Targeting aerobic glycolysis in breast and ovarian cancer
@inproceedings{Xintaropoulou2017TargetingAG,
title={Targeting aerobic glycolysis in breast and ovarian cancer},
author={Chrysi Xintaropoulou},
year={2017}
}Figures, Tables, and Topics from this paper
figure 1.1 
figure 1.10 
table 1.1 
figure 1.11 
figure 1.12 
figure 1.13 
figure 1.14 
figure 1.15 
figure 1.16 
figure 1.17 
figure 1.2 
figure 1.3 
figure 1.4 
figure 1.5 
figure 1.6 
figure 1.7 
figure 1.8 
figure 1.9 
figure 2.1 
table 2.1 
table 2.2 
figure 2.2 
figure 2.3 
table 2.3 
figure 2.4 
table 2.4 
figure 2.5 
table 2.5 
figure 2.6 
table 2.6 
table 2.7 
figure 2.7 
table 2.8 
figure 3.10 
table 3.1 
table 3.10 
figure 3.12 
figure 3.13 
figure 3.16 
figure 3.18 
figure 3.2 
figure 3.20 
table 3.2 
figure 3.22 
figure 3.24 
figure 3.26 
figure 3.28 
figure 3.30 
table 3.3 
figure 3.31 
figure 3.33 
figure 3.35 
figure 3.36 
figure 3.38 
figure 3.4 
table 3.4 
figure 3.40 
figure 3.41 
figure 3.42 
figure 3.44 
figure 3.47 
figure 3.5 
table 3.5 
figure 3.50 
figure 3.52 
figure 3.54 
table 3.6 
table 3.7 
figure 3.8 
table 3.8 
table 3.9 
figure 4.11 
figure 4.11 
figure 4.13 
figure 4.15 
figure 4.17 
figure 4.19 
figure 4.21 
figure 4.22 
figure 4.23 
figure 4.25 
figure 4.25 
figure 4.26 
figure 4.26 
figure 4.28 
figure 4.28 
figure 4.3 
figure 4.3 
figure 4.31 
figure 4.31 
figure 4.32 
figure 4.33 
figure 4.35 
figure 4.37 
figure 4.38 
figure 4.40 
figure 4.43 
figure 4.45 
figure 4.47 
figure 4.48 
figure 4.5 
figure 4.51 
figure 4.52 
figure 4.55 
figure 4.57 
figure 4.59 
figure 4.60 
figure 4.63 
figure 4.64 
figure 4.67 
figure 4.68 
figure 4.7 
figure 4.70 
figure 4.71 
figure 4.72 
figure 4.73 
figure 4.74 
figure 4.76 
figure 4.77 
figure 4.79 
figure 4.81 
table 5.1 
figure 5.1 
figure 5.10 
table 5.10 
figure 5.11 
figure 5.14 
figure 5.15 
figure 5.18 
figure 5.19 
table 5.2 
figure 5.21 
figure 5.22 
figure 5.24 
figure 5.25 
figure 5.26 
figure 5.29 
table 5.3 
figure 5.30 
figure 5.31 
figure 5.33 
figure 5.34 
figure 5.36 
figure 5.38 
figure 5.4 
table 5.4 
figure 5.41 
figure 5.42 
figure 5.44 
figure 5.46 
figure 5.49 
table 5.5 
figure 5.50 
figure 5.53 
figure 5.55 
figure 5.57 
figure 5.59 
figure 5.6 
table 5.6 
figure 5.61 
figure 5.62 
figure 5.63 
figure 5.64 
figure 5.66 
figure 5.66 
figure 5.67 
figure 5.68 
figure 5.68 
table 5.7 
figure 5.71 
figure 5.8 
table 5.8 
table 5.9 
figure 6.10 
table 6.1 
figure 6.12 
figure 6.14 
figure 6.15 
figure 6.17 
figure 6.19 
figure 6.2 
table 6.2 
figure 6.21 
figure 6.24 
figure 6.25 
figure 6.27 
figure 6.3 
table 6.3 
figure 6.32 
figure 6.34 
figure 6.35 
figure 6.38 
table 6.4 
figure 6.40 
figure 6.41 
figure 6.43 
figure 6.45 
figure 6.47 
figure 6.49 
figure 6.5 
table 6.5 
figure 6.52 
figure 6.54 
figure 6.55 
figure 6.57 
figure 6.59 
table 6.6 
figure 6.60 
figure 6.61 
figure 6.62 
figure 6.63 
figure 6.64 
figure 6.72 
figure 6.75 
figure 6.77 
figure 6.8 
figure 7.1 
table 7.1 
figure 7.13 
figure 7.14 
figure 7.16 
figure 7.18 
figure 7.2 
table 7.2 
figure 7.3 
table 7.3 
figure 7.4 
table 7.4 
figure 7.5 
figure 7.6
References
SHOWING 1-10 OF 529 REFERENCES
Understanding the Warburg Effect: The Metabolic Requirements of Cell Proliferation
- Biology, Medicine
- Science
- 2009
- 9,340
- Highly Influential
- PDF
Dichloroacetate enhances apoptotic cell death via oxidative damage and attenuates lactate production in metformin-treated breast cancer cells
- Medicine
- Breast Cancer Research and Treatment
- 2014
- 65
- Highly Influential
Overexpression of Glucose Transporter-1 (GLUT-1) Predicts Poor Prognosis in Epithelial Ovarian Cancer
- Biology, Medicine
- Cancer investigation
- 2013
- 52
- Highly Influential
Small-molecule inhibitors of human LDH5.
- Biology, Medicine
- Future medicinal chemistry
- 2013
- 44
- Highly Influential
A Small-Molecule Inhibitor of Glucose Transporter 1 Downregulates Glycolysis, Induces Cell-Cycle Arrest, and Inhibits Cancer Cell Growth In Vitro and In Vivo
- Biology, Medicine
- Molecular Cancer Therapeutics
- 2012
- 299
- Highly Influential
- PDF
Energy metabolism of cancer: Glycolysis versus oxidative phosphorylation (Review).
- Biology, Medicine
- Oncology letters
- 2012
- 405
- Highly Influential
Aerobic glycolysis: meeting the metabolic requirements of cell proliferation.
- Biology, Chemistry
- Annual review of cell and developmental biology
- 2011
- 1,579
- Highly Influential
- PDF
Control of glycolysis through regulation of PFK1: old friends and recent additions.
- Biology, Medicine
- Cold Spring Harbor symposia on quantitative biology
- 2011
- 158
- Highly Influential
- PDF
Discovery of N-hydroxyindole-based inhibitors of human lactate dehydrogenase isoform A (LDH-A) as starvation agents against cancer cells.
- Chemistry, Medicine
- Journal of medicinal chemistry
- 2011
- 140
- Highly Influential
- PDF