Spelling suggestions: "subject:"anticancer"" "subject:"antiacancer""
91 |
Derivation of Hydroquinone to Produce Selective, Oxidatively Activated Chemotherapeutic AgentsBell-Horwath, Tiffany R. 12 September 2014 (has links)
No description available.
|
92 |
Derivation of Hydroquinone to Produce Selective, Oxidatively Activated Chemotherapeutic AgentsBell-Horwath, Tiffany R. 17 October 2014 (has links)
No description available.
|
93 |
FROM NON-STEROIDAL ANTI-INFLAMMATORY DRUG (NSIAD) INDOMETHACIN TO ANTI-CANCER AGENTS: DESIGN, SYNTHESIS, BIOLOGICAL EVALUATION AND MECHANISM INVESTIGATIONChennamaneni, Snigdha January 2014 (has links)
No description available.
|
94 |
Toward Total Synthesis of (-)-Muironolide AClay, Charles Michael 10 August 2017 (has links)
No description available.
|
95 |
Modified Nucleosides Part A: A Platform for the Chemical Tagging of Ribonucleic Acids for Analysis by Mass Spectrometry Part B: Base-Modified Thymidines Exhibiting Cytotoxicity towards Cancer CellsBorland, Kayla January 2019 (has links)
No description available.
|
96 |
Computational, Synthetic, Biochemical and Biological Studies and Characterization on STAT3 Inhibitors for Potential Anticancer TherapyYu, Wenying 04 September 2013 (has links)
No description available.
|
97 |
Design and Synthesis of Stable Glucose Uptake InhibitorsRoberts, Dennis A. January 2016 (has links)
No description available.
|
98 |
Pin1 Inhibitors: Towards Understanding the Enzymatic MechanismXu, Guoyan 11 June 2010 (has links)
An important role of Pin1 is to catalyze the cis-trans isomerization of pSer/Thr-Pro bonds; as such, it plays an important role in many cellular events through the effects of conformational change on the function of its biological substrates, including Cdc25, c-Jun, and p53. The expression of Pin1 correlates with cyclin D1 levels, which contributes to cancer cell transformation. Overexpression of Pin1 promotes tumor growth, while its inhibition causes tumor cell apoptosis. Because Pin1 is overexpressed in many human cancer tissues, including breast, prostate, and lung cancer tissues, it plays an important role in oncogenesis, making its study vital for the development of anti-cancer agents.
Many inhibitors have been discovered for Pin1, including 1) several classes of designed inhibitors such as alkene isosteres, non-peptidic, small molecular Pin1 inhibitors, and indanyl ketones, and 2) several natural products such as juglone, pepticinnamin E analogues, PiB and its derivatives obtained from a library screen. These Pin1 inhibitors show promise in the development of novel diagnostic and therapeutic anticancer drugs due to their ability to block cell cycle progression. In order to develop potent Pin1 inhibitors, the concept of transition-state analogues was used for the design of three classes of compounds: ketoamide, ketone, and reduced amide analogues.
Specifically, a convergent synthesis of α-ketoamide inhibitors of Pin1 was developed. An α-hydroxyorthothioester derivative of Ser was reacted directly with an aminyl synthon. The reaction was catalyzed by HgO and HgCl2 to form an α-hydroxyamide. Hydrolysis and coupling were combined in one step in 80% yield. Two diastereomers of a phospho-Ser-Pro α-ketoamide analogue were synthesized. The resulting IC50 values of 100 µM and 200 µM were surprisingly weak for the Pin1 peptidyl-prolyl isomerase.
Diastereomeric ketones were synthesized by coupling cyclohexenyl lithium to the serine Weinreb amide, via the Michael addition of a carboxylate synthon. The IC50 values of the two ketone diastereomers were determined to be 260 μM and 61 μM, respectively.
