partial sequence was similar to that of two magainin-2 α-helices joined together by extended indolicidin. The BpSl14 protein inhibited the cells of lung carcinoma, one of the deadliest cancers. Docking studies conducted with DR5 and TGF-ß, two of the most prominent apoptotic receptors in adenocarcinoma, also proved the anti-apoptotic action of BpSl14.

In vivo evaluation of cetuximab-conjugated poly(γ-glutamic acid)-docetaxel nanomedicines in EGFR-overexpressing gastric cancer xenografts.

Epidermal growth factor receptor (EGFR), upregulated in gastric cancer patients, is an oncogene of interest in the development of targeted cancer nanomedicines. This study demonstrates in silico modeling of monoclonal antibody cetuximab (CET MAb)-conjugated docetaxel (DOCT)-loaded poly(γ-glutamic acid) (γ-PGA) nanoparticles (Nps) and evaluates the in vitro/in vivo effects on EGFR-overexpressing gastric cancer cells (MKN-28). Nontargeted DOCT-γ-PGA Nps (NT Nps: 110±40 nm) and targeted CET MAb-DOCT-γ-PGA Nps (T Nps: 200±20 nm) were prepared using ionic gelation followed by 1-Ethyl-3-(3-dimethyl aminopropyl)carbodiimide-N-Hydoxysuccinimide (EDC-NSH) chemistry. Increased uptake correlated with enhanced cytotoxicity induced by targeted Nps to EGFR +ve MKN-28 compared with nontargeted Nps as evident from MTT and flow cytometric assays. Nanoformulated DOCT showed a superior pharmacokinetic profile to that of free DOCT in Swiss albino mice, indicating the possibility of improved therapeutic effect in the disease model. Qualitative in vivo imaging showed early and enhanced tumor targeted accumulation of CET MAb-DOCT-γ-PGA Nps in EGFR +ve MKN-28-based gastric cancer xenograft, which exhibited efficient arrest of tumor growth compared with nontargeted Nps and free DOCT. Thus, actively targeted CET MAb-DOCT-γ-PGA Nps could be developed as a substitute to conventional nonspecific chemotherapy, and hence could become a feasible strategy for cancer therapy for EGFR-overexpressing gastric tumors.

In vitro combinatorial anticancer effects of 5-fluorouracil and curcumin loaded N,O-carboxymethyl chitosan nanoparticles toward colon cancer and in vivo pharmacokinetic studies.

Colon cancer is the third most leading causes of death due to cancer worldwide and the chemo drug 5-fluorouracil's (5-FU) applicability is limited due to its non-specificity, low bioavailability and overdose. The efficacy of 5-FU in colon cancer chemo treatment could be improved by nanoencapsulation and combinatorial approach. In the present study curcumin (CUR), a known anticancer phytochemical, was used in combination with 5-FU and the work focuses on the development of a combinatorial nanomedicine based on 5-FU and CUR in N,O-carboxymethyl chitosan nanoparticles (N,O-CMC NPs). The developed 5-FU-N,O-CMC NPs and CUR-N,O-CMC NPs were found to be blood compatible. The in vitro drug release profile in pH 4.5 and 7.4 showed a sustained release profile over a period of 4 days. The combined exposure of the nanoformulations in colon cancer cells (HT 29) proved the enhanced anticancer effects. In addition, the in vivo pharmacokinetic data in mouse model revealed the improved plasma concentrations of 5-FU and CUR which prolonged up to 72 h unlike the bare drugs. In conclusion, the 5-FU and CUR released from the N,O-CMC NPs produced enhanced anticancer effects in vitro and improved plasma concentrations under in vivo conditions.

In vitro targeted imaging and delivery of camptothecin using cetuximab-conjugated multifunctional PLGA-ZnS nanoparticles.

BACKGROUND: Targeted cancer therapy has been extensively developed to improve the quality of treatment by reducing the systemic exposure of cytotoxic drug. Polymeric nanoparticles with conjugated targeting agents are widely investigated because they offer tunability in particle size, drug release profile and biocompatibility. MATERIALS & METHODS: Here, we have prepared targeted multifunctional nanoparticles composed of a poly(lactic-co-glycolic acid) matrix, ZnS:Mn(2+) quantum dots and camptothecin, and targeted them to EGF receptor overexpressing cells with a cetuximab antibody. RESULTS: Physicochemical characterization of multifunctional nanoparticles showed stable particles with sizes of <200 nm. In vitro drug release and blood contact studies showed a sustained release profile, with limited hemolysis. In vitro cytotoxicity and cell uptake studies were carried out in A549, KB and MFC-7 cell lines using 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide assay, FACS, fluorescent microscopic images and spectroflourimetry. CONCLUSION: Our studies revealed higher camptothecin activity and uptake in cell lines that overexpress the EGF receptor. All these results suggest that anti-EGF receptor cetuximab-conjugated poly(lactic-co-glycolic acid) multifunctional nanoparticles can be used as a potential nanomedicine against cancer.