AUTHOR(S):

Likhtenshtein Gertz I

TITLE

Nitroxides in Cotton and Cellulose Physicochemistry and Technology. 42 Years of History

ABSTRACT

Since pioneering works of Marupov and Likhtenshtein groups, nitroxides are widely used in solving a number of challenging problems of structure and functions of cotton fibres and cellulose. Methods of nitroxide spin labelling have been proved to be a powerful tool in this area. Covalent modification cotton fibres and cellulose by the labels and the use electron Spin Resonance (ESR) allow to establish the label location and motion the labelled samples which in turn is modulated ’by the polymers local molecular dynamics and its distribution. Data on dependencies of the fibres’ molecular dynamics on origin, temperature, water and other plasticizing agents, nutrition, period of maturing, virus infection and radiation of seeds have been presented. Combination of ESR experiments and Zhurkov technique have revealed a strong dependence of fibres’ resistance to stress (durability) on microscopic structural defects. In the fibres, the distribution of the molecular dynamics correlation time within 10-4 – 10-9 s temporal range was also established. Employing non-covalently bound nitroxides as spin probes provides a way for studies of effect of humidity on the supramolecular structure of cotton, local polarity and heterogeneous viscosity of two types of unprocessed cotton fibers, cellulose modification by nitroxide-mediated graft polymerization, composites of poly(lactic) acid reinforced with TEMPO-oxidized fibrillated cellulose, photo-lnduced macromolecular functionalization of cellulose via nitroxide spin trapping. The developed approach, the efficiency of which is demonstrated in this review, can be used in the investigation of molecular dynamics, microstructure polymers and other complex molecular objects.

KEYWORDS

cotton fibres, cellulose, nitroxide spin labels, luminescence labels, molecular dynamics, structural defects, stress resistance

REFERENCES

[1]. Gordon S, Hsieh YL. Cotton Science and Technology. 1st Edition. Woodhead Publishing, 2007.

[2]. Marupov R. M., Bobodzhanov P. Kh., Kostina N. V., Shapiro A. B. Spin label study of the structure and conformational properties of cotton filament grown from γ-irradiated seeds. Biofizika. 21, 825-828 (1976)..

[3]. Marupov R, Bobodzhanov P. Kh., Yusupov I. Kh., Frolov E. N.. Likhtenshtein G. I. Study of temperature stability of cotton fibers by spin labeling. Biofizika 24. 519-523 (1979).

[4]. Likhtenshtein GI. .Spin Labeling Method in Molecular Biology, N. Y., Wiley Interscience, New York, 1976

[5]. Likhtenshtein, G.I. Biophysical Labeling Methods in Molecular Biology,.Cambridge, New York,.Cambridge University Press, 1993.

[6]. Likhtenshtein G.I., Yamauchi J, Nakatsuji S, Smirnov A., Tamura R.Nitroxides: Application in Chemistry, Biomedicine, and Materials Science. WILEY-VCH, Weinhem , 2008.

[7]. Berliner L. (Ed.) Spin Labeling. The Next Millennium Academic Press, New York, 1998.

[8]. Kokorin A.I. (editor)(2012) Nitroxides - Theory, Experiment and Applications. InTech, 2012.

[9]. Likhtenshtein GI. (2016) Electron Spin in Chemistry and Biology: Fundamentals, Methods, Reactions Mechanisms, Magnetic Phenomena, Structure Investigation. Springer, 2016.

[10]. Marupov R, Yusupov I. Kh., Bobodzhanov P. Kh., Kol'tover V. K. Likhtenshtein G. I. Study of the molecular dynamics of cotton fibers by spin labeling. Doklady Akademii Nauk SSSR 256, 414-417 (1981).

[11]. Bobodjanov P.Kh. Yusupov I.Kh., Marupov P, Study of molecular dynamics fine-crystal cellulose by ESR method. Prikladnaay Spectroscopiya 56, 424-428 (1991) '

[12]. Dushkin A. V., Troitskaya I. B., Boldyrev, V. V., Grigor'ev I. A. Mechanochemical method for introduction of a spin marker in cellulose, Russian Chemical Bulletin, 54, 1155-1159 (2005).

[13]. Freed J.H. Theory of the ESR spectra of nitroxids in Spin Labeling. Theory and Applications, Berliner, L(Ed.) Vol.1, Academic Press, New York, 1976.

[14]. Bobodzhanov, P. Kh.; Yusupov, I. Kh.; Marