lactic acid and Colorectal Neoplasms studies

Lactic Acid: A normal intermediate in the fermentation (oxidation, metabolism) of sugar. The concentrated form is used internally to prevent gastrointestinal fermentation. (From Stedman, 26th ed)
2-hydroxypropanoic acid : A 2-hydroxy monocarboxylic acid that is propanoic acid in which one of the alpha-hydrogens is replaced by a hydroxy group.

Colorectal Neoplasms: Tumors or cancer of the COLON or the RECTUM or both. Risk factors for colorectal cancer include chronic ULCERATIVE COLITIS; FAMILIAL POLYPOSIS COLI; exposure to ASBESTOS; and irradiation of the CERVIX UTERI.

Research Excerpts

Excerpt	Relevance	Reference
"Fluorouracil (FU) is a cornerstone of colorectal cancer treatment; however, it has clinical and subclinical influence on the heart."	9.14	Fluorouracil induces myocardial ischemia with increases of plasma brain natriuretic peptide and lactic acid but without dysfunction of left ventricle. ( Hasbak, P; Jensen, SA; Mortensen, J; Sørensen, JB, 2010)
"5-Fluorouracil (5-FU) is a widely used chemotherapeutic agent for colorectal cancer (CRC) owing to its potent anticancer effects."	8.31	5-Fluorouracil crystal-incorporated, pH-responsive, and release-modulating PLGA/Eudragit FS hybrid microparticles for local colorectal cancer-targeted chemotherapy. ( Bae, J; Hee Lee, E; Kim, H; Kim, J; Kim, MS; Kwak, D; Lee, J; Phyu Hlaing, S; Ryong Moon, H; Saparbayeva, A; Yoo, JW; Yoon, IS, 2023)
" An immunometabolic strategy for treating colorectal cancer liver metastases using the shikonin-loaded, hyaluronic acid-modified mesoporous polydopamine nanoparticles (SHK@HA-MPDA) via glycolysis inhibition, anticancer immunity activation, and EMT reversal."	8.31	Regulating lactate-related immunometabolism and EMT reversal for colorectal cancer liver metastases using shikonin targeted delivery. ( Chen, G; He, Y; Hou, J; Huang, Y; Lin, F; Long, L; Peng, T; Wang, R; Xiong, W; Xu, Q, 2023)
"To investigate the effect of lactic acid (LA) on the progression of bone metastasis from colorectal cancer (CRC) and its regulatory effects on primary CD115 (+) osteoclast (OC) precursors."	8.02	Lactic acid promotes metastatic niche formation in bone metastasis of colorectal cancer. ( Gong, ZC; Kang, X; Liu, D; Liu, XL; Qian, J; Sheng, J; Wang, LT; Wang, W; Wu, HH; Wu, J; Xu, W; Ye, LJ; Zhang, YN; Zhao, J; Zheng, W, 2021)
" In this paper, we have assessed the impact of citrus pectin and modified citrus pectin on colorectal cancer in rats (Rattus norvegicus F344) to which azoxymethane and DSS were supplied."	8.02	Behaviour of citrus pectin and modified citrus pectin in an azoxymethane/dextran sodium sulfate (AOM/DSS)-induced rat colorectal carcinogenesis model. ( Fernández, J; Ferreira-Lazarte, A; Gallego-Lobillo, P; Lombó, F; Moreno, FJ; Villamiel, M; Villar, CJ, 2021)
"Sorafenib has been recently used for the treatment of patients with advanced colorectal cancer (CRC) and is recognized for its therapeutic value."	7.96	Combination Antitumor Effect of Sorafenib via Calcium-Dependent Deactivation of Focal Adhesion Kinase Targeting Colorectal Cancer Cells. ( Jeong, KY; Kim, HM; Park, M; Sim, JJ, 2020)
"Phytic acid (PA) has been demonstrated to have a potent anticarcinogenic activity against colorectal cancer (CRC)."	7.88	Phytic acid improves intestinal mucosal barrier damage and reduces serum levels of proinflammatory cytokines in a 1,2-dimethylhydrazine-induced rat colorectal cancer model. ( Chen, C; Cheng, L; Li, X; Liu, C; Song, Y; Yang, F, 2018)
" In this work CUR-NPs (curcumin-loaded lipid-polymer-lecithin hybrid nanoparticles) were synthesized and functionalized with ribonucleic acid (RNA) Aptamers (Apts) against epithelial cell adhesion molecule (EpCAM) for targeted delivery to colorectal adenocarcinoma cells."	7.80	Epithelial cell adhesion molecule aptamer functionalized PLGA-lecithin-curcumin-PEG nanoparticles for targeted drug delivery to human colorectal adenocarcinoma cells. ( Duan, W; Li, L; Li, Q; Lin, J; Liu, K; Shigdar, S; Xiang, D; Yang, W, 2014)
"Lactic acid has been directly linked to the massive proliferation of cancerous cells since the glycolytic pathway provides cancerous cells with not only ATP, but also biosynthetic intermediates for rapid growth and proliferation."	7.01	Targeted lactate dehydrogenase genes silencing in probiotic lactic acid bacteria: A possible paradigm shift in colorectal cancer treatment? ( Bence, RL; Bodnar, I; Budán, F; Kaposztas, Z; Macharia, JM; Varjas, T; Zand, A, 2023)
"69 patients with nonmetastatic colorectal cancer (non-mCRC) and 57 with metastatic CRC (mCRC) were enrolled to evaluate the prognostic value of serum albumin (ALB), serum lactate (SLA), and lactate dehydrogenase (LDH) in patients with metastatic CRC."	6.87	Prognostic Significance of Serum Lactic Acid, Lactate Dehydrogenase, and Albumin Levels in Patients with Metastatic Colorectal Cancer. ( Dai, J; Peng, J; Wang, W; Wei, Y; Xia, L; Xu, H; Zhou, F, 2018)
" To achieve better bioavailability of antitumor drugs that were loaded in RBCm-NPs, the functionalization of coated RBCm with specific targeting ability is essential."	5.48	Anti-EGFR-iRGD recombinant protein modified biomimetic nanoparticles loaded with gambogic acid to enhance targeting and antitumor ability in colorectal cancer treatment. ( Hua, D; Huang, J; Liu, B; Qian, H; Qian, X; Sha, H; Yu, L; Zhang, H; Zhang, Z, 2018)
"Dimethilhydrazine was used to induce colorectal cancer in mice."	5.46	Anti-cancer effect of lactic acid bacteria expressing antioxidant enzymes or IL-10 in a colorectal cancer mouse model. ( Azevedo, V; Bermúdez-Humarán, LG; de Moreno de LeBlanc, A; Del Carmen, S; Langella, P; LeBlanc, JG; Levit, R, 2017)
"An increased risk of colorectal cancer is related to the development of metabolic syndromes including hyperglycemia, and hyperinsulinemia."	5.43	2-Deoxyglucose Reverses the Promoting Effect of Insulin on Colorectal Cancer Cells In Vitro. ( Fei, Q; Li, J; Sun, Y; Wang, F; Zhang, C; Zhang, D; Zhu, C, 2016)
"The role of MCTs in the survival of colorectal cancer (CRC) cells is scarce and poorly understood."	5.42	Monocarboxylate transport inhibition potentiates the cytotoxic effect of 5-fluorouracil in colorectal cancer cells. ( Amorim, R; Baltazar, F; Miranda-Gonçalves, V; Moyer, MP; Pereira, H; Pinheiro, C; Preto, A, 2015)
"Fluorouracil (FU) is a cornerstone of colorectal cancer treatment; however, it has clinical and subclinical influence on the heart."	5.14	Fluorouracil induces myocardial ischemia with increases of plasma brain natriuretic peptide and lactic acid but without dysfunction of left ventricle. ( Hasbak, P; Jensen, SA; Mortensen, J; Sørensen, JB, 2010)
"5-Fluorouracil (5-FU) is a widely used chemotherapeutic agent for colorectal cancer (CRC) owing to its potent anticancer effects."	4.31	5-Fluorouracil crystal-incorporated, pH-responsive, and release-modulating PLGA/Eudragit FS hybrid microparticles for local colorectal cancer-targeted chemotherapy. ( Bae, J; Hee Lee, E; Kim, H; Kim, J; Kim, MS; Kwak, D; Lee, J; Phyu Hlaing, S; Ryong Moon, H; Saparbayeva, A; Yoo, JW; Yoon, IS, 2023)
" An immunometabolic strategy for treating colorectal cancer liver metastases using the shikonin-loaded, hyaluronic acid-modified mesoporous polydopamine nanoparticles (SHK@HA-MPDA) via glycolysis inhibition, anticancer immunity activation, and EMT reversal."	4.31	Regulating lactate-related immunometabolism and EMT reversal for colorectal cancer liver metastases using shikonin targeted delivery. ( Chen, G; He, Y; Hou, J; Huang, Y; Lin, F; Long, L; Peng, T; Wang, R; Xiong, W; Xu, Q, 2023)
" In this paper, we have assessed the impact of citrus pectin and modified citrus pectin on colorectal cancer in rats (Rattus norvegicus F344) to which azoxymethane and DSS were supplied."	4.02	Behaviour of citrus pectin and modified citrus pectin in an azoxymethane/dextran sodium sulfate (AOM/DSS)-induced rat colorectal carcinogenesis model. ( Fernández, J; Ferreira-Lazarte, A; Gallego-Lobillo, P; Lombó, F; Moreno, FJ; Villamiel, M; Villar, CJ, 2021)
"To investigate the effect of lactic acid (LA) on the progression of bone metastasis from colorectal cancer (CRC) and its regulatory effects on primary CD115 (+) osteoclast (OC) precursors."	4.02	Lactic acid promotes metastatic niche formation in bone metastasis of colorectal cancer. ( Gong, ZC; Kang, X; Liu, D; Liu, XL; Qian, J; Sheng, J; Wang, LT; Wang, W; Wu, HH; Wu, J; Xu, W; Ye, LJ; Zhang, YN; Zhao, J; Zheng, W, 2021)
"Sorafenib has been recently used for the treatment of patients with advanced colorectal cancer (CRC) and is recognized for its therapeutic value."	3.96	Combination Antitumor Effect of Sorafenib via Calcium-Dependent Deactivation of Focal Adhesion Kinase Targeting Colorectal Cancer Cells. ( Jeong, KY; Kim, HM; Park, M; Sim, JJ, 2020)
