gallic acid and Neoplasms studies

Neoplasms: New abnormal growth of tissue. Malignant neoplasms show a greater degree of anaplasia and have the properties of invasion and metastasis, compared to benign neoplasms.

Research Excerpts

Excerpt	Relevance	Reference
" In addition, characterization of the UGT1A locus and genetic studies directed at understanding the role of bilirubin glucuronidation and the biochemical basis of the clinical symptoms found in unconjugated hyperbilirubinemia have uncovered the structural gene polymorphisms associated with Crigler-Najjar's and Gilbert's syndrome."	4.80	Human UDP-glucuronosyltransferases: metabolism, expression, and disease. ( Strassburg, CP; Tukey, RH, 2000)
"Accordingly, anticancer compounds are essential for chemotherapy-resistant cancer cells."	3.01	How gallic acid regulates molecular signaling: role in cancer drug resistance. ( Alam, W; Aschner, M; Ghanbari, F; Hassani, S; Khan, H; Lotfi, M; Popović-Djordjević, J; Shahcheraghi, SH, 2023)
"Oxidative imbalance plays a key role in cancer induction and cardiovascular diseases (CVD) in patients with type 2 diabetes mellitus (T2DM)."	2.87	Gallic Acid Improves Health-Associated Biochemical Parameters and Prevents Oxidative Damage of DNA in Type 2 Diabetes Patients: Results of a Placebo-Controlled Pilot Study. ( Al-Serori, H; Brath, H; Ferk, F; Knasmueller, S; Kundi, M; Marculescu, R; Mišík, M; Saiko, P; Szekeres, T; Wagner, KH, 2018)
" In addition nanotechnology-mediated approaches are also discussed to enhance bioavailability and therapeutic efficacy."	2.82	Gallic Acid: A Dietary Polyphenol that Exhibits Anti-neoplastic Activities by Modulating Multiple Oncogenic Targets. ( Aggarwal, D; Garg, VK; Kaur, G; Khan, MA; Mistry, H; Mittal, S; Sak, K; Tuli, HS; Yerer, MB, 2022)
"Human diseases such as cancer can be caused by aberrant epigenetic regulation."	2.82	Polyphenols as Potent Epigenetics Agents for Cancer. ( Abdelsalam, SA; Ahmed, EA; Ben Ammar, R; Rajendran, P; Renu, K; Veeraraghavan, V, 2022)
"Gallic acid (GA) is a phenolic acid exclusively found in natural sources such as gallnut, sumac, tea leaves, and oak bark."	2.72	Gallic acid for cancer therapy: Molecular mechanisms and boosting efficacy by nanoscopical delivery. ( Ahn, KS; Ang, HL; Ashrafizadeh, M; Hashemi, F; Hushmandi, K; Khan, H; Kumar, AP; Makvandi, P; Mirzaei, S; Nabavi, N; Samarghandian, S; Sethi, G; Varma, RS; Zabolian, A; Zarrabi, A, 2021)
"Globally, cancer is the second leading cause of death."	2.66	Therapeutic Potential of Plant Phenolic Acids in the Treatment of Cancer. ( Abotaleb, M; Büsselberg, D; Kubatka, P; Liskova, A, 2020)
"The inhibitory effect of gallic acid on cancer cell growth is mediated via the modulation of genes which encodes for cell cycle, metastasis, angiogenesis and apoptosis."	2.49	Gallic acid: molecular rival of cancer. ( Mishra, A; Singh, A; Verma, S, 2013)
"Chemodynamic therapy (CDT) is a novel cancer therapeutic strategy."	1.91	Metal-polyphenol nanodots loaded hollow MnO ( Duan, J; Kuang, Y; Li, C; Liao, T; Liu, Y; Xu, X, 2023)
"Diet and nutrition are important for cancer prevention."	1.72	Dietary behavior and urinary gallic acid concentration differences among underserved elder racial and ethnic minorities in New York City. ( Beeber, M; Fraser, M; Ibrahim, S; Johnson, C; Lu, W; Ma, GX; Navder, K; Ogunwobi, OO; Panitz, A; Yeh, MC; Zambrano, CN, 2022)
"Gallic acid is a natural phenolic compound that displays anti-cancer properties in clinically relevant cell culture and rodent models."	1.62	Gene expression profile analysis of gallic acid-induced cell death process. ( Cheung, PCK; Tang, HM, 2021)
"Gallic acid (GA) is a natural phenolic compound with therapeutic effects that are often challenged by its rapid metabolism and clearance."	1.56	Preparation, characterization and therapeutic properties of gum arabic-stabilized gallic acid nanoparticles. ( Azarian, MMS; Hassani, A; Hussain, SA; Ibrahim, WN, 2020)
"The four compounds inhibited prostate cancer PC-3 cell growth in a dose-dependent manner, whereas CG and MG inhibited breast cancer MDA-MB-231 cell growth."	1.43	Growth inhibition and apoptosis in cancer cells induced by polyphenolic compounds of Acacia hydaspica: Involvement of multiple signal transduction pathways. ( Afsar, T; Ahmed, K; Khan, MR; Razak, S; Salomon, CE; Trembley, JH, 2016)
"Pre-treatment with gallic acid significantly rendered K562 cells more susceptible to NK cell-mediated necrosis, while pre-treatment with rutin significantly rendered K562 cells more susceptible to apoptosis."	1.33	Effect of phenols on natural killer (NK) cell-mediated death in the K562 human leukemic cell line. ( Andrikopoulos, NK; Dedoussis, GV; Kaliora, AC, 2005)

