Email: jitnapasirirak@gmail.com, sirirak_j@silpakorn.edu

Room: 4210/4 Science Building 4

Tel.: 034-109686 ext. 207316

Website: -

Education:

Ph.D. (Chemistry) University of Bristol, UK

MSci (Chemistry) University of Bristol, UK

Research Interest:

Molecular modelling, Natural dye and Lake pigment

Publications:

• Oekchuae, S., Sirirak, J., Charoensuksai, P., Wongprayoon, P., Chuaypen, N., Boonsombat, J., Ruchirawat, S., Tangkijvanich, P., Suksamrarn, A., Limpachayaporn, P. (2022). “The Design and Synthesis of a New Series of 1,2,3-Triazole-Cored Structures Tethering Aryl Urea and Their Highly Selective Cytotoxicity toward HepG2.” Pharmaceuticals, 15: 504. (Scopus)

• Limpachayaporn, P., Nuchpun, S., Sirirak,, Charoensuksai, P., Wongprayoon, P., Chuaypen, N., Tangkijvanich, P., Suksamrarn, A. (2022). “meta-Ureidophenoxy-1,2,3-triazole hybrid as a novel scaffold for promising HepG2 hepatocellular carcinoma inhibitors: Synthesis, biological evaluation and molecular docking studies.” Bioorganic & Medicinal Chemistry, 74: 117048. (ISI)

• Vicharn, S., Sirirak, J., Phutdhawong, W., Taechowisan, T., Phutdhawong, W.S. (2022). “Synthesis of 2-substituted indoles and evaluation of their antibacterial activity and inhibitory effects on the efflux pump of methicillin-resistant Staphylococcus aureu.s” Journal of Applied Pharmaceutical Science, 12, 1: 084-093. (Scopus)

• Petdum A., Kaewnok N., Panchan W., Charoenpanich A., Sirirak J., Sahasithiwat S., Sooksimuang T., Wanichacheva N. (2022). “Novel rapid “turn on” tetrahydro-[5]helicene-based fluorescence sensor for selective detection of Cd2+ with a remarkable large Stokes shift and its applications in food samples and living cell.” Journal of Photochemistry and Photobiology A: Chemistry, 423: 113578. (ISI, SCOPUS)

• Keeratichamroen S., Lirdprapamongkol K., Thongnest S., Boonsombat J., Chawengrum P., Sornprachum T., Sirirak, J., Verathamjamras C., Ornnork N., Ruchirawat S., Svasti J. (2022). “JAK2/STAT3-mediated dose-dependent cytostatic and cytotoxic effects of sesquiterpene lactones from Gymnanthemum extensum on A549 human lung carcinoma cells.” Oncology Reports, 47(1): 1-11. (SCOPUS)

• Leerawatthanakun S., Charoenwongpaiboon T., Klaewkla M., Chunsrivirot S., Sirirak, J., Sriwitool T.-E., Wangpaiboon K., Pichyangkura R. (2022). “High surfactant-tolerant β-mannanase isolated from Dynastes hercules larvae excrement, and identification of its hotspot using site-directed mutagenesis and molecular dynamics simulations.” Enzyme and Microbial Technology, 154: 109956.

• Chuenbarn T., Sirirak, J., Tuntarawongsa S., Okonogi S., Phaechamud, T. (2022). “Design and Comparative Evaluation of Vancomycin HCl-Loaded Rosin-Based In Situ Forming Gel and Microparticles.” Gels, 8(4): 231. (Scopus)

• Petdum, A., Sirirak, J., Lee, V. S., Nienaber, H. A., Panchan, W., Sooksimuang, T., Wanichacheva, N. (2020). “New [5]helicene derivatives with large stokes shifts for Hg²⁺ determination and their application in drinking water, river water and tuna fillet.” Science, Engineering and Health Studies, 14(1): 32-46.

• Sirirak, , Worawannotai, N., Suwanchawalit, C., Chayabutra, S. (2020). “Preparation and characterization of lake pigments from sappan wood using Thai local clays.” Journal of Metals, Materials and Minerals, 30(1): 20-28.