"Phytic acid (PA) has been demonstrated to have a potent anticarcinogenic activity against colorectal cancer (CRC)."	3.88	Phytic acid improves intestinal mucosal barrier damage and reduces serum levels of proinflammatory cytokines in a 1,2-dimethylhydrazine-induced rat colorectal cancer model. ( Chen, C; Cheng, L; Li, X; Liu, C; Song, Y; Yang, F, 2018)
" Correlation of findings with duration of hepatic pedicle clamping, postoperative markers of hepatocellular necrosis and function (aminotransferases, arterial lactate, international normalized ratio, bilirubin), and morbidity."	3.83	Mitochondrial bioenergetics and posthepatectomy liver dysfunction. ( Alexandrino, H; Castro E Sousa, F; Martins, MA; Palmeira, CM; Rolo, AP; Teodoro, JS; Tralhão, JG; Varela, AT, 2016)
" In this work CUR-NPs (curcumin-loaded lipid-polymer-lecithin hybrid nanoparticles) were synthesized and functionalized with ribonucleic acid (RNA) Aptamers (Apts) against epithelial cell adhesion molecule (EpCAM) for targeted delivery to colorectal adenocarcinoma cells."	3.80	Epithelial cell adhesion molecule aptamer functionalized PLGA-lecithin-curcumin-PEG nanoparticles for targeted drug delivery to human colorectal adenocarcinoma cells. ( Duan, W; Li, L; Li, Q; Lin, J; Liu, K; Shigdar, S; Xiang, D; Yang, W, 2014)
"Lactic acid has been directly linked to the massive proliferation of cancerous cells since the glycolytic pathway provides cancerous cells with not only ATP, but also biosynthetic intermediates for rapid growth and proliferation."	3.01	Targeted lactate dehydrogenase genes silencing in probiotic lactic acid bacteria: A possible paradigm shift in colorectal cancer treatment? ( Bence, RL; Bodnar, I; Budán, F; Kaposztas, Z; Macharia, JM; Varjas, T; Zand, A, 2023)
"69 patients with nonmetastatic colorectal cancer (non-mCRC) and 57 with metastatic CRC (mCRC) were enrolled to evaluate the prognostic value of serum albumin (ALB), serum lactate (SLA), and lactate dehydrogenase (LDH) in patients with metastatic CRC."	2.87	Prognostic Significance of Serum Lactic Acid, Lactate Dehydrogenase, and Albumin Levels in Patients with Metastatic Colorectal Cancer. ( Dai, J; Peng, J; Wang, W; Wei, Y; Xia, L; Xu, H; Zhou, F, 2018)
"Colorectal cancer is a clinical condition whose treatment often involves intestinal resection."	2.80	Markers of Perioperative Bowel Complications in Colorectal Surgery Patients. ( Havel, E; Hyšpler, R; Kaška, M; Plíšková, L; Tichá, A; Zadák, Z; Žaloudková, L, 2015)
"Totally 90 inpatients with confirmed colorectal cancer by pathological diagnosis were recruited as subjects in this study."	2.80	[Effects of Couplet Medicines (Astragalus Membranaceus and Jiaozhen) on Intestinal Barrier in Postoperative Colorectal Cancer Patients]. ( Chen, XP; Huang, JP; Jiang, XW; Wang, QZ, 2015)
"Chronic inflammation is a major driving factor for the development of colitis-associated cancer (CAC)."	1.51	( Cao, G; Li, J; Li, Z; Shen, H; Xie, P; Yue, Z; Zang, T; Zhang, S; Zhu, Y, 2019)
"Colorectal cancer is the third most common malignancy worldwide, with 1."	1.51	Lactate-Mediated Acidification of Tumor Microenvironment Induces Apoptosis of Liver-Resident NK Cells in Colorectal Liver Metastasis. ( Almuaili, D; Geoghegan, J; Hand, F; Harmon, C; Hoti, E; Houlihan, DD; Lynch, L; Mentor, K; O'Farrelly, C; Robinson, MW, 2019)
"Malignant tumors, such as colorectal cancer (CRC), are heterogeneous diseases characterized by distinct metabolic phenotypes."	1.48	Nuclear factor E2-related factor-2 has a differential impact on MCT1 and MCT4 lactate carrier expression in colonic epithelial cells: a condition favoring metabolic symbiosis between colorectal cancer and stromal cells. ( Ammar, N; Arlt, A; Diehl, K; Dinges, LA; Helm, O; Plundrich, D; Röcken, C; Schäfer, H; Sebens, S, 2018)
" The in vivo study revealed significant enhancement in DTX bioavailability from CS-decorated PLGA NPs with more than 4-fold increase in AUC compared to DTX solution."	1.48	Novel docetaxel chitosan-coated PLGA/PCL nanoparticles with magnified cytotoxicity and bioavailability. ( Alomrani, AH; Ashour, AE; Badran, MM; Harisa, GI; Kumar, A; Yassin, AE, 2018)
" To achieve better bioavailability of antitumor drugs that were loaded in RBCm-NPs, the functionalization of coated RBCm with specific targeting ability is essential."	1.48	Anti-EGFR-iRGD recombinant protein modified biomimetic nanoparticles loaded with gambogic acid to enhance targeting and antitumor ability in colorectal cancer treatment. ( Hua, D; Huang, J; Liu, B; Qian, H; Qian, X; Sha, H; Yu, L; Zhang, H; Zhang, Z, 2018)
"The prognosis of colorectal cancer (CRC) is seriously affected by high intestinal mucosal permeability accompanied by increasing tumor load."	1.48	Effects of berberine on tumor growth and intestinal permeability in HCT116 tumor-bearing mice using polyamines as targets. ( Li, TM; Liu, B; Wang, GX; Wu, YY; Zang, LQ, 2018)
"Dimethilhydrazine was used to induce colorectal cancer in mice."	1.46	Anti-cancer effect of lactic acid bacteria expressing antioxidant enzymes or IL-10 in a colorectal cancer mouse model. ( Azevedo, V; Bermúdez-Humarán, LG; de Moreno de LeBlanc, A; Del Carmen, S; Langella, P; LeBlanc, JG; Levit, R, 2017)
"An increased risk of colorectal cancer is related to the development of metabolic syndromes including hyperglycemia, and hyperinsulinemia."	1.43	2-Deoxyglucose Reverses the Promoting Effect of Insulin on Colorectal Cancer Cells In Vitro. ( Fei, Q; Li, J; Sun, Y; Wang, F; Zhang, C; Zhang, D; Zhu, C, 2016)
"Forty-two patients with gastric or colorectal cancer underwent chemotherapy, including FAM or FOLFOX4 regimens."	1.42	Biomarkers for assessing mucosal barrier dysfunction induced by chemotherapy: Identifying a rapid and simple biomarker. ( Kong, W; Li, Y; Liu, F; Ni, X; Ping, X; Shen, J; Wang, J; Yu, B, 2015)
"The role of MCTs in the survival of colorectal cancer (CRC) cells is scarce and poorly understood."	1.42	Monocarboxylate transport inhibition potentiates the cytotoxic effect of 5-fluorouracil in colorectal cancer cells. ( Amorim, R; Baltazar, F; Miranda-Gonçalves, V; Moyer, MP; Pereira, H; Pinheiro, C; Preto, A, 2015)
"We reported that colorectal cancer express higher levels of LDHA compared with adjacent normal tissue."	1.42	Lactate dehydrogenase A negatively regulated by miRNAs promotes aerobic glycolysis and is increased in colorectal cancer. ( Fang, C; Hao, J; Liu, A; Wang, H; Wang, J; Wang, Z, 2015)
"Under normoxia, the three colorectal cancer cell lines present high rates of lactate production and can be seen as "Warburg" like cancer cells independently of substrate availability, since such profile was dominant at both high and low glucose media contents."	1.40	Metabolic effects of hypoxia in colorectal cancer by 13C NMR isotopomer analysis. ( Abrantes, AM; Botelho, MF; Carvalho, RA; Casalta-Lopes, J; Grazina, MM; Mendes, C; Pires, S; Simões, M; Tavares, LC, 2014)
"Micro- and nanoparticle formulations are widely used to improve the bioavailability of low solubility drugs."	1.40	Docetaxel load biodegradable porous microspheres for the treatment of colorectal peritoneal carcinomatosis. ( Fan, R; Guo, G; Han, B; Luo, Y; Peng, X; Wang, Y; Wu, M; Zheng, Y; Zhou, L, 2014)
"MiR-26a regulates glucose metabolism of colorectal cancer cells by direct targeting the PDHX, which inhibits the conversion of pyruvate to acetyl coenzyme A in the citric acid cycle."	1.40	MicroRNA-26a regulates glucose metabolism by direct targeting PDHX in colorectal cancer cells. ( Chen, B; Jin, X; Liang, S; Liu, J; Liu, Y; Lu, W; Xia, Z; Xu, N; Yuan, Q; Zhao, X, 2014)
"In addition, we established a colorectal cancer model, and detected CD147 expression in vivo."	1.39	Downregulation of CD147 expression by RNA interference inhibits HT29 cell proliferation, invasion and tumorigenicity in vitro and in vivo. ( Deng, Q; Gao, T; He, B; Li, R; Pan, Y; Song, G; Sun, H; Wang, S; Xu, Y, 2013)
"Representative colorectal cancer and non-cancerous cell lines were treated with dichloroacetate (DCA), an inhibitor of pyruvate dehydrogenase kinase."	1.36	Dichloroacetate induces apoptosis and cell-cycle arrest in colorectal cancer cells. ( Hughes, TA; Jayne, DG; Madhok, BM; Perry, SL; Yeluri, S, 2010)
"Studying the transcriptomes of paired colorectal cancer cell lines that differed only in the mutational status of their KRAS or BRAF genes, we found that GLUT1, encoding glucose transporter-1, was one of three genes consistently up-regulated in cells with KRAS or BRAF mutations."	1.35	Glucose deprivation contributes to the development of KRAS pathway mutations in tumor cells. ( Angenendt, P; Cheong, I; Diaz, LA; Kinzler, KW; Lengauer, C; Markowitz, S; Pagliarini, R; Papadopoulos, N; Rago, C; Rajagopalan, H; Schmidt, K; Velculescu, VE; Vogelstein, B; Willson, JK; Yun, J; Zhou, S, 2009)