Timeframe	Studies, this research(%)	All Research%
pre-1990	3 (6.98)	18.7374
1990's	1 (2.33)	18.2507
2000's	8 (18.60)	29.6817
2010's	15 (34.88)	24.3611
2020's	16 (37.21)	2.80

Article	Year
Human UDP-glucuronosyltransferases: metabolism, expression, and disease. Annual review of pharmacology and toxicology, 2000, Volume: 40 Topics: Autoimmunity; Chromosome Mapping; Glucuronides; Glucuronosyltransferase; Humans; Hyperbilirubinemia;	2000
6-Phosphogluconate dehydrogenase links oxidative PPP, lipogenesis and tumour growth by inhibiting LKB1-AMPK signalling. Nature cell biology, 2015, Volume: 17, Issue:11 Topics: AMP-Activated Protein Kinase Kinases; AMP-Activated Protein Kinases; Humans; Lipogenesis; Neoplasms;	2015
Another look at phenolic compounds in cancer therapy the effect of polyphenols on ubiquitin-proteasome system. European journal of medicinal chemistry, 2019, Apr-01, Volume: 167 Topics: Animals; Diet; Humans; Neoplasms; Phenols; Polyphenols; Proteasome Endopeptidase Complex; Ubiquitin	2019
Gallic acid for cancer therapy: Molecular mechanisms and boosting efficacy by nanoscopical delivery. Food and chemical toxicology : an international journal published for the British Industrial Biological Research Association, 2021, Volume: 157 Topics: Animals; Antineoplastic Agents, Phytogenic; Apoptosis; Gallic Acid; Humans; Nanoparticle Drug Delive	2021
Gallic Acid: A Dietary Polyphenol that Exhibits Anti-neoplastic Activities by Modulating Multiple Oncogenic Targets. Anti-cancer agents in medicinal chemistry, 2022, Volume: 22, Issue:3 Topics: Antineoplastic Agents, Phytogenic; Cell Proliferation; Gallic Acid; Humans; Neoplasms; Oncogenes; Ph	2022
Polyphenols as Potent Epigenetics Agents for Cancer. International journal of molecular sciences, 2022, Oct-03, Volume: 23, Issue:19 Topics: Animals; Antineoplastic Agents; Chromatin; Curcumin; DNA Methylation; Epigenesis, Genetic; Gallic Ac	2022
How gallic acid regulates molecular signaling: role in cancer drug resistance. Medical oncology (Northwood, London, England), 2023, Sep-27, Volume: 40, Issue:11 Topics: Antineoplastic Agents; Drug Resistance, Neoplasm; Gallic Acid; Humans; Neoplasms; Signal Transductio	2023
Therapeutic Potential of Plant Phenolic Acids in the Treatment of Cancer. Biomolecules, 2020, 02-03, Volume: 10, Issue:2 Topics: Angiogenesis Inhibitors; Animals; Antineoplastic Agents, Phytogenic; Apoptosis; Benzoic Acid; Cell D	2020
Probing Gallic Acid for Its Broad Spectrum Applications. Mini reviews in medicinal chemistry, 2018, Volume: 18, Issue:15 Topics: Anti-Infective Agents; Antineoplastic Agents; Antioxidants; Bacteria; Diabetes Mellitus; DNA Damage;	2018
Gallic acid: molecular rival of cancer. Environmental toxicology and pharmacology, 2013, Volume: 35, Issue:3 Topics: Animals; Antineoplastic Agents; Gallic Acid; Humans; Neoplasms	2013
Medicinal importance of gallic acid and its ester derivatives: a patent review. Pharmaceutical patent analyst, 2015, Volume: 4, Issue:4 Topics: Animals; Anti-Inflammatory Agents; Antioxidants; Esters; Gallic Acid; Humans; Neoplasms; Patents as	2015
[Review in the studies on tannins activity of cancer prevention and anticancer]. Zhong yao cai = Zhongyaocai = Journal of Chinese medicinal materials, 2003, Volume: 26, Issue:6 Topics: Animals; Antineoplastic Agents, Phytogenic; Flavonoids; Gallic Acid; Humans; Mice; Neoplasms; Phenol	2003
Synthetic antioxidants: biochemical actions and interference with radiation, toxic compounds, chemical mutagens and chemical carcinogens. Toxicology, 1984, Volume: 33, Issue:3-4 Topics: Adult; Animals; Anisoles; Antibody Formation; Antioxidants; Butylated Hydroxyanisole; Butylated Hydr	1984
[The influence of carotenoids and synthetic beta-carotene on human health]. Polskie Archiwum Medycyny Wewnetrznej, 2001, Volume: 106, Issue:6 Topics: beta Carotene; Cardiovascular Diseases; Carotenoids; Dietary Supplements; Gallic Acid; Humans; Macul	2001

Article	Year
Spectroscopic and computational studies on the binding interaction between gallic acid and Pin1. Luminescence : the journal of biological and chemical luminescence, 2021, Volume: 36, Issue:8 Topics: Gallic Acid; Humans; Hydrogen Bonding; Neoplasms; NIMA-Interacting Peptidylprolyl Isomerase; Protein	2021
Ultrasmall Zwitterionic Polypeptide-Coordinated Nanohybrids for Highly Efficient Cancer Photothermal Ferrotherapy. ACS applied materials & interfaces, 2021, Sep-22, Volume: 13, Issue:37 Topics: Animals; Antineoplastic Agents; Cell Line, Tumor; Coordination Complexes; Female; Ferroptosis; Galli	2021
Dietary behavior and urinary gallic acid concentration differences among underserved elder racial and ethnic minorities in New York City. Cancer causes & control : CCC, 2022, Volume: 33, Issue:7 Topics: Aged; Diet; Ethnic and Racial Minorities; Feeding Behavior; Female; Fruit; Gallic Acid; Humans; Male	2022
The diminution and modulation role of water-soluble gallic acid-carboxymethyl chitosan conjugates against the induced nephrotoxicity with cisplatin. Scientific reports, 2022, 11-19, Volume: 12, Issue:1 Topics: Animals; Chitosan; Cisplatin; Gallic Acid; Neoplasms; Rats; Water	2022
The diminution and modulation role of water-soluble gallic acid-carboxymethyl chitosan conjugates against the induced nephrotoxicity with cisplatin. Scientific reports, 2022, 11-19, Volume: 12, Issue:1 Topics: Animals; Chitosan; Cisplatin; Gallic Acid; Neoplasms; Rats; Water	2022
The diminution and modulation role of water-soluble gallic acid-carboxymethyl chitosan conjugates against the induced nephrotoxicity with cisplatin. Scientific reports, 2022, 11-19, Volume: 12, Issue:1 Topics: Animals; Chitosan; Cisplatin; Gallic Acid; Neoplasms; Rats; Water	2022
The diminution and modulation role of water-soluble gallic acid-carboxymethyl chitosan conjugates against the induced nephrotoxicity with cisplatin. Scientific reports, 2022, 11-19, Volume: 12, Issue:1 Topics: Animals; Chitosan; Cisplatin; Gallic Acid; Neoplasms; Rats; Water	2022
The diminution and modulation role of water-soluble gallic acid-carboxymethyl chitosan conjugates against the induced nephrotoxicity with cisplatin. Scientific reports, 2022, 11-19, Volume: 12, Issue:1 Topics: Animals; Chitosan; Cisplatin; Gallic Acid; Neoplasms; Rats; Water	2022
The diminution and modulation role of water-soluble gallic acid-carboxymethyl chitosan conjugates against the induced nephrotoxicity with cisplatin. Scientific reports, 2022, 11-19, Volume: 12, Issue:1 Topics: Animals; Chitosan; Cisplatin; Gallic Acid; Neoplasms; Rats; Water	2022
The diminution and modulation role of water-soluble gallic acid-carboxymethyl chitosan conjugates against the induced nephrotoxicity with cisplatin. Scientific reports, 2022, 11-19, Volume: 12, Issue:1 Topics: Animals; Chitosan; Cisplatin; Gallic Acid; Neoplasms; Rats; Water	2022
The diminution and modulation role of water-soluble gallic acid-carboxymethyl chitosan conjugates against the induced nephrotoxicity with cisplatin. Scientific reports, 2022, 11-19, Volume: 12, Issue:1 Topics: Animals; Chitosan; Cisplatin; Gallic Acid; Neoplasms; Rats; Water	2022
The diminution and modulation role of water-soluble gallic acid-carboxymethyl chitosan conjugates against the induced nephrotoxicity with cisplatin. Scientific reports, 2022, 11-19, Volume: 12, Issue:1 Topics: Animals; Chitosan; Cisplatin; Gallic Acid; Neoplasms; Rats; Water	2022
