Yeni Floresans Özellikli Çapraz Bağlı Polifosfazen Mikrokürelerin Sentezi ve Karakterizasyonu

Siklomatriks yapılı net-poli(siklotetrafosfazen-ko-tiramin) mikroküreler çöktürme polimerizasyonu iletek adımda sentezlenmiştir. Elde dilen mikrokürelerin karakterizasyonu SEM, EDX, FTIR, XRD ve DLSteknikleri ile yapılmıştır. Ayrıca mikrokürelerin UV ve floresans özellikleri de incelenmiş olup,mikrokürelerin 239 nm’de maksimum absorbans yaptığı belirlenmiştir. Tiramin ve mikrokürelerin katıhal floresans özellikleri, 254 nm dalga boyunda uyarılarak incelenmiştir. Tiramin çok zayıf emisyonyaparken, mikroküreler 308 nm’de şiddetli emisyon göstermiştir. Elde edilen sonuçlar, sentezlenenpolifosfazen mikrokürelerin sensör, biyolojik kataliz ve görüntüleme gibi floresans uygulamalar içinyüksek potansiyele sahip olduğunu göstermektedir.

Synthesis and Characterization of Novel Fluorescent Cross-Linked Polyphosphazene Microspheres

Cyclomatrix structured net-poly(cyclotetraphosphazene-co-tyramine) microspheres were synthesized by single step precipitation polymerization. The characterization of obtained microspheres were performed by SEM, EDX, FTIR, XRD and DLS techniques. Besides, UV and fluorescence properties of microspheres were researched and it was determined that microspheres have been shown maximum absorption at 239 nm. It was investigated the fluorescence characteristics of tyramine and microspheres as solid state, using 254 nm as the excitation wavelength. The microspheres showed a strong emission peak at 308 nm, whereas the emission peak of the tyramine was very weak. The obtained results show that the synthesized polyphosphazene microspheres have a high potential for fluorescent sensor, biological catalysis and imaging applications etc.

