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PARMESWARAN DIAGARADJANE

TitleAssistant Professor
InstitutionMD Anderson
DepartmentExperimental Radiation Oncology
Address1515 Holcombe Blvd
Houston TX 77030-4009
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    Publications listed below are automatically derived from MEDLINE/PubMed and other sources, which might result in incorrect or missing publications. Faculty can login to make corrections and additions.
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    PMC Citations indicate the number of times the publication was cited by articles in PubMed Central, and the Altmetric score represents citations in news articles and social media. (Note that publications are often cited in additional ways that are not shown here.) Fields are based on how the National Library of Medicine (NLM) classifies the publication's journal and might not represent the specific topic of the publication. Translation tags are based on the publication type and the MeSH terms NLM assigns to the publication. Some publications (especially newer ones and publications not in PubMed) might not yet be assigned Field or Translation tags.) Click a Field or Translation tag to filter the publications.
    1. Parmeswaran D, Pushpan SK, Srinivasan A, Ravi Kumar M, Chandrashekar TK, Ganesan S. In vitro and in vivo investigations on the photodynamic activity of core-modified expanded porphyrin--ammonium salt of 5,10,15,20-tetrakis-(meso-p-sulfonato phenyl)-25,27,29-trithia sapphyrin. Photochem Photobiol. 2003 Nov; 78(5):487-95. PMID: 14653581.
      Citations: 2     Fields:    
    2. Diagaradjane P, Madhuri S, Aruna P, Gupta PK, Ganesan S. In vivo pharmacokinetics of 8-aminolevulinic acid-induced protoporphyrin IX during pre- and post-photodynamic therapy in 7,12-dimethylbenz(a)nthracene-treated skin carcinogenesis in Swiss mice: a comparison by three-compartment model. Photochem Photobiol. 2002 Jul; 76(1):81-90. PMID: 12126311.
      Citations:    Fields:    Translation:Animals
    3. Pushpan SK, Venkatraman S, Anand VG, Sankar J, Parmeswaran D, Ganesan S, Chandrashekar TK. Porphyrins in photodynamic therapy - a search for ideal photosensitizers. Curr Med Chem Anticancer Agents. 2002 Mar; 2(2):187-207. PMID: 12678743.
      Citations: 31     Fields:    Translation:HumansAnimals
    4. Native cellular fluorescence characteristics of normal and malignant epithelial cells from human larynx. 759-764.
    5. Photothermal and photochemical effects of laser light absorption by Indocyanine Green (ICG). 27-35.
    6. Photodynamic activity on human erythrocytes by a newly synthesized sensitizer - trithia sapphyrin sulfonate. 94-100.
    7. In-vivo pharmacokinetics of δ-ALA induced PPIX during photodynamic therapy on mice tumor model. 128-133.
    8. Narrow band imaging of tumors using gold nanoshells.
    9. Autofluorescence characterization of DMBA-TPA induced two-stage carcinogenesis in mouse skin for the early detection of tissue transformation. 41-50.
    10. Two-photon-induced photoluminescence imaging of gold nanoshell's tumor biodistribution.
    11. EGF-conjugated Near-infrared quantum dots as nanoprobes for in-vivo imaging of EGFR expression.
    12. Theranostic Applications of Gold Nanoparticles in Cancer. 639-657.
    13. miR-141-mediated regulation of brain metastasis from breast cancer. Journal of the National Cancer Institute. 108.
    14. Quantitative imaging of gold nanoparticle distribution in a tumor-bearing mouse using benchtop x-ray fluorescence computed tomography. Scientific Reports. 6.
    15. Comparison of PDT efficiencies for photooxidation of substrate (NADPH) using a photosensitizer (Photofrin II). 97-103.
    16. Native fluorescence characteristics of blood plasma during rat liver regeneration. 15-19.
    17. Curcumin sensitizes human colorectal cancer to capecitabine by modulation of cyclin D1, COX-2, MMP-9, VEGF and CXCR4 expression in an orthotopic mouse model (International Journal of Cancer (2009) 125, (2187-2197)). International Journal of Cancer. 126:799.
    18. Convergence of nanotechnology with radiation therapy-insights and implications for clinical translation. Translational Cancer Research. 2:256-268.
    19. Measuring gold nanoparticle concentrations in tissue using diffuse optical spectroscopy.
    20. Gold nanoshell mediated hyperthermia enhances the efficacy of radiation therapy.
    21. In vivo detection of gold nanoshells in tumors using diffuse optical spectroscopy. IEEE Journal on Selected Topics in Quantum Electronics. 13:1715-1720.
    22. Microscopy of gold nanoshells in tumors using two-photon induced photoluminescence. 71-72.
    23. Comparison of bond strength and surface morphology of dental enamel for acid and Nd-YAG laser etching. 86-90.
    24. Measuring gold nanoparticle concentrations in tissue using diffuse optical spectroscopy.
    25. Erratum. IEEE Journal on Selected Topics in Quantum Electronics. 14:251.
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