Timeframe	Studies, this research(%)	All Research%
pre-1990	1 (1.12)	18.7374
1990's	3 (3.37)	18.2507
2000's	6 (6.74)	29.6817
2010's	57 (64.04)	24.3611
2020's	22 (24.72)	2.80

Trial			Phase	Enrollment	Study Type	Start Date	Status
Trial of Dichloroacetate (DCA) in Glioblastoma Multiforme (GBM)[NCT05120284]			Phase 2	40 participants (Anticipated)	Interventional	2022-07-01	Recruiting
[information is prepared from clinicaltrials.gov, extracted Sep-2024]

Article	Year
Targeted lactate dehydrogenase genes silencing in probiotic lactic acid bacteria: A possible paradigm shift in colorectal cancer treatment? Biomedicine & pharmacotherapy = Biomedecine & pharmacotherapie, 2023, Volume: 160 Topics: Colorectal Neoplasms; Glycolysis; Humans; L-Lactate Dehydrogenase; Lactic Acid; Probiotics; Tumor Mi	2023
Lactate-related metabolic reprogramming and immune regulation in colorectal cancer. Frontiers in endocrinology, 2022, Volume: 13 Topics: Carcinogenesis; Cell Transformation, Neoplastic; Colorectal Neoplasms; Glycolysis; Humans; Lactic Ac	2022
Emerging roles of lactic acid bacteria in protection against colorectal cancer. World journal of gastroenterology, 2014, Jun-28, Volume: 20, Issue:24 Topics: Animals; Antioxidants; Apoptosis; Colorectal Neoplasms; DNA Damage; Epigenesis, Genetic; Gene Expres	2014

Article	Year
Prognostic Significance of Serum Lactic Acid, Lactate Dehydrogenase, and Albumin Levels in Patients with Metastatic Colorectal Cancer. BioMed research international, 2018, Volume: 2018 Topics: Adult; Aged; Colorectal Neoplasms; Disease-Free Survival; Female; Humans; L-Lactate Dehydrogenase; L	2018
[Effects of Couplet Medicines (Astragalus Membranaceus and Jiaozhen) on Intestinal Barrier in Postoperative Colorectal Cancer Patients]. Zhongguo Zhong xi yi jie he za zhi Zhongguo Zhongxiyi jiehe zazhi = Chinese journal of integrated traditional and Western medicine, 2015, Volume: 35, Issue:11 Topics: Amine Oxidase (Copper-Containing); Antineoplastic Combined Chemotherapy Protocols; Astragalus propin	2015
Markers of Perioperative Bowel Complications in Colorectal Surgery Patients. Disease markers, 2015, Volume: 2015 Topics: Aged; Anastomotic Leak; Biomarkers; Citrulline; Colorectal Neoplasms; DNA, Bacterial; Fatty Acid-Bin	2015
Fluorouracil induces myocardial ischemia with increases of plasma brain natriuretic peptide and lactic acid but without dysfunction of left ventricle. Journal of clinical oncology : official journal of the American Society of Clinical Oncology, 2010, Dec-20, Volume: 28, Issue:36 Topics: Adult; Aged; Aged, 80 and over; Antimetabolites, Antineoplastic; Antineoplastic Combined Chemotherap	2010
Changes of interleukin-6 and related factors as well as gastric intramucosal pH during colorectal and orthopaedic surgical procedures. Chinese medical sciences journal = Chung-kuo i hsueh k'o hsueh tsa chih, 2006, Volume: 21, Issue:1 Topics: Adult; Aged; C-Reactive Protein; Colorectal Neoplasms; Female; Gastric Acidity Determination; Gastri	2006