PDF

___

Abbas, Y., Zuhra, Z., Basharat, M., Qiu, M., Wu, Z., Wu, D. and Ali, S., 2019. Morphology control of novel crosslinked ferrocenedimethanol derivative cyclophosphazenes: from microspheres to nanotubes and their enhanced physicochemical performances. The Journal of Pysical Chemistry B., 123, 4148−4156.
Basharat, M., Liu, W., Zhang, S., Abbas, Y., Wu, Z. and Wu, D., 2019. Poly(cyclotriphosphazene-co-tris(4- hydroxyphenyl)ethane) microspheres with intrinsic excitation wavelength tunable multicolor photoluminescence. Macromolecular Chemistry and Physics, 220, 1900256-1900264.
Berberoğlu, İ., Asmafiliz, N., Kılıç, Z., Hökelek, T., Koç, L. Y., Açık, L., Türk, M., Soltanzade, H. and Dal, H., 2016. Phosphorus nitrogen compounds: Part 34. Syntheses, structural investigations, cytotoxic and biological activities of spiro-ansa-spiro and spiro-bino-spiro tetrameric phosphazene derivatives. Inorganica Chimica Acta, 446, 75-86.
Bi, B., Liu, H., Kang, W., Zhuo, R. and Jiang, X., 2019. An injectable enzymatically crosslinked tyraminemodified carboxymethyl chitin hydrogel for biomedical applications. Colloids and Surfaces B: Biointerfaces, 175, 614–624.
Chen, K., Liu, Y., Hu, Y., Yuan, M., Zheng, X., Huang, X., 2020. Facile synthesis of amino-functionalized polyphosphazene microspheres and their application for highly sensitive fluorescence detection of Fe3+ . Journal of Applied Polymer Science, 137, 48937- 48945.
Elmas, G., Okumuş, A., Cemaloğlu, R., Kılıç, Z., Çelik, S. P., Açık, L., Tunalı, B. Ç., Türk, M., Çerçi, N. A., Güzel, R. and Hökelek, T., 2017. Phosphorus-nitrogen compounds. part 38. Syntheses, characterizations, cytotoxic, antituberculosis and antimicrobial activities and DNA interactions of spirocyclotetraphosphazenes with bis-ferrocenyl pendant arms. Journal of Organometallic Chemistry, 853, 93-106.
Fu, J., Wang, M., Zhang, C., Zhang, P. and Xu, Q., 2012. High hydrogen storage capacity of heteroatomcontaining porous carbon nanospheres produced from cross-linked polyphosphazene nanospheres. Materials Letters, 81, 215–218.
Fu, J., Wang, S., Zhu, J., Wang, K., Gao, M., Wang, X. and Xu, Q., 2018. Au-Ag bimetallic nanoparticles decorated multi-amino cyclophosphazene hybrid microspheres as enhanced activity catalysts for the reduction of 4-nitrophenol. Materials Chemistry and Physics, 207, 315-324.
Hong, S., Li, J., Huang, X. and Liu, H., 2018. A facile approach to generate cross-linked poly (cyclotriphosphazeneco-oxyresveratrol) nanoparticle with intrinsically fluorescence. Journal of Inorganic and Organometallic Polymers and Materials, 28, 2258–2263.
Hou, S., Chen, S., Dong, Y., Gao, S., Zhu, B. and Lu, Q., 2018. Biodegradable cyclomatrix polyphosphazene nanoparticles: a novel ph-responsive drug self-framed delivery system. ACS Applied Materials & Interfaces, 10, 25983-25993.
Jiang, Z., Xie, F., Kang, C., Wang, Y., Yuan, L. and Wang, Y., 2019. Adsorption of thorium(IV) from aqueous solutions by poly (cyclotriphosphazene‑co‑4,4′‑diaminodiphenyl ether) microspheres. Journal of Radioanalytical and Nuclear Chemistry, 321, 895–905.
Kripotou, S., Stefanopoulou, E., Culebras-Martínez, M., Morales-Románb, R. M., Ferrer, G. G. and Kyritsis, A., 2019. Water dynamics and thermal properties of tyramine-modified hyaluronic acid - gelatin hydrogels. Polymer, 178, 121598-121611.
Lee, F., Chung, J. E. and Kurisawa, M., 2009. An injectable hyaluronic acid–tyramine hydrogel system for protein delivery. Journal of Controlled Release, 134, 186–193.
Liu, W., Huang, X., Wei, H., Tang, X. and Zhu, Lu., 2011. Intrinsically fluorescent nanoparticles with excellent stability based on a highly crosslinked organic– inorganic hybrid polyphosphazene material. Chemical Communications, 47, 11447–11449.
Malkappa, K. and Ray, S.S., 2019. Thermal stability, pyrolysis behavior, and fire-retardant performance of melamine cyanurate@poly(cyclotriphosphazene-co4,4′-sulfonyl diphenol) hybrid nanosheet-containing polyamide 6 composites. ACS Omega, 4, 9615−9628.
Meng, L., Xu, C., Liu, T., Li, H., Lu, Q. and Long, J., 2015. One-pot synthesis of highly cross-linked fluorescent polyphosphazene nanoparticles for cell imaging. Polymer Chemistry, 6, 3155–3163.