Metal-polyphenol nanodots loaded hollow MnO Journal of colloid and interface science, 2023, Mar-15, Volume: 634 Topics: Cell Line, Tumor; Gallic Acid; Glutathione; Humans; Hydrogen Peroxide; Imines; Manganese Compounds;	2023
Anticancer Effect of Gallic Acid on Acidity-Induced Invasion of MCF7 Breast Cancer Cells. Nutrients, 2023, Aug-16, Volume: 15, Issue:16 Topics: Gallic Acid; Heartburn; Humans; Matrix Metalloproteinase 2; MCF-7 Cells; Neoplasms; Phosphatidylinos	2023
A Microbial Siderophore-Inspired Self-Gelling Hydrogel for Noninvasive Anticancer Phototherapy. Cancer research, 2019, Dec-15, Volume: 79, Issue:24 Topics: Animals; Cell Line, Tumor; Combined Modality Therapy; Female; Ferric Compounds; Gallic Acid; Humans;	2019
Dietary Behavior and Urinary Gallic Acid Concentrations in Older Minority Residents of East Harlem, New York City. Journal of racial and ethnic health disparities, 2020, Volume: 7, Issue:2 Topics: Age Factors; Aged; Aged, 80 and over; Black or African American; Diet; Female; Gallic Acid; Hispanic	2020
Applied radiation and isotopes : including data, instrumentation and methods for use in agriculture, industry and medicine, 2020, Volume: 164 Topics: Animals; Cell Line, Tumor; Gallic Acid; Gold; Humans; Metal Nanoparticles; Mice; Neoplasms; Organote	2020
Preparation, characterization and therapeutic properties of gum arabic-stabilized gallic acid nanoparticles. Scientific reports, 2020, 10-20, Volume: 10, Issue:1 Topics: Angiotensin-Converting Enzyme Inhibitors; Antineoplastic Agents; Antioxidants; Apoptosis; Biphenyl C	2020
Intratumoral synthesis of nano-metalchelate for tumor catalytic therapy by ligand field-enhanced coordination. Nature communications, 2021, 06-07, Volume: 12, Issue:1 Topics: Animals; Antineoplastic Agents; Catalysis; Coordination Complexes; Drug Carriers; Female; Gallic Aci	2021
Gene expression profile analysis of gallic acid-induced cell death process. Scientific reports, 2021, 08-18, Volume: 11, Issue:1 Topics: Antineoplastic Agents; Gallic Acid; Gene Expression Profiling; Gene Expression Regulation, Neoplasti	2021
BSA-assisted synthesis of ultrasmall gallic acid-Fe(III) coordination polymer nanoparticles for cancer theranostics. International journal of nanomedicine, 2017, Volume: 12 Topics: Animals; Biocompatible Materials; Cell Line, Tumor; Gallic Acid; Humans; Hyperthermia, Induced; Iron	2017
Paclitaxel-Induced Ultrasmall Gallic Acid-Fe@BSA Self-Assembly with Enhanced MRI Performance and Tumor Accumulation for Cancer Theranostics. ACS applied materials & interfaces, 2018, Aug-29, Volume: 10, Issue:34 Topics: Cell Line, Tumor; Ferric Compounds; Gallic Acid; Humans; Magnetic Resonance Imaging; Nanoparticles;	2018
Growth inhibition and apoptosis in cancer cells induced by polyphenolic compounds of Acacia hydaspica: Involvement of multiple signal transduction pathways. Scientific reports, 2016, Mar-15, Volume: 6 Topics: Acacia; Apoptosis; bcl-X Protein; Blotting, Western; Catechin; Cell Line, Tumor; Cell Proliferation;	2016
Identification and optimization of hydrazone-gallate derivatives as specific inhibitors of DNA methyltransferase 3A. Future medicinal chemistry, 2016, Volume: 8, Issue:4 Topics: Antineoplastic Agents; Cell Line, Tumor; Cell Proliferation; DNA (Cytosine-5-)-Methyltransferases; D	2016
