Zeynep Büşra Bolat scite author profile

Combination chemotherapy, administrating two chemotherapeutic agents concurrently, comes into prominence, as the heterogeneity or the level of the disease necessitates a collaborative action. Curcumin, isolated from turmeric, and piperine, isolated from black long pepper, are two dietary polyphenols studied for their intrinsic anti-cancer properties against various cancer types including colorectal cancer (CRC). Furthermore, piperine improves the therapeutic effect of curcumin. Addressing this mutual behavior, this study combines curcumin and piperine within emulsome nanoformulations. Curcumin-(CurcuEmulsomes) and piperine-loaded emulsomes (PiperineEmulsomes) have established a uniform, stable, spherical dispersion with average diameters of 184.21 and 248.76 nm, respectively. The solid tripalmitin inner core achieved encapsulation capacities of up to 0.10 mg/ml curcumin and 0.09 mg/ml piperine content. While piperine treatment alone-in its both free and emulsome forms-showed no inhibition in the proliferation of HCT116 cells in vitro, its presence as the second drug agent enhanced curcumin's effect. Combination of 7 µM PiperineEmulsome and 25 µM CurcuEmulsome concentrations was found to be most effective with an inhibition of cell proliferation of about 50% viability. Cell cycle arrest at G2/M phase and induced apoptosis verified the improved anti-cancer characteristics of the therapy. While CurcuEmulsomes achieved a fourfold increase in Caspase 3 level, combination of treatment with PiperineEulsomes achieved a sixfold increase in the level of this apoptotic marker. Combinational treatment of HCT116 cells with CurcuEmulsomes and PiperineEmulsomes improved the anticancer activity of the compounds and highlighted the potential of the approach for further in vivo studies.

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Design of Colloidally Stable and Non‐Toxic Petox‐Based Polymersomes for Cargo Molecule Encapsulation

Öz

Küçüktürkmen

Özköse

et al. 2019

ChemNanoMat

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Polymersomes are vesicular constructs formed by the self‐assembly of polymer amphiphiles. Here we report the fabrication of PEtOx‐b‐PLA polymersomes at physiological pH/salt concentration and the determination of a fPEtOx range, which is one of the most recognized factors that governs the self‐assembly of amphiphilic copolymers, for the first time. The findings indicate that PEtOx‐b‐PLA copolymers, containing PEtOx fractions of varied lengths, self‐assemble to form polymersomes in the range of 98.35 to 119.50 nm. The encapsulation potential of PEtOx‐b‐PLA polymersomes was demonstrated by loading of docetaxel (hydrophobic) with 17.90% encapsulation efficiency and by loading of pDNA (hydrophilic) with 65.03% encapsulation efficiency. In addition, size distribution profiles showed that polymersomes are colloidally stable for 24 h at 37 °C and for 3 months at +4 °C. The cell viability results showed that PEtOx‐b‐PLA copolymer and polymersomes are not cytotoxic to HUVEC, HEK293 and hMSC cell lines.

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Synthesis, biocompatibility and gene encapsulation of poly(2-Ethyl 2-Oxazoline)-dioleoyl phosphatidylethanolamine (PEtOx-DOPE) and post-modifications with peptides and fluorescent dye coumarin

Gülyüz

Bayram

Özköse

et al. 2020

International Journal of Polymeric Materials and Polymeric Biom

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Cloning of Intron-Removed Enolase Gene and Expression, Purification, Kinetic Characterization of the Enzyme from Theileria annulata

et al. 2014

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Tropical theileriosis is a disease caused by infection with an apicomplexan parasite, Theileria annulata, and giving rise to huge economic losses. In recent years, parasite resistance has been reported against the most effective antitheilerial drug used for the treatment of this disease. This emphasizes the need for alternative methods of treatment. Enolase is a key glycolytic enzyme and can be selected as a macromolecular target of therapy of tropical theileriosis. In this study, an intron sequence present in T. annulata enolase gene was removed by PCR-directed mutagenesis, and the gene was first cloned into pGEM-T Easy vector and then subcloned into pLATE31 vector, and expressed in Escherichia coli cells. The enzyme was purified by affinity chromatography using Ni-NTA agarose column. Steady-state kinetic parameters of the enzyme were determined using GraFit 3.0. High quantities (~65 mg/l of culture) of pure recombinant T. annulata enolase have been obtained in a higly purified form (>95 %). Homodimer form of purified protein was determined from the molecular weights obtained from a single band on SDS-PAGE (48 kDa) and from size exclusion chromatography (93 kDa). Enzyme kinetic measurements using 2-PGA as substrate gave a specific activity of ~40 U/mg, K m: 106 μM, kcat: 37 s(-1), and k cat/K m: 3.5 × 10(5) M(-1) s(-1). These values have been determined for the first time from this parasite enzyme, and availability of large quantities of enolase enzyme will facilitate further kinetic and structural characterization toward design of new antitheilerial drugs.

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