Metinoğlu Örüm, S. and Süzen Demircioğlu, Y., 2019. One-pot synthesis and characterization of crosslinked polyphosphazene dopamine microspheres for controlled drug delivery applications. Journal of Macromolecular Science, Part A Pure and Applied Chemistry, 56, 854–859.
Pan, T., Huang, X., Wei, H., Wei, W. and Tang X., 2012. Intrinsically fluorescent microspheres with superior thermal stability and broad ultraviolet-visible absorption based on hybrid polyphosphazene material. Macromolecular Chemistry and Physics, 213, 1590−1595.
Raman, N., Sobha, S. and Mitu, L., 2012. Synthesis, structure elucidation, DNA interaction, biological evaluation, and molecular docking of an isatinderived tyramine bidentate Schiff base and its metal complexes. Monatshefte fuer Chemie, 143:1019– 1030.
Raman, N., Sobha, S. and Thamaraichelvan, A., 2011. A novel bioactive tyramine derived Schiff base and its transition metal complexes as selective DNA binding agents. Spectrochimica Acta Part A, 78, 888–898.
Sakai, S. and Kawakami K., 2008. Both ionically and enzymatically crosslinkable alginate–tyramine conjugate as materials for cell encapsulation. Journal of Biomedical Materials Research Part A, 85A:2, 345- 351.
Qiu, S., Xing, W., Feng, X., Yu, B., Mu, X., Yuen, R.K.K. and Hu, Y., 2017. Self-standing cuprous oxide nanoparticles on silica@polyphosphazene nanospheres: 3D nanostructure for enhancing the flame retardancy and toxic effluents elimination of epoxy resins via synergistic catalytic effect. Chemical Engineering Journal, 309, 802–814.
Siddiqui, H., Bashir, M. A., Javaid, K., Nizamani, A., Bano, H., Yousuf, S., Rahman, A. and Choudhary, M. I., 2016. Ultrasonic synthesis of tyramine derivatives as novel inhibitors of a-glucosidase in vitro. Journal of Enzyme Inhibition and Medicinal Chemistry, 31, 1392–1403.
Sun, L., Liu, T., Li, H., Yang, L., Meng, L., Lu, Q. and Long, J., 2015. Fluorescent and cross-linked organic−inorganic hybrid nanoshells for monitoring drug delivery. ACS Applied Materials Interfaces, 7, 4990−4997.
Süzen, Y. and Metinoğlu Örüm, S., 2017. Novel cyclomatrix-type polyphosphazene microspheres crosslinked with octachlorocyclotetraphosphazene: preparation and characterization. Anadolu University Journal of Science and Technology A- Applied Sciences and Engineering, 18, 973 – 987.
Tang, X.Z. and Huang, X.B., 2017. Modern Inorganic Synthetic Chemistry. Ruren Xu and Yan Xu, Elsevier, 279-306.
Wan, C. and Huang, X., 2017. Cyclomatrix polyphosphazenes frameworks (Cyclo-POPs) and therelated nanomaterials: Synthesis, assembly and functionalisation. Materials Today Communications, 11, 38–60.
Wang, D., Hu, Y., Meng, L., Wang, X. and Lub, Q., 2015. One-pot synthesis of fluorescent and cross-linked polyphosphazene nanoparticles for highly sensitive and selective detection of dopamine in body fluids. RSC Advances, 5, 92762–92768.
Wang, Y., Mu, J., Li, L., Shi, L., Zhang, W. and Jiang, Z., 2012. Preparation and properties of novel fluorinated cross-linked polyphosphazene micro-nano spheres. High Performance Polymers, 24, 229–236.
Wei, X., Chen, H., Tham, H. P., Zhang, N., Xing, P., Zhang, G. and Zhao, Y., 2018. Combined photodynamic and photothermal therapy using cross-linked polyphosphazene nanospheres decorated with gold nanoparticles. ACS Applied Nano Materials, 7, 3663- 3672.
Wei, X., Zhang, G., Zhou, L. and Li, J., 2017. Synthesis and characterization of hydrophobic amino-based polyphosphazene microspheres with different morphologies via two strategies. Applied Surface Science, 419, 744–752.
Wei, W., Lu, R., Xie, H., Zhang, Y., Bai, X., Gu, L., Da, R. and Liu, X., 2015. Selective adsorption and separation of dyes from an aqueous solution on organic–inorganic hybrid cyclomatrix polyphosphazene submicrospheres. Journal of Materials Chemistry A, 3, 4314– 4322.
Yenilmez Çiftçi, G., Şenkuytu, E., İncir, S.E., Yuksel F., Ölçer Z., Yıldırım, T., Kılıç, A., and Uludağ, Y., 2016. First paraben substituted cyclotetraphosphazene compounds and DNA interaction analysis with a new automated biosensor. Biosensors and Bioelectronics, 80, 331–338.
Zhang, H., Lu, Y., Wu, S., Wei, Y., Liu, Q., Liu, J. and Jiao, Q., 2016. Two-step enzymatic synthesis of tyramine from raw pyruvatefermentation broth. Journal of Molecular Catalysis B: Enzymatic, 124, 38–44.