In silico studies on potential MCF-7 inhibitors: a combination of pharmacophore and 3D-QSAR modeling, virtual screening, molecular docking, and pharmacokinetic analysis. Journal of biomolecular structure & dynamics, 2017, Volume: 35, Issue:9 Topics: Anticarcinogenic Agents; Catalytic Domain; Computer Simulation; Gallic Acid; Humans; Ligands; MCF-7	2017
Antioxidant and antiproliferative activity of Diospyros lotus L. extract and isolated compounds. Plant foods for human nutrition (Dordrecht, Netherlands), 2009, Volume: 64, Issue:4 Topics: Antineoplastic Agents, Phytogenic; Antioxidants; Cell Line, Tumor; Cell Proliferation; Diospyros; El	2009
Bioactive compounds and antioxidant and antiproliferative activities of Korean white lotus cultivars. Journal of medicinal food, 2009, Volume: 12, Issue:5 Topics: Amino Acids; Antineoplastic Agents, Phytogenic; Antioxidants; Ascorbic Acid; Cell Line, Tumor; Cell	2009
Suppression of TNF-α induced NFκB activity by gallic acid and its semi-synthetic esters: possible role in cancer chemoprevention. Natural product research, 2010, Volume: 24, Issue:18 Topics: Analysis of Variance; Cell Line; Chromatography, Gel; Chromatography, High Pressure Liquid; Euphorbi	2010
Gallic acid suppresses cell viability, proliferation, invasion and angiogenesis in human glioma cells. European journal of pharmacology, 2010, Sep-01, Volume: 641, Issue:2-3 Topics: Animals; Blotting, Western; Brain Neoplasms; Cell Line; Cell Line, Tumor; Cell Proliferation; Cell S	2010
Surface modified dendrimers: synthesis and characterization for cancer targeted drug delivery. Bioorganic & medicinal chemistry, 2011, Jun-01, Volume: 19, Issue:11 Topics: Antineoplastic Agents; Cell Line, Tumor; Dendrimers; Gallic Acid; Humans; Magnetic Resonance Spectro	2011
[The effect of propyl gallate on glycolysis of tumor- and normal tissue]. Acta biologica et medica Germanica, 1960, Volume: 5 Topics: Animals; Carbohydrate Metabolism; Carbohydrates; Gallic Acid; Glycolysis; Humans; Hydrolyzable Tanni	1960
Effect of phenols on natural killer (NK) cell-mediated death in the K562 human leukemic cell line. Cell biology international, 2005, Volume: 29, Issue:11 Topics: Annexin A5; Annexins; Apoptosis; Cell Death; Cell Line, Tumor; Cell Separation; Coculture Techniques	2005
Reactive oxygen species and intracellular Ca2+, common signals for apoptosis induced by gallic acid. Biochemical pharmacology, 1998, Jun-15, Volume: 55, Issue:12 Topics: Animals; Antineoplastic Agents; Apoptosis; Calcium; Electrophoresis, Agar Gel; Flow Cytometry; Galli	1998
Cancer chemopreventive effects of constituents of Caesalpinia ferrea and related compounds. Cancer letters, 2002, Mar-28, Volume: 177, Issue:2 Topics: Antigens, Viral; Biological Assay; Caesalpinia; Gallic Acid; Humans; Neoplasms; Phytotherapy; Plant	2002
Can apple antioxidants inhibit tumor cell proliferation? Generation of H(2)O(2) during interaction of phenolic compounds with cell culture media. Journal of agricultural and food chemistry, 2002, May-22, Volume: 50, Issue:11 Topics: Antioxidants; Caffeic Acids; Catalase; Cell Division; Copper; Culture Media; Fruit; Gallic Acid; Hyd	2002
Lipopolysaccharide-mediated macrophage activation: the role of calcium in the generation of tumoricidal activity. Journal of immunology (Baltimore, Md. : 1950), 1987, Feb-01, Volume: 138, Issue:3 Topics: Aminoquinolines; Animals; Calcimycin; Calcium; Cytotoxicity, Immunologic; Cytotoxins; Gallic Acid; L	1987