• Sasiwimon, K., Panchan, W., Charoenpanich, A., Sirirak, , Sahasithiwat, S., Swanglap, P., Promarak, V., Panchan, W., Charoenpanich, A., Sirirak, J., Sahasithiwat, S., Swanglap, P., Promarak, V., Thamyongkit, P., Wanichacheva, N. (2020) “A method to detect Hg²⁺ in vegetable via a “Turn–ON” Hg²⁺–Fluorescent sensor with a nanomolar sensitivity.” Journal of Photochemistry and Photobiology A: Chemistry, 389: 112224.

• Petdum, A., Faichu, N., Sirirak, , Khammultri, P., Promarak, V., Panchan, W., Sooksimuang, T., Charoenpanich, A., Wanichacheva, N. (2020). “[5]Helicene-rhodamine 6 G hybrid-based sensor for ultrasensitive Hg2+ detection and its biological applications.” Journal of Photochemistry and Photobiology A: Chemistry, 394: 112473.

• Petdum, A., Waraeksiri, N., Hanmeng, O., Jarutikorn, S., Chaneam, S., Sirirak, , Charoenpanich, A., Panchan, W., Sooksimuang, T., Wanichacheva, N., (2020). “A new water-soluble Fe³⁺ fluorescence sensor with a large Stokes shift based on [5]helicene derivative: Its application in flow injection analysis and biological systems.”  Journal of Photochemistry and Photobiology A: Chemistry, 401: 112769.

• Hanmeng, O., Chailek, N., Charoenpanich, A., Phuekvilai, P., Yookongkaew, N., Sanmanee, N., Sirirak, , Swanglap, P., Wanichacheva, N. (2020). “Cu²⁺-selective NIR fluorescence sensor based on heptamethine cyanine in aqueous media and its application.” Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 240: 118606.

• ชณิภรณ์ วดีศิริศักดิ์, สุพรรณี ฉายะบุตร และจิตนภา ศิริรักษ์, (2563). “ผลของสายพันธุ์และวิธีการเตรียมใบมะม่วงที่มีต่อผงสีธรรมชาติจากใบมะม่วงที่ตรียมด้วยวิธีการดูดซับ.” วารสารวิทยาศาสตร์บูรพา, 25(2): 545-562.

• พลอยพัทธ์ ศุภรัตน์ธัญญา, ภานุพันธ์ ลิมปชยาพร, สุมนมาลย์ จันทร์เอี่ยม, สุพรรณี ฉายะบุตร และจิตนภา ศิริรักษ์ (2562). “การศึกษาจลนศาสตร์และไอโซเทอมของการดูดซับบราซิลีนจากฝางด้วยมอนต์มอริลโลไนท์.” วารสารวิทยาศาสตร์และเทคโนโลยี มหาวิทยาลัยธรรมศาสตร์, 27(6): 989-1001.

• Praikaew, P., Maniam, S., Charoenpanich, A., Sirirak, J., Promarak, V., Langford, S.J. and Wanichacheva, N. (2019). “Water-soluble Cu2+- fluorescent sensor based on core-substituted naphthalene diimide and its application in drinking water analysis and live cell imaging.” Journal of Photochemistry and Photobiology A: Chemistry, 382(1): 111852.

• Petdum, A., Sooksimuang, T., Wanichacheva, N., Sirirak, J. (2019). “Natural colorimetric sensor from sappanwood for turn–on selective Fe2+ detection in aqueous media and its application in water and pharmaceutical samples.” Chemistry Letters, 48(7): 678-681. (ISI/SCOPUS)

• Piyanuch, P., Sirirak, J., Kamkaew, A., Weeranantanapa, O., Promarak, V., Burgess, K., Wanichacheva, N. (2019). “Near‐Infrared fluorescence chemosensor based on isothiocyanate‐aza‐BODIPY for cyanide detection in ppb level: Applications in buffer media and living cell imaging.” ChemPlusChem, 84(3): 252-259 (ISI/SCOPUS)