Article	Year
Role of salt‑inducible kinase 2 in the malignant behavior and glycolysis of colorectal cancer cells. Molecular medicine reports, 2021, Volume: 24, Issue:5 Topics: Cell Line, Tumor; Cell Movement; Cell Proliferation; Colorectal Neoplasms; Enzyme Activation; Gene E	2021
Simultaneous silencing of the A2aR and PD-1 immune checkpoints by siRNA-loaded nanoparticles enhances the immunotherapeutic potential of dendritic cell vaccine in tumor experimental models. Life sciences, 2022, Jan-01, Volume: 288 Topics: Animals; Apoptosis; Breast Neoplasms; Cell Proliferation; Chitosan; Colorectal Neoplasms; Combined M	2022
DDR1 promotes LoVo cell proliferation by regulating energy metabolism. Acta biochimica et biophysica Sinica, 2022, May-25, Volume: 54, Issue:5 Topics: Bromodeoxyuridine; Cell Line, Tumor; Cell Movement; Cell Proliferation; Colorectal Neoplasms; Diamid	2022
Lactate promotes metastasis of normoxic colorectal cancer stem cells through PGC-1α-mediated oxidative phosphorylation. Cell death & disease, 2022, 07-27, Volume: 13, Issue:7 Topics: Cell Line; Colorectal Neoplasms; Humans; Hypoxia; Lactic Acid; Neoplastic Stem Cells; Oxidative Phos	2022
Lactate: A regulator of immune microenvironment and a clinical prognosis indicator in colorectal cancer. Frontiers in immunology, 2022, Volume: 13 Topics: Colorectal Neoplasms; Humans; Lactic Acid; Neovascularization, Pathologic; Prognosis; Tumor Microenv	2022
5-Fluorouracil crystal-incorporated, pH-responsive, and release-modulating PLGA/Eudragit FS hybrid microparticles for local colorectal cancer-targeted chemotherapy. International journal of pharmaceutics, 2023, Jan-05, Volume: 630 Topics: Animals; Colorectal Neoplasms; Drug Carriers; Drug Delivery Systems; Fluorouracil; Hydrogen-Ion Conc	2023
5-Fluorouracil crystal-incorporated, pH-responsive, and release-modulating PLGA/Eudragit FS hybrid microparticles for local colorectal cancer-targeted chemotherapy. International journal of pharmaceutics, 2023, Jan-05, Volume: 630 Topics: Animals; Colorectal Neoplasms; Drug Carriers; Drug Delivery Systems; Fluorouracil; Hydrogen-Ion Conc	2023
5-Fluorouracil crystal-incorporated, pH-responsive, and release-modulating PLGA/Eudragit FS hybrid microparticles for local colorectal cancer-targeted chemotherapy. International journal of pharmaceutics, 2023, Jan-05, Volume: 630 Topics: Animals; Colorectal Neoplasms; Drug Carriers; Drug Delivery Systems; Fluorouracil; Hydrogen-Ion Conc	2023
5-Fluorouracil crystal-incorporated, pH-responsive, and release-modulating PLGA/Eudragit FS hybrid microparticles for local colorectal cancer-targeted chemotherapy. International journal of pharmaceutics, 2023, Jan-05, Volume: 630 Topics: Animals; Colorectal Neoplasms; Drug Carriers; Drug Delivery Systems; Fluorouracil; Hydrogen-Ion Conc	2023
Circ-IGF1R Affects the Progression of Colorectal Cancer by Activating the miR-362-5p/HMGB3-Mediated Wnt/β-Catenin Signal Pathway. Biochemical genetics, 2023, Volume: 61, Issue:3 Topics: Animals; beta Catenin; Cell Line, Tumor; Cell Proliferation; Colorectal Neoplasms; HMGB3 Protein; Hu	2023
Mutant KRAS Drives Immune Evasion by Sensitizing Cytotoxic T-Cells to Activation-Induced Cell Death in Colorectal Cancer. Advanced science (Weinheim, Baden-Wurttemberg, Germany), 2023, Volume: 10, Issue:6 Topics: CD8-Positive T-Lymphocytes; Cell Death; Colorectal Neoplasms; Humans; Immune Evasion; Lactic Acid; P	2023
Upregulation of HMGB1 in tumor-associated macrophages induced by tumor cell-derived lactate further promotes colorectal cancer progression. Journal of translational medicine, 2023, 01-28, Volume: 21, Issue:1 Topics: Animals; Carcinogenesis; Cell Line, Tumor; Cell Movement; Cell Transformation, Neoplastic; Colorecta	2023
Development of lactate-related gene signature and prediction of overall survival and chemosensitivity in patients with colorectal cancer. Cancer medicine, 2023, Volume: 12, Issue:8 Topics: Colorectal Neoplasms; Databases, Factual; Humans; Lactic Acid; Multivariate Analysis; Mutation; Prog	2023
Regulating lactate-related immunometabolism and EMT reversal for colorectal cancer liver metastases using shikonin targeted delivery. Journal of experimental & clinical cancer research : CR, 2023, May-10, Volume: 42, Issue:1 Topics: Animals; CD8-Positive T-Lymphocytes; Colorectal Neoplasms; Epithelial-Mesenchymal Transition; Humans	2023
Depicting the landscape of gut microbial-metabolic interaction and microbial-host immune heterogeneity in deficient and proficient DNA mismatch repair colorectal cancers. Journal for immunotherapy of cancer, 2023, Volume: 11, Issue:8 Topics: CD8-Positive T-Lymphocytes; Colorectal Neoplasms; DNA Mismatch Repair; Gastrointestinal Microbiome;	2023
MCT4 blockade increases the efficacy of immune checkpoint blockade. Journal for immunotherapy of cancer, 2023, Volume: 11, Issue:10 Topics: Animals; Cell Line, Tumor; Colorectal Neoplasms; Glycolysis; Humans; Immune Checkpoint Inhibitors; L	2023
Differentiated cancer cell-originated lactate promotes the self-renewal of cancer stem cells in patient-derived colorectal cancer organoids. Cancer letters, 2020, 11-28, Volume: 493 Topics: Animals; Cell Differentiation; Cell Proliferation; Colorectal Neoplasms; Disease Progression; Gene E	2020
Behaviour of citrus pectin and modified citrus pectin in an azoxymethane/dextran sodium sulfate (AOM/DSS)-induced rat colorectal carcinogenesis model. International journal of biological macromolecules, 2021, Jan-15, Volume: 167 Topics: Acetates; Animals; Azoxymethane; Bifidobacterium; Blood Glucose; Body Weight; Butyrates; Carcinogene	2021
Combination Antitumor Effect of Sorafenib via Calcium-Dependent Deactivation of Focal Adhesion Kinase Targeting Colorectal Cancer Cells. Molecules (Basel, Switzerland), 2020, Nov-13, Volume: 25, Issue:22 Topics: Antineoplastic Agents; Calcium; Cell Cycle; Cell Line, Tumor; Cell Survival; Colorectal Neoplasms; D	2020
Lactate and TGF-β antagonistically regulate inflammasome activation in the tumor microenvironment. Journal of cellular physiology, 2021, Volume: 236, Issue:6 Topics: Colorectal Neoplasms; Culture Media, Conditioned; HCT116 Cells; Humans; Immunity, Innate; Inflammaso	2021
Lactic acid promotes metastatic niche formation in bone metastasis of colorectal cancer. Cell communication and signaling : CCS, 2021, 01-21, Volume: 19, Issue:1 Topics: Animals; Bone Neoplasms; Cadherins; CD4-Positive T-Lymphocytes; Cell Adhesion; Cell Differentiation;	2021
The risk factors of intraoperative hyperlactatemia in patients undergoing laparoscopic colorectal surgery. Annali italiani di chirurgia, 2021, Volume: 92 Topics: Adult; Aged; Aged, 80 and over; Colorectal Neoplasms; Female; Humans; Hyperlactatemia; Lactic Acid;	2021
The novel hypoxia-inducible factor-1α inhibitor IDF-11774 regulates cancer metabolism, thereby suppressing tumor growth. Cell death & disease, 2017, 06-01, Volume: 8, Issue:6 Topics: Adamantane; Animals; Antineoplastic Agents; Cell Proliferation; Colorectal Neoplasms; Cyclic AMP; Fe	2017
miR-142-5p promotes development of colorectal cancer through targeting SDHB and facilitating generation of aerobic glycolysis. Biomedicine & pharmacotherapy = Biomedecine & pharmacotherapie, 2017, Volume: 92 Topics: Apoptosis; Caco-2 Cells; Case-Control Studies; Cell Proliferation; Colorectal Neoplasms; Gene Expres	2017
Nuclear factor E2-related factor-2 has a differential impact on MCT1 and MCT4 lactate carrier expression in colonic epithelial cells: a condition favoring metabolic symbiosis between colorectal cancer and stromal cells. Oncogene, 2018, 01-04, Volume: 37, Issue:1 Topics: Apoptosis; Biopsy; Cell Line, Tumor; Cell Transformation, Neoplastic; Coculture Techniques; Colon; C	2018
Using PVA and TPGS as combined emulsifier in nanoprecipitation method improves characteristics and anticancer activity of ibuprofen loaded PLGA nanoparticles. Die Pharmazie, 2017, Sep-01, Volume: 72, Issue:9 Topics: Adenocarcinoma; Animals; Antineoplastic Agents; Breast Neoplasms; Caco-2 Cells; Chemistry, Pharmaceu	2017