gallic acid and Neoplasms

Research Excerpts

Research

Studies (43)

Authors

Reviews

Trials

Other Studies

Authors	Studies
Tukey, RH	1
Strassburg, CP	1
Lin, R	1
Elf, S	1
Shan, C	1
Kang, HB	1
Ji, Q	1
Zhou, L	2
Hitosugi, T	1
Zhang, L	1
Zhang, S	1
Seo, JH	1
Xie, J	1
Tucker, M	1
Gu, TL	1
Sudderth, J	1
Jiang, L	1
Mitsche, M	1
DeBerardinis, RJ	1
Wu, S	1
Li, Y	1
Mao, H	1
Chen, PR	1
Wang, D	1
Chen, GZ	1
Hurwitz, SJ	1
Lonial, S	1
Arellano, ML	1
Khoury, HJ	1
Khuri, FR	1
Lee, BH	1
Lei, Q	1
Brat, DJ	1
Ye, K	1
Boggon, TJ	1
He, C	1
Kang, S	1
Fan, J	1
Chen, J	1
Golonko, A	1
Pienkowski, T	1
Swislocka, R	1
Lazny, R	1
Roszko, M	1
Lewandowski, W	1
Zhu, GF	1
Lyu, SL	1
Liu, Y	3
Ma, C	1
Wang, W	1
Du, C	1
Qian, J	1
He, M	1
Zhang, ZG	1
Feng, C	1
Zhang, Y	1
Zhang, R	1
Dong, CM	1
Ashrafizadeh, M	1
Zarrabi, A	1
Mirzaei, S	1
Hashemi, F	1
Samarghandian, S	1
Zabolian, A	1
Hushmandi, K	1
Ang, HL	1
Sethi, G	1
Kumar, AP	1
Ahn, KS	1
Nabavi, N	1
Khan, H	2
Makvandi, P	1
Varma, RS	1
Tuli, HS	1
Mistry, H	1
Kaur, G	1
Aggarwal, D	1
Garg, VK	1
Mittal, S	1
Yerer, MB	1
Sak, K	1
Khan, MA	1
Zambrano, CN	2
Lu, W	2
Johnson, C	2
Beeber, M	2
Panitz, A	2
Ibrahim, S	2
Fraser, M	2
Ma, GX	2
Navder, K	2
Yeh, MC	2
Ogunwobi, OO	2
Rajendran, P	1
Abdelsalam, SA	1
Renu, K	1
Veeraraghavan, V	1
Ben Ammar, R	1
Ahmed, EA	1
Hafez, HS	3
Kotb, ES	3
El-Khayat, Z	3
Elshaarawy, RFM	3
Serag, WM	3
Duan, J	1
Liao, T	1
Xu, X	1
Kuang, Y	1
Li, C	1
Hong, R	1
Lim, SC	1
Lee, TB	1
Han, SI	1
Hassani, S	1
Ghanbari, F	1
Lotfi, M	1
Alam, W	1
Aschner, M	1
Popović-Djordjević, J	1
Shahcheraghi, SH	1
Ko, S	1
Park, JY	1
Oh, YK	1
Wyka, K	1
Bhimla, A	1
Tan, Y	1
Abotaleb, M	1