• Rattanopas, S., Piyanuch, P., Wisansin, K., Charoenpanich, A., Sirirak, J., Phutdhawong, W.S., Wanichacheva, N. (2019). “Indole-based fluorescent sensors for selective sensing of Fe²⁺ and Fe³⁺ in aqueous buffer systems and their applications in living cells.” Journal of Photochemistry and Photobiology A-Chemistry, 377: 138-148 (ISI/SCOPUS)

• Jarutikorn, S., Kraithong, S., Sirirak, J., Panchan, W., Sooksimuang, T., Charoenpanich, A. Wanichacheva, N. (2019). “Environmentally Friendly Ag+ Detection of “Turn-on” Fluorescent Sensor with a Mega-Stokes Shift and Its Application in Biological Systems.” Oriental Journal of Chemistry, 35(3): 1227-1234. (ISI)

• Phutdhawong, W., Rattanopas, S., Sirirak, J., Taechowisan, T., Phutdhawong, W.S. (2019). “Synthesis and Anticancer Activity Evaluation of Azepinobisindoles; The Isomeric Iheyamine A-derivatives.” Oriental Journal of Chemistry, 35(2): 723-731. (ISI)

• Sukaram, T., Sirisakwisut, P., Sirirak, J., Nacapricha, D., Chaneam, S. (2018). “Environmentally friendly method for determination of ammonia nitrogen in fertilisers and wastewaters based on flow injection-spectrophotometric detection using natural reagent from orchid flower.” International Journal of Environmental Analytical Chemistry, 98: 907-920.

• Sutinee Girdthep, Sirirak, J., Donraporn Daranarong, Rathawat Daengngern, Supanee Chayabutra. (2018). “Physico-chemical characterization of natural lake pigments obtained from Caesalpinia Sappan Linn. and their composite films for poly (lactic acid)-based packaging materials.” Dyes and Pigments, 157: 27-39.

• Kraithong, S., Sangsuwan, R., Worawannotai, N., Sirirak, J., Charoenpanich, A., Thamyongkit, P., Wanichacheva, N. (2018). “Triple detection modes for Hg2+sensing based on NBD-fluorescent and colorimetric sensor and its potential in cell imaging.” New Journal of Chemistry, 42: 13180-13180.

• Sakunkaewkasem, S., Petdum , A., Waraporn Panchan, Sirirak, J., Charoenpanich, A., Sooksimuang, T., Wanichacheva., (2018). “Dual-analyte fluorescent sensor based on [5]helicene derivative with super large stokes shift for the selective determinations of Cu²⁺ or Zn²⁺ in Buffer Solutions and Its Application in Living Cell.” ACS Sensors, 3 (5): 1016–1023.

• Kaewnok, N., Petdum, A., Sirirak, J., Charoenpanich, A., Panchan, W., Sahasithiwat, S., Sooksimuangc, T., Wanichacheva, N. (2018). “Novel Cu2+-specific ‘‘Turn-ON’’ fluorescent probe based on [5]helicene with very large Stokes shift and its potential application in living cells.” New Journal of Chemistry., 42: 5540.

• Kraitong, S., Sirirak, J., Soisuwan, K., Wanichacheva, N., Swanglap, P. (2018). “Enhancing sensitivity of novel Hg²⁺ fluorescent sensor via plasmonic enhancement of silver nanoparticles.” Sensors and Actuators, B: Chemical, 258: 694-703.

• Petdum, A., Panchan, W., Swanglap, P., Sirirak, J., Sooksimuang, T., Wanichacheva, N. (2018). “"Turn-ON" [5]helicene-based fluorescence sensor with very large Stokes shift for highly selective detection of Ag⁺ and AgNPs.” Sensors and Actuators, B: Chemical, 259: 862 - 870.

• Puangsamlee, T., Tachapermpon, Y., Kammalun, P., Sukrat, K., Wainiphithapong, C., Sirirak, J., Wanichacheva, N. (2018). “Solvent control bifunctional fluorescence probe for selective detection of Cu²⁺ and Hg²⁺ via the excimer of pyrenylacetamide subunits.” Journal of Luminescence, 196: 227 – 235.