Alterations of mTOR signaling impact metabolic stress resistance in colorectal carcinomas with BRAF and KRAS mutations. Scientific reports, 2018, 06-15, Volume: 8, Issue:1 Topics: Amino Acid Substitution; AMP-Activated Protein Kinases; Animals; Caco-2 Cells; Colorectal Neoplasms;	2018
Rejuvenation research, 2019, Volume: 22, Issue:2 Topics: Animals; Carcinogenesis; Cell Line, Tumor; Colitis; Colorectal Neoplasms; Dextran Sulfate; Diet; Dis	2019
Phytic acid improves intestinal mucosal barrier damage and reduces serum levels of proinflammatory cytokines in a 1,2-dimethylhydrazine-induced rat colorectal cancer model. The British journal of nutrition, 2018, Volume: 120, Issue:2 Topics: 1,2-Dimethylhydrazine; Animals; Body Weight; Cadherins; Claudin-1; Colon; Colorectal Neoplasms; Cyto	2018
STK25-induced inhibition of aerobic glycolysis via GOLPH3-mTOR pathway suppresses cell proliferation in colorectal cancer. Journal of experimental & clinical cancer research : CR, 2018, Jul-11, Volume: 37, Issue:1 Topics: Animals; Cell Line, Tumor; Cell Proliferation; Colorectal Neoplasms; Disease Models, Animal; Gene Ex	2018
Novel docetaxel chitosan-coated PLGA/PCL nanoparticles with magnified cytotoxicity and bioavailability. Biomedicine & pharmacotherapy = Biomedecine & pharmacotherapie, 2018, Volume: 106 Topics: Animals; Antineoplastic Agents; Biological Availability; Cell Survival; Chitosan; Colorectal Neoplas	2018
Carbonic anhydrase IX is a pH-stat that sets an acidic tumour extracellular pH in vivo. British journal of cancer, 2018, Volume: 119, Issue:5 Topics: Animals; Antigens, Neoplasm; Carbonic Anhydrase IX; Cell Hypoxia; Cell Proliferation; Colorectal Neo	2018
Anti-EGFR-iRGD recombinant protein modified biomimetic nanoparticles loaded with gambogic acid to enhance targeting and antitumor ability in colorectal cancer treatment. International journal of nanomedicine, 2018, Volume: 13 Topics: Animals; Antineoplastic Agents; Apoptosis; Biomimetic Materials; Cell Line, Tumor; Cell Proliferatio	2018
Effects of berberine on tumor growth and intestinal permeability in HCT116 tumor-bearing mice using polyamines as targets. Biomedicine & pharmacotherapy = Biomedecine & pharmacotherapie, 2018, Volume: 107 Topics: Animals; Antineoplastic Agents, Phytogenic; Berberine; Colorectal Neoplasms; Dose-Response Relations	2018
Urgent Laparotomy in Patients with Metastatic Colorectal Cancer Presenting as an Acute Abdomen: A Retrospective Analysis. The Israel Medical Association journal : IMAJ, 2018, Volume: 20, Issue:10 Topics: Abdomen, Acute; Adult; Age Factors; Aged; Aged, 80 and over; Colorectal Neoplasms; Female; Hospital	2018
Lactate-Mediated Acidification of Tumor Microenvironment Induces Apoptosis of Liver-Resident NK Cells in Colorectal Liver Metastasis. Cancer immunology research, 2019, Volume: 7, Issue:2 Topics: Adult; Aged; Apoptosis; Biological Transport; Biomarkers; Biopsy; Cell Line, Tumor; Colorectal Neopl	2019
Exosomes Derived from Human Primary and Metastatic Colorectal Cancer Cells Contribute to Functional Heterogeneity of Activated Fibroblasts by Reprogramming Their Proteome. Proteomics, 2019, Volume: 19, Issue:8 Topics: Amino Acid Transport System ASC; Cell Proliferation; Cell Transformation, Neoplastic; Colonic Neopla	2019
B7-H3 promotes aerobic glycolysis and chemoresistance in colorectal cancer cells by regulating HK2. Cell death & disease, 2019, 04-05, Volume: 10, Issue:4 Topics: Animals; Apoptosis; B7 Antigens; Cell Proliferation; Colorectal Neoplasms; Drug Resistance, Neoplasm	2019
Long Noncoding RNA LINC00265 Promotes Glycolysis and Lactate Production of Colorectal Cancer through Regulating of miR-216b-5p/TRIM44 Axis. Digestion, 2020, Volume: 101, Issue:4 Topics: Cell Line, Tumor; Cell Survival; Colorectal Neoplasms; Gene Expression Regulation, Neoplastic; Glyco	2020
Metabolomics Analysis in Serum from Patients with Colorectal Polyp and Colorectal Cancer by Disease markers, 2019, Volume: 2019 Topics: Acetates; Amino Acids; Biomarkers; Citrates; Colonic Polyps; Colorectal Neoplasms; Glycerol; Humans;	2019
Selective pro-apoptotic and antimigratory effects of polyphenol complex catechin:lysine 1:2 in breast, pancreatic and colorectal cancer cell lines. European journal of pharmacology, 2019, Sep-15, Volume: 859 Topics: Antineoplastic Agents; Apoptosis; Biological Transport; Breast Neoplasms; Catechin; Cell Line, Tumor	2019
TNFα and IL-17 cooperatively stimulate glucose metabolism and growth factor production in human colorectal cancer cells. Molecular cancer, 2013, Jul-17, Volume: 12 Topics: Cell Proliferation; Cell Survival; Colorectal Neoplasms; Gene Expression Regulation, Neoplastic; Glu	2013
Downregulation of CD147 expression by RNA interference inhibits HT29 cell proliferation, invasion and tumorigenicity in vitro and in vivo. International journal of oncology, 2013, Volume: 43, Issue:6 Topics: Antineoplastic Agents; Basigin; Carcinogenesis; Cell Line, Tumor; Cell Proliferation; Cisplatin; Col	2013
Cross-talk between E. coli strains and a human colorectal adenocarcinoma-derived cell line. Scientific reports, 2013, Dec-04, Volume: 3 Topics: Adenocarcinoma; Caco-2 Cells; Cell Line, Tumor; Citric Acid Cycle; Coculture Techniques; Colorectal	2013
Epithelial cell adhesion molecule aptamer functionalized PLGA-lecithin-curcumin-PEG nanoparticles for targeted drug delivery to human colorectal adenocarcinoma cells. International journal of nanomedicine, 2014, Volume: 9 Topics: Adenocarcinoma; Animals; Antigens, Neoplasm; Antineoplastic Agents; Aptamers, Nucleotide; Cell Adhes	2014
Antitumor activity of 7-aminocarboxycoumarin derivatives, a new class of potent inhibitors of lactate influx but not efflux. Molecular cancer therapeutics, 2014, Volume: 13, Issue:6 Topics: Animals; Breast Neoplasms; Colorectal Neoplasms; Coumarins; Female; HCT116 Cells; Humans; Lactic Aci	2014
Docetaxel load biodegradable porous microspheres for the treatment of colorectal peritoneal carcinomatosis. International journal of biological macromolecules, 2014, Volume: 69 Topics: Animals; Antineoplastic Agents; Cell Line, Tumor; Cell Proliferation; Colorectal Neoplasms; Docetaxe	2014
Dichloroacetate induces autophagy in colorectal cancer cells and tumours. British journal of cancer, 2014, Jul-15, Volume: 111, Issue:2 Topics: Animals; Apoptosis; Autophagy; Cell Cycle Checkpoints; Cell Line, Tumor; Colorectal Neoplasms; Dichl	2014
MicroRNA-26a regulates glucose metabolism by direct targeting PDHX in colorectal cancer cells. BMC cancer, 2014, Jun-16, Volume: 14 Topics: Base Sequence; Binding Sites; Cell Line, Tumor; Colorectal Neoplasms; Computational Biology; Gene Ex	2014
Metabolic effects of hypoxia in colorectal cancer by 13C NMR isotopomer analysis. BioMed research international, 2014, Volume: 2014 Topics: Carbon-13 Magnetic Resonance Spectroscopy; Cell Hypoxia; Cell Line, Tumor; Colorectal Neoplasms; Glu	2014
Pyruvate dehydrogenase kinase expression and metabolic changes following dichloroacetate exposure in anoxic human colorectal cancer cells. Experimental cell research, 2015, Feb-01, Volume: 331, Issue:1 Topics: Blotting, Western; Cell Proliferation; Colorectal Neoplasms; Dichloroacetic Acid; Flow Cytometry; Gl	2015
Augmented pentose phosphate pathway plays critical roles in colorectal carcinomas. Oncology, 2015, Volume: 88, Issue:5 Topics: Administration, Oral; Animals; Antineoplastic Agents; Benzoxazoles; Blotting, Western; Cell Line, Tu	2015
Lactate promotes PGE2 synthesis and gluconeogenesis in monocytes to benefit the growth of inflammation-associated colorectal tumor. Oncotarget, 2015, Jun-30, Volume: 6, Issue:18 Topics: Animals; Apoptosis; Blotting, Western; Cell Cycle; Cell Proliferation; Colitis; Colorectal Neoplasms	2015
Biomarkers for assessing mucosal barrier dysfunction induced by chemotherapy: Identifying a rapid and simple biomarker. Clinical laboratory, 2015, Volume: 61, Issue:3-4 Topics: Adult; Aged; Amine Oxidase (Copper-Containing); Antineoplastic Agents; Biomarkers; Citrulline; Color	2015
Monocarboxylate transport inhibition potentiates the cytotoxic effect of 5-fluorouracil in colorectal cancer cells. Cancer letters, 2015, Aug-28, Volume: 365, Issue:1 Topics: Antimetabolites, Antineoplastic; Antineoplastic Combined Chemotherapy Protocols; Cell Line, Tumor; C	2015