Liskova, A	1
Kubatka, P	1
Büsselberg, D	1
Sakr, TM	1
El-Hashash, MA	1
El-Mohty, AA	1
Essa, BM	1
Hassani, A	1
Azarian, MMS	1
Ibrahim, WN	1
Hussain, SA	1
Yang, B	1
Yao, H	1
Tian, H	1
Yu, Z	1
Guo, Y	1
Wang, Y	1
Yang, J	1
Chen, C	1
Shi, J	1
Tang, HM	1
Cheung, PCK	1
Mu, X	2
Yan, C	2
Tian, Q	2
Lin, J	2
Yang, S	2
Ferk, F	1
Kundi, M	1
Brath, H	1
Szekeres, T	1
Al-Serori, H	1
Mišík, M	1
Saiko, P	1
Marculescu, R	1
Wagner, KH	1
Knasmueller, S	1
Choubey, S	2
Goyal, S	1
Varughese, LR	2
Kumar, V	2
Sharma, AK	1
Beniwal, V	2
An, L	1
Tao, C	1
Verma, S	1
Singh, A	1
Mishra, A	1
Afsar, T	1
Trembley, JH	1
Salomon, CE	1
Razak, S	1
Khan, MR	1
Ahmed, K	1
Erdmann, A	1
Menon, Y	1
Gros, C	1
Masson, V	1
Aussagues, Y	1
Ausseil, F	1
Novosad, N	1
Schambel, P	1
Baltas, M	1
Arimondo, PB	1
Badhani, B	1
Kakkar, R	1
Loizzo, MR	1
Said, A	1
Tundis, R	1
Hawas, UW	1
Rashed, K	1
Menichini, F	2
Frega, NG	1
Park, YS	1
Towantakavanit, K	1
Kowalska, T	1
Jung, ST	1
Ham, KS	1
Heo, BG	1
Cho, JY	1
Yun, JG	1
Kim, HJ	1
Gorinstein, S	1
Morais, MC	1
Luqman, S	1
Kondratyuk, TP	1
Petronio, MS	1
Regasini, LO	1
Silva, DH	1
Bolzani, VS	1
Soares, CP	1
Pezzuto, JM	1
Lu, Y	1
Jiang, F	1
Jiang, H	1
Wu, K	1
Zheng, X	1
Cai, Y	1
Katakowski, M	1
Chopp, M	1
To, SS	1
Sharma, A	1
Gautam, SP	1
Gupta, AK	1
SCHOEN, R	1
VENKER, P	1
Li, H	1
Wang, Z	1
Dedoussis, GV	1
Kaliora, AC	1
Andrikopoulos, NK	1
Kahl, R	1
Sakaguchi, N	1
Inoue, M	1
Ogihara, Y	1
Nakamura, ES	1
Kurosaki, F	1
Arisawa, M	1
Mukainaka, T	1
Okuda, M	1
Tokuda, H	1
Nishino, H	1
Pastore, F	1
Lapidot, T	1
Walker, MD	1
Kanner, J	1
Wartanowicz, M	1
Drysdale, BE	1
Yapundich, RA	1
Shin, ML	1
Shin, HS	1