Five reduced amide inhibitors for Pin1 were synthesized through a selective reduction using borane. The most potent inhibitor was found to be Fmocâ pSerâ Ψ[CH2N]-Proâ tryptamine, which had an IC50 value of 6.3 µM. This represents a 4.5-fold better inhibition for Pin1 than a comparable cis-amide alkene isostere. The co-crystal structure of Acâ pSerâ Ψ[CH2N]-Proâ tryptamine bound to Pin1 was determined to 1.76 Ã resolution.
Towards understanding the two proposed mechanisms of Pin1 catalysis, nucleophilic-additition mechanism and twisted-amide mechanism, three classes of Pin1 inhibitors (ketoamide, ketone, and reduced amide analogues) involving a total of nine compounds were synthesized and evaluated. The weak inhibitory activities of ketoamide and ketone analogues do not support the nucleophilic-addition mechanism, while the twisted-amide mechanism of Pin1 catalysis is promising based on the reduced amide inhibitors with good potencies. / Ph. D.
|
99 |
The hollow fiber assay for drug responsiveness in the Ewing's sarcoma family of tumorsBibby, Michael C., Bridges, E.M., Burchill, S.A. 27 May 2009 (has links)
No / Objective: To investigate the use of the National Cancer Institute's hollow fiber assay (HFA) to evaluate and prioritize novel treatment strategies for clinical trials in the Ewing's sarcoma family of tumors (ESFT).
Study design: The growth and morphology of ESFT cell lines in hollow fibers (HFs) was characterized in vitro and in vivo. Reliability and reproducibility were evaluated using doxorubicin.
Results: The numbers of viable cells in all 6 ESFT cell lines increased with time in vitro (0 to 96 hours). The SKES-1 and A673 cell lines grew exponentially after implantation of HFs in nude mice at subcutaneous and intraperitoneal sites. ESFT cells formed highly organized distinctive morphology within the HFs in vitro and in vivo. The number of viable ESFT cells within the HFs decreased in a time-dependent (24 to 96 hours) and dose-dependent (1 to 10 mg/kg) manner after treatment with doxorubicin in vivo.
Conclusions: The HFA is a versatile short-term in vivo model that may be exploited to predict efficacy of potential anticancer agents in ESFT cells. Tumor markers and pharmacodynamic endpoints may be quantified in the pure population of ESFT cells from within the HFs.
|
100 |
Cytotoxic hydrogen bridged ruthenium quinaldamide complexes showing induced cancer cell death by apoptosisLord, Rianne M., Allison, Simon J., Rafferty, K., Ghandhi, L., Pask, C.M., McGowan, P.C. 01 July 2016 (has links)
Yes / This report presents the first known p-cymene ruthenium quinaldamide complexes which are stabilised
by a hydrogen-bridging atom, [{(p-cym)RuIIX(N,N)}{H+}{(N,N)XRuII(p-cym)}][PF6] (N,N = functionalised
quinaldamide and X = Cl or Br). These complexes are formed by a reaction of [p-cymRu(μ-X)2]2 with a
functionalised quinaldamide ligand. When filtered over NH4PF6, and under aerobic conditions the equilibrium
of NH4PF6 ⇔ NH3 + HPF6 enables incorporation of HPF6 and the stabilisation of two monomeric
ruthenium complexes by a bridging H+, which are counter-balanced by a PF6 counterion. X-ray crystallographic
analysis is presented for six new structures with O⋯O distances of 2.420(4)–2.448(15) Å, which is
significant for strong hydrogen bonds. Chemosensitivity studies against HCT116, A2780 and cisplatinresistant
A2780cis human cancer cells showed the ruthenium complexes with a bromide ancillary ligand
to be more potent than those with a chloride ligand. The 4’-fluoro compounds show a reduction in
potency for both chloride and bromide complexes against all cell lines, but an increase in selectivity
towards cancer cells compared to non-cancer ARPE-19 cells, with a selectivity index >1. Mechanistic
studies showed a clear correlation between IC50 values and induction of cell death by apoptosis
|
Page generated in 0.0451 seconds