GX1-conjugated poly(lactic acid) nanoparticles encapsulating Endostar for improved in vivo anticolorectal cancer treatment. International journal of nanomedicine, 2015, Volume: 10 Topics: Angiogenesis Inhibitors; Animals; Benzenesulfonates; Cell Line, Tumor; Colorectal Neoplasms; Endosta	2015
Lactate dehydrogenase A negatively regulated by miRNAs promotes aerobic glycolysis and is increased in colorectal cancer. Oncotarget, 2015, Aug-14, Volume: 6, Issue:23 Topics: 3' Untranslated Regions; Adenosine Triphosphate; Animals; Binding Sites; Cell Proliferation; Colorec	2015
MicroRNA-124 reduces the pentose phosphate pathway and proliferation by targeting PRPS1 and RPIA mRNAs in human colorectal cancer cells. Gastroenterology, 2015, Volume: 149, Issue:6 Topics: Aldose-Ketose Isomerases; Animals; Cell Line, Tumor; Cell Proliferation; Colorectal Neoplasms; Femal	2015
Tumor suppressor NDRG2 inhibits glycolysis and glutaminolysis in colorectal cancer cells by repressing c-Myc expression. Oncotarget, 2015, Sep-22, Volume: 6, Issue:28 Topics: Amino Acid Transport System ASC; Animals; beta Catenin; Caco-2 Cells; Cell Proliferation; Colorectal	2015
SN-38 active loading in poly(lactic-co-glycolic acid) nanoparticles and assessment of their anticancer properties on COLO-205 human colon adenocarcinoma cells. Journal of microencapsulation, 2015, Volume: 32, Issue:8 Topics: Adenocarcinoma; Antineoplastic Agents, Phytogenic; Apoptosis; Camptothecin; Cell Line, Tumor; Cell P	2015
Enhanced antitumor effects by docetaxel/LL37-loaded thermosensitive hydrogel nanoparticles in peritoneal carcinomatosis of colorectal cancer. International journal of nanomedicine, 2015, Volume: 10 Topics: Animals; Antimicrobial Cationic Peptides; Antineoplastic Agents; Apoptosis; Cathelicidins; Cell Line	2015
2-Deoxyglucose Reverses the Promoting Effect of Insulin on Colorectal Cancer Cells In Vitro. PloS one, 2016, Volume: 11, Issue:3 Topics: Adenosine Triphosphate; Apoptosis; Cell Cycle; Cell Cycle Checkpoints; Cell Line, Tumor; Cell Moveme	2016
Mitochondrial bioenergetics and posthepatectomy liver dysfunction. European journal of clinical investigation, 2016, Volume: 46, Issue:7 Topics: Adenoma; Adenosine Triphosphate; Adult; Aged; Aged, 80 and over; Alanine Transaminase; Aspartate Ami	2016
Oncogenic KRAS and BRAF Drive Metabolic Reprogramming in Colorectal Cancer. Molecular & cellular proteomics : MCP, 2016, Volume: 15, Issue:9 Topics: Biosynthetic Pathways; Cell Line, Tumor; Colorectal Neoplasms; Gene Expression Regulation, Neoplasti	2016
Significance of glycolytic metabolism-related protein expression in colorectal cancer, lymph node and hepatic metastasis. BMC cancer, 2016, 07-26, Volume: 16 Topics: Basigin; Biomarkers, Tumor; Colorectal Neoplasms; Glucose Transporter Type 1; Glycolysis; Humans; Im	2016
Hypoxia-responsive miR-210 promotes self-renewal capacity of colon tumor-initiating cells by repressing ISCU and by inducing lactate production. Oncotarget, 2016, Oct-04, Volume: 7, Issue:40 Topics: Aged; Aged, 80 and over; Carcinogenesis; Cell Self Renewal; Colon; Colonic Neoplasms; Colorectal Neo	2016
Anti-cancer effect of lactic acid bacteria expressing antioxidant enzymes or IL-10 in a colorectal cancer mouse model. International immunopharmacology, 2017, Volume: 42 Topics: Animals; Antineoplastic Agents; Antioxidants; Catalase; Colorectal Neoplasms; Disease Models, Animal	2017
Gambogic acid-loaded biomimetic nanoparticles in colorectal cancer treatment. International journal of nanomedicine, 2017, Volume: 12 Topics: Animals; Antineoplastic Agents; Biocompatible Materials; Biomimetic Materials; Cell Death; Cell Line	2017
Antitumor effect of adriamycin-encapsulated nanoparticles of poly(DL-lactide-co-glycolide)-grafted dextran. Journal of pharmaceutical sciences, 2009, Volume: 98, Issue:6 Topics: Animals; Antibiotics, Antineoplastic; Cell Line, Tumor; Cell Survival; Colorectal Neoplasms; Dextran	2009
Glucose deprivation contributes to the development of KRAS pathway mutations in tumor cells. Science (New York, N.Y.), 2009, Sep-18, Volume: 325, Issue:5947 Topics: Animals; Cell Line, Tumor; Cell Proliferation; Colorectal Neoplasms; Gene Expression Regulation, Neo	2009
Dichloroacetate induces apoptosis and cell-cycle arrest in colorectal cancer cells. British journal of cancer, 2010, Jun-08, Volume: 102, Issue:12 Topics: Apoptosis; Cell Cycle; Cell Line, Tumor; Cell Proliferation; Colorectal Neoplasms; Dichloroacetic Ac	2010
Therapeutic effectiveness of slow-release PLGA-oxaliplatin microsphere on human colorectal tumor-bearing mice. Anti-cancer drugs, 2010, Volume: 21, Issue:6 Topics: Animals; Antineoplastic Agents; Cell Line, Tumor; Colorectal Neoplasms; Delayed-Action Preparations;	2010
Effect of injection site on in situ implant formation and drug release in vivo. Journal of controlled release : official journal of the Controlled Release Society, 2010, Nov-01, Volume: 147, Issue:3 Topics: Animals; Antineoplastic Agents; Catheter Ablation; Cell Line, Tumor; Chemotherapy, Adjuvant; Colorec	2010
Partial liver ischemia is followed by metabolic changes in the normally perfused part of the liver during reperfusion. European surgical research. Europaische chirurgische Forschung. Recherches chirurgicales europeennes, 2010, Volume: 45, Issue:2 Topics: Animals; Colorectal Neoplasms; Disease Models, Animal; Female; Glucose; Glycerol; Humans; Ischemia;	2010
Lactate influx through the endothelial cell monocarboxylate transporter MCT1 supports an NF-κB/IL-8 pathway that drives tumor angiogenesis. Cancer research, 2011, Apr-01, Volume: 71, Issue:7 Topics: Breast Neoplasms; Cell Growth Processes; Cell Line, Tumor; Colorectal Neoplasms; Humans; Hypoxia-Ind	2011
Lactate-induced IL-8 pathway in endothelial cells--letter. Cancer research, 2012, Apr-01, Volume: 72, Issue:7 Topics: Breast Neoplasms; Colorectal Neoplasms; Humans; Interleukin-8; Lactic Acid; Monocarboxylic Acid Tran	2012
1H HR-MAS NMR spectroscopy of tumor-induced local metabolic "field-effects" enables colorectal cancer staging and prognostication. Journal of proteome research, 2013, Feb-01, Volume: 12, Issue:2 Topics: Adenocarcinoma; Adult; Aged; Aged, 80 and over; Amino Acids; Biomarkers, Tumor; Cell Transformation,	2013
Multifocal inflammatory leukoencephalopathy: use of thallium-201 SPECT and proton MRS. Journal of Korean medical science, 2003, Volume: 18, Issue:4 Topics: Adjuvants, Immunologic; Antimetabolites, Antineoplastic; Aspartic Acid; Axons; Biopsy; Brain; Brain	2003
[Decreasing the risk of developing colorectal carcinoma. Lactic acid forming bacteria]. Krankenpflege Journal, 2003, Volume: 41, Issue:7-9 Topics: Animals; Bifidobacterium; Cell Transformation, Neoplastic; Clinical Trials as Topic; Colorectal Neop	2003
Comparison of metabolic pathways between cancer cells and stromal cells in colorectal carcinomas: a metabolic survival role for tumor-associated stroma. Cancer research, 2006, Jan-15, Volume: 66, Issue:2 Topics: Adenocarcinoma; Cell Cycle Proteins; Cell Hypoxia; Cell Proliferation; Cell Survival; Colon; Colorec	2006
Metabolic imaging in tumours by means of bioluminescence. British journal of cancer, 1995, Volume: 72, Issue:5 Topics: Adenocarcinoma; Adenosine Triphosphate; Animals; Carcinoma, Squamous Cell; Cell Death; Colorectal Ne	1995
Immunity and probiotics. Immunology today, 1999, Volume: 20, Issue:9 Topics: Adaptation, Physiological; Bacteria; Colorectal Neoplasms; Humans; Hypersensitivity; Immune Toleranc	1999
Cell-surface fucosylation and magnetic resonance spectroscopy characterization of human malignant colorectal cells. Biochemistry, 1992, Nov-17, Volume: 31, Issue:45 Topics: Amino Acids; Cell Membrane; Cell Survival; Colorectal Neoplasms; Fourier Analysis; Fucose; Humans; L	1992
Oral calcium suppresses increased rectal epithelial proliferation of persons at risk of colorectal cancer. Gut, 1989, Volume: 30, Issue:5 Topics: Administration, Oral; Adult; Aged; Calcium Carbonate; Calcium Gluconate; Cell Division; Colorectal N	1989

