2024
Phosphosulindac (OXT-328) prevents and reverses chemotherapy induced peripheral neuropathy in mice
Basu A, Yang J, Tsirukis V, Loiacono A, Koch G, Khwaja I, Krishnamurthy M, Fazio N, White E, Jha A, Shah S, Takmil C, Bagdas D, Demirer A, Master A, Natke E, Honkanen R, Huang L, Rigas B. Phosphosulindac (OXT-328) prevents and reverses chemotherapy induced peripheral neuropathy in mice. Frontiers In Neuroscience 2024, 17: 1240372. PMID: 38347876, PMCID: PMC10860339, DOI: 10.3389/fnins.2023.1240372.Peer-Reviewed Original ResearchChemotherapy-induced peripheral neuropathyAnticancer effect of paclitaxelEffects of paclitaxelAllodynia scoresCold allodyniaPeripheral neuropathyInduces chemotherapy-induced peripheral neuropathyChemotherapeutic efficacy of paclitaxelLewis lung carcinoma xenograftsPrevent chemotherapy-induced peripheral neuropathyHind paw of miceAnticancer effectsTreat chemotherapy-induced peripheral neuropathyVon Frey testLevels of IL-6Chemotherapy induced peripheral neuropathyEfficacy of paclitaxelPaw of miceLung cancer xenograftsLung carcinoma xenograftsMale C57BL/6 J miceCell linesSide effects of chemotherapyEffects of chemotherapyApparent side effects
2023
Self‐Assembled nanoparticles of natural bioactive molecules enhance the delivery and efficacy of paclitaxel in glioblastoma
Li Y, Zhao Q, Zhu X, Zhou L, Song P, Liu B, Tian D, Chen Q, Zhou J, Deng G. Self‐Assembled nanoparticles of natural bioactive molecules enhance the delivery and efficacy of paclitaxel in glioblastoma. CNS Neuroscience & Therapeutics 2023, 30: e14528. PMID: 38044793, PMCID: PMC11017454, DOI: 10.1111/cns.14528.Peer-Reviewed Original ResearchBlood-brain barrierP-gp inhibitorsCerebral vascular endothelial cellsStrong anti-tumor effectsCommon primary malignant tumorApplication of paclitaxelEfflux transportersPrimary malignant tumorsUse of paclitaxelEfficacy of paclitaxelAnti-tumor effectsPeripheral solid tumorsCentral nervous systemNatural bioactive moleculesEffective anti-cancer drugsP-gp transporterVascular endothelial cellsBlood concentrationsMalignant tumorsGlioma treatmentNervous systemP-gpAnti-cancer drugsSolid tumorsTumor tissue
2022
A precision medicine approach to metabolic therapy for breast cancer in mice
Akingbesote ND, Norman A, Zhu W, Halberstam AA, Zhang X, Foldi J, Lustberg MB, Perry RJ. A precision medicine approach to metabolic therapy for breast cancer in mice. Communications Biology 2022, 5: 478. PMID: 35595952, PMCID: PMC9122928, DOI: 10.1038/s42003-022-03422-9.Peer-Reviewed Original ResearchConceptsPrecision medicine approachBreast cancerSodium-glucose transport protein 2 inhibitorsBreast tumorsMedicine approachCanonical insulinSGLT2 inhibitor dapagliflozinEfficacy of paclitaxelBreast tumor-bearing miceTumor glucose uptakeTumor-bearing miceChemotherapy correlatesNeoadjuvant approachNeoadjuvant settingPaclitaxel chemotherapyInhibitor dapagliflozinSGLT2 inhibitorsProlonging survivalAntihyperglycemic drugsPotential adjuvantMetabolic therapyDapagliflozinTumorsDriver mutationsGlucose uptake
2018
An assessment of neuronal calcium sensor-1 and response to neoadjuvant chemotherapy in breast cancer patients
Moore LM, Wilkinson R, Altan M, Toki M, Carvajal-Hausdorf DE, McGuire J, Ehrlich BE, Rimm DL. An assessment of neuronal calcium sensor-1 and response to neoadjuvant chemotherapy in breast cancer patients. Npj Breast Cancer 2018, 4: 6. PMID: 29560416, PMCID: PMC5847580, DOI: 10.1038/s41523-018-0057-7.Peer-Reviewed Original ResearchTaxane-based neoadjuvant chemotherapyPathological complete responseNeuronal calcium sensor-1Neoadjuvant chemotherapyNCS-1 expressionBreast cancer patientsPoor clinical outcomeEfficacy of paclitaxelBreast cancer biopsiesComplete responseClinical outcomesCancer patientsPredictive biomarkersBreast cancerCancer biopsiesChemotherapyElevated expressionPaclitaxelPrevious studiesResponseBiopsyPatientsExpressionTaxanesCancer
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