• Petdum, A., Panchan, W., Sirirak, J., Promarak, V., Sooksimuang, T., Wanichacheva, N. (2017). “Colorimetric and fluorescent sensing of a new FRET system via [5]helicene and rhodamine 6G for Hg²⁺” Dalton Trans., 46: 16251–16256.

• Tachapermpon, Y., Thavornpradit, S., Charoenpanich, A., Sirirak, J., Burgess, K., Wanichacheva, N. (2017). “Near-infrared aza-BODIPY fluorescent probe for selective Cu²⁺ detection and its potential in living cell imaging.” Dalton Trans., 46: 16251.

• Sirirak, J., Sertphon, D., Phonsri, W., Harding, P., Harding, D. J. (2017). “Comparison of density functionals for the study of the high spin low spin gap in Fe(III) spin crossover complexes” Int J Quantum Chem., 117(9), e25362.

• Tachapermpon, Y., Chaneam, S., Charoenpanich, A., Sirirak, J., Wanichacheva, N. (2017). “Highly Cu2+-sensitive and selective colorimetric and fluorescent probes: Utilizations in batch, flow analysis and living cell imaging.” Sensors and Actuators B: Chemical, 241: 868-878.

• Kraithong, S., Damrongsak, P., Suwatpipat, K., Sirirak, J., Swanglap, P., Wanichacheva. N. (2016). “Highly Hg²⁺-sensitive and selective fluorescent sensors in aqueous solution and sensors-encapsulated polymeric membrane.” RSC Adv., 6: 10401-10411

• Thavornpradit, S., Sirirak, J., Wanichacheva, N. (2016). “Turn-on naphthalimide fluorescent sensor with high quantum yield and large Stokes shift for the determination of Cu(II).” J Photochem Photobiol A Chem., 330: 55-63

• , Insiti, Jitthiang, P., Harding, P., Chainok, K., Chotima, R., Sirirak, J., Blackwood, S., Alkaş, A., Telfer, S. G., Harding, D. J. (2016). “Substituent modulated packing in octahedral Ni(II) complexes.” Polyhedron, 114: 242-248

• Sirirak, J., Harding, D. J., Harding, P., Murray, K. S., Moubaraki, B., Liu, L., Telfer, S. G. (2015). “Spin Crossover in cis Manganese (III) Quinolylsalicylaldiminates.” Eur. J. Inor. Chem., 15, 2534-2542.

• Harding, D. J., Phonsri, W., Harding, P., Sirirak, J., Tangtirungrotechai, Y., Webster, R. D., Adams, H. (2014). “Copper hydrotris(3,5-diphenylpyrazolyl)borate dithiocarbamates: attempting to model azurin” New J. Chem., 39: 1489.

• Sirirak, J., Harding, D. J., Harding, P., Liu, L., Telfer, S. G. (2014). “Solvatomorphism and electronic communication in FeIII N,N-bis(salicylidene)-1,3-propanediamine dimers.” Aus. J. Chem., 68(5): 766-773.

• Kamp, M. W. v. d., Sirirak, J., Żurek, J., Allemann. R. K., Mulholland, A. J. (2013). “Conformational Change and Ligand Binding in the Aristolochene Synthase Catalytic Cycle.” Biochemistry, 52: 8094.

• Chudyk, E., Kazimierowicz, E. D., Langner, K. M., Sokalski, W. A., Lodola, A., Mor, M., Sirirak, J., Mulholland, A. J. (2013). “Nonempirical energetic analysis of reactivity and covalent inhibition of fatty acid amide hydrolase.” J. Phys.Chem. B, 117(22): 6656.

• Sirirak, J., Phonsri, W., Harding, D. J., Harding, P., Phommon, P., Chaoprasa, W., Hendry, R. M., Roseveare, T. M., Adams, H. (2013). “Halogen substituted quinolylsalicylaldimines: Four halogens three structural types.” J. Mol. Struct., 1036: 439.