lactic acid and Colorectal Neoplasms

Research Excerpts

Research

Studies (89)

Authors

Clinical Trials (1)

Trial Overview

Reviews

Trials

Other Studies

Authors	Studies
Ni, X	2
Feng, Y	1
Fu, X	1
Karoon Kiani, F	1
Izadi, S	1
Ansari Dezfouli, E	1
Ebrahimi, F	1
Mohammadi, M	1
Chalajour, H	1
Mortazavi Bulus, M	1
Nasr Esfahani, M	1
Karpisheh, V	1
Mahmoud Salehi Khesht, A	1
Abbaszadeh-Goudarzi, K	1
Soleimani, A	1
Gholizadeh Navashenaq, J	1
Ahmadi, M	1
Hassannia, H	1
Hojjat-Farsangi, M	1
Shahmohammadi Farid, S	1
Hashemi, V	1
Jadidi-Niaragh, F	1
Xiong, B	1
Xie, Z	1
Song, F	1
Chen, H	1
Wang, X	3
Jin, Z	1
Han, T	1
Li, Y	3
Zhang, D	3
Liu, S	4
Zhao, H	2
Hu, Y	3
Yan, C	2
Mi, Y	1
Li, X	6
Tao, D	2
Qin, J	2
Zhu, D	1
Jiang, Y	1
Cao, H	1
Yang, J	2
Shu, Y	1
Feng, H	1
Yang, X	2
Sun, X	2
Shao, M	1
Lee, J	2
Bae, J	2
Kwak, D	2
Kim, H	2
Kim, J	2
Phyu Hlaing, S	2
Saparbayeva, A	2
Hee Lee, E	2
Yoon, IS	2
Kim, MS	2
Ryong Moon, H	2
Yoo, JW	2
Gao, S	1
Zhang, X	5
Bai, W	1
Wang, J	3
Jiang, B	2
Liu, H	1
Liang, Z	1
Cheng, S	1
Huang, L	1
Li, W	2
Zhou, C	1
Zheng, X	1
Li, S	1
Zeng, Z	1
Kang, L	1
Gao, X	2
Zhou, S	2
Qin, Z	1
Li, D	2
Zhu, Y	2
Ma, D	1
Macharia, JM	1
Kaposztas, Z	1
Varjas, T	1
Budán, F	1
Zand, A	1
Bodnar, I	1
Bence, RL	1
Tong, Z	1
Shi, S	1
Hou, T	1
Gao, G	1
Shan, Y	1
Zhang, C	2
Sun, Q	1
Wu, J	2
Zhu, G	1
Li, T	1
Zhu, X	1
Ni, B	1
Xu, B	1
Ma, X	2
Li, J	5
Long, L	1
Xiong, W	1
Lin, F	1
Hou, J	1
Chen, G	1
Peng, T	1
He, Y	1
Wang, R	2
Xu, Q	1
Huang, Y	1
Guo, Y	2
Liu, J	2
Guo, F	1
Du, L	1
Yang, Y	1
Ma, Y	2
Babl, N	1
Decking, SM	1
Voll, F	1
Althammer, M	1
Sala-Hojman, A	1
Ferretti, R	1
Korf, C	1
Schmidl, C	1
Schmidleithner, L	1
Nerb, B	1
Matos, C	1
Koehl, GE	1
Siska, P	1
Bruss, C	1
Kellermeier, F	1
Dettmer, K	1
Oefner, PJ	1
Wichland, M	1
Ugele, I	1
Bohr, C	1
Herr, W	1
Ramaswamy, S	1
Heinrich, T	1
Herhaus, C	1
Kreutz, M	1
Renner, K	1
Mu, L	1
Huang, K	1
Li, Q	2
Ferreira-Lazarte, A	1
Fernández, J	1
Gallego-Lobillo, P	1
Villar, CJ	1
Lombó, F	1
Moreno, FJ	1
Villamiel, M	1
Jeong, KY	1
Park, M	1
Sim, JJ	1
Kim, HM	2
Tu, CE	1
Zhou, P	1
Guo, X	1
Gu, C	1
Zhang, Y	1
Li, A	1
Qian, J	1
Gong, ZC	1
Zhang, YN	1
Wu, HH	1
Zhao, J	1
Wang, LT	1
Ye, LJ	1
Liu, D	1
Wang, W	2
Kang, X	1
Sheng, J	1
Xu, W	1
Liu, XL	1
Zheng, W	1
Gulmez, S	1
Senger, AS	1
Uzun, O	1
Keklikkiran, ZZ	1
Bozkurt, H	1
Omeroglu, S	1
Polat, E	1
Duman, M	1
Ban, HS	1
Kim, BK	1
Lee, H	1
Harmalkar, D	1
Nam, M	1
Park, SK	1
Lee, K	2
Park, JT	1
Kim, I	1
Hwang, GS	1
Won, M	1
Xiao, Z	1
Ai, F	1
Liu, F	2
Chen, X	1
Cao, K	1
Ren, W	1
Shu, P	1
Diehl, K	1
Dinges, LA	1
Helm, O	1
Ammar, N	1
Plundrich, D	1
Arlt, A	1
Röcken, C	1
Sebens, S	1
Schäfer, H	1
Sahin, A	1
Spiroux, F	1
Guedon, I	1
Arslan, FB	1
Sarcan, ET	1
Ozkan, T	1
Colak, N	1
Yuksel, S	1
Ozdemir, S	1
Ozdemir, B	1
Akbas, S	1
Ultav, G	1
Aktas, Y	1
Capan, Y	1
Fritsche-Guenther, R	1
Zasada, C	1
Mastrobuoni, G	1
Royla, N	1
Rainer, R	1
Roßner, F	1
Pietzke, M	1
Klipp, E	1
Sers, C	1
Kempa, S	1
Zhang, S	1
Xie, P	1
Zang, T	1
Shen, H	1
Cao, G	1
Yue, Z	1
Li, Z	1
Liu, C	2
Chen, C	1
Yang, F	1
Cheng, L	1
Song, Y	1
Wu, F	1
Gao, P	1
Wu, W	1
Wang, Z	3
Di, J	1
Su, X	1
Badran, MM	1
Alomrani, AH	1
Harisa, GI	1
Ashour, AE	1
Kumar, A	1
Yassin, AE	1
Lee, SH	1
McIntyre, D	1
Honess, D	1
Hulikova, A	1
Pacheco-Torres, J	1
Cerdán, S	1
Swietach, P	1
Harris, AL	2
Griffiths, JR	2
Zhang, Z	2
Qian, H	2
Huang, J	1
Sha, H	1
Zhang, H	1
Yu, L	2
Liu, B	3
Hua, D	1
Qian, X	2
Wu, YY	1
Li, TM	1
Zang, LQ	1
Wang, GX	1
Gendler, S	1
Shmilovich, H	1
Aranovich, D	1
Nadler, R	1
Kashtan, H	1
Stein, M	1
Harmon, C	1
Robinson, MW	1
Hand, F	1
Almuaili, D	1
Mentor, K	1
Houlihan, DD	1
Hoti, E	1
Lynch, L	1
Geoghegan, J	1
O'Farrelly, C	1
Rai, A	1
Greening, DW	1
Chen, M	1
Xu, R	1
Ji, H	1
Simpson, RJ	1
Wei, Y	1
Xu, H	1
Dai, J	1
Peng, J	1
Xia, L	1
Zhou, F	1
Shi, T	1
Cao, L	1
Zhan, S	1
Xu, Y	2
Fu, F	1
Zhang, G	1
Lu, H	1
Lu, B	1
Chen, W	1
Sun, S	1
Luan, H	1
Gu, J	1
Xiao, Y	1
Shu, D	1
Liang, X	2
Hu, X	1
Xie, Y	1
Lin, D	1
Li, H	1
Silva, C	1
Correia-Branco, A	1
Andrade, N	1
Ferreira, AC	1
Soares, ML	1
Sonveaux, P	3
Stephenne, J	1
Martel, F	1
Straus, DS	1
Li, R	3
Pan, Y	1
He, B	1
Gao, T	1
Song, G	1
Sun, H	1
Deng, Q	1
Wang, S	1
He, X	2
Mishchuk, DO	1
Shah, J	1
Weimer, BC	1
Slupsky, CM	1
Li, L	2
Xiang, D	1
Shigdar, S	1
Yang, W	1
Lin, J	1
Liu, K	1
Duan, W	1
Draoui, N	1
Schicke, O	1
Seront, E	1
Bouzin, C	1
Riant, O	1
Feron, O	2
Fan, R	2
Wang, Y	1
Han, B	1
Luo, Y	1
Zhou, L	2
Peng, X	1
Wu, M	1
Zheng, Y	1
Guo, G	2
Lin, G	1
Hill, DK	1
Andrejeva, G	1
Boult, JK	1
Troy, H	1
Fong, AC	1
Orton, MR	1
Panek, R	1
Parkes, HG	1
Jafar, M	1
Koh, DM	1
Robinson, SP	1
Judson, IR	1
Leach, MO	1
Eykyn, TR	1
Chung, YL	1
Chen, B	1
Liu, Y	1
Jin, X	1
Lu, W	1
Xia, Z	1
Yuan, Q	1
Zhao, X	1
Xu, N	1
Liang, S	1
Zhong, L	1
Covasa, M	1
Abrantes, AM	1
Tavares, LC	1
Pires, S	1
Casalta-Lopes, J	1
Mendes, C	1
Simões, M	1
Grazina, MM	1
Carvalho, RA	1
Botelho, MF	1
Ho, N	1
Coomber, BL	1
Shibuya, N	1
Inoue, K	1
Tanaka, G	1
Akimoto, K	1
Kubota, K	1
Wei, L	2
Zhou, Y	1
Yao, J	1
Qiao, C	1
Ni, T	1
Guo, R	1
Guo, Q	1
Lu, N	1
Kong, W	1
Ping, X	1
Shen, J	1
Yu, B	1
Amorim, R	2
Pinheiro, C	3
Miranda-Gonçalves, V	1
Pereira, H	1
Moyer, MP	1
Preto, A	2
Baltazar, F	3
Du, Y	1
Zhang, Q	1
Jing, L	1
Chi, C	1
Dai, Z	1
Tian, J	1
Wang, H	1
Liu, A	1
Fang, C	1
Hao, J	1
Qiu, Z	1
Guo, W	1
Wang, Q	1
Chen, Z	1
Huang, S	1
Zhao, F	1
Yao, M	1
Zhao, Y	1
Xu, X	1
Chu, D	1
Yang, G	1
Liu, X	1
Yao, L	1
Zhang, J	1
Shen, L	1
Essa, S	1
Daoud, J	1
Lafleur, M	1
Martel, S	1
Tabrizian, M	1
Tong, A	1
Mei, L	1
You, C	1
Wang, QZ	1
Chen, XP	1
Huang, JP	1
Jiang, XW	1
Hyšpler, R	1
Tichá, A	1
Kaška, M	1
Žaloudková, L	1
Plíšková, L	1
Havel, E	1
Zadák, Z	1
Fei, Q	1
Sun, Y	2
Zhu, C	1
Wang, F	1
Alexandrino, H	1
Varela, AT	1
Teodoro, JS	1
Martins, MA	1
Rolo, AP	1
Tralhão, JG	1
Palmeira, CM	1
Castro E Sousa, F	1
Hutton, JE	1
Zimmerman, LJ	1
Slebos, RJ	1
Trenary, IA	1
Young, JD	1
Li, M	1
Liebler, DC	1
Martins, SF	1
Viana-Pereira, M	1
Costa, RF	1
Silva, P	1
Couto, C	1
Alves, S	1
Fernandes, S	1
Vilaça, S	1
Falcão, J	1
Marques, H	1
Pardal, F	1
Rodrigues, M	1
Reis, RM	1
Longatto-Filho, A	2
Ullmann, P	1
Qureshi-Baig, K	1
Rodriguez, F	1
Ginolhac, A	1
Nonnenmacher, Y	1
Ternes, D	1
Weiler, J	1
Gäbler, K	1
Bahlawane, C	1
Hiller, K	1
Haan, S	1
Letellier, E	1
Del Carmen, S	1
de Moreno de LeBlanc, A	1
Levit, R	1
Azevedo, V	1
Langella, P	1
Bermúdez-Humarán, LG	1
LeBlanc, JG	1
Yang, M	1
Hu, J	1
Choi, KC	1
Bang, JY	1
Kim, C	1
Kim, PI	1
Lee, SR	1
Chung, WT	1
Park, WD	1
Park, JS	1
Lee, YS	1
Song, CE	1
Lee, HY	1
Yun, J	1
Rago, C	1
Cheong, I	1
Pagliarini, R	1
Angenendt, P	1
Rajagopalan, H	1
Schmidt, K	1
Willson, JK	1
Markowitz, S	1
Diaz, LA	1
Velculescu, VE	1
Lengauer, C	1
Kinzler, KW	1
Vogelstein, B	1
Papadopoulos, N	1
Madhok, BM	1
Yeluri, S	1
Perry, SL	1
Hughes, TA	1
Jayne, DG	1
Li, JQ	1
Wang, SL	1
Xu, F	1
Liu, ZY	1
Patel, RB	1
Solorio, L	1
Wu, H	1
Krupka, T	1
Exner, AA	1
Kannerup, AS	1
Grønbæk, H	1
Funch-Jensen, P	1
Karlsen, S	1
Mortensen, FV	1
Jensen, SA	1
Hasbak, P	1
Mortensen, J	1
Sørensen, JB	1
Végran, F	1
Boidot, R	1
Michiels, C	1
Nogueira, R	1
Schmitt, F	1
Jiménez, B	1
Mirnezami, R	1
Kinross, J	1
Cloarec, O	1
Keun, HC	1
Holmes, E	1
Goldin, RD	1
Ziprin, P	1
Darzi, A	1
Nicholson, JK	1
Hwang, YH	1
Suh, CK	1
Park, SP	1
Koukourakis, MI	1
Giatromanolaki, A	1
Sivridis, E	1
Hong, X	1
Ye, TH	1
Zhang, XH	1
Ren, HZ	1
Huang, YG	1
Bu, YF	1
Tamulevicius, P	1
Streffer, C	1
Dugas, B	1
Mercenier, A	1
Lenoir-Wijnkoop, I	1
Arnaud, C	1
Dugas, N	1
Postaire, E	1
Lean, CL	1
Mackinnon, WB	1
Delikatny, EJ	1
Whitehead, RH	1
Mountford, CE	1
Rozen, P	1
Fireman, Z	1
Fine, N	1
Wax, Y	1
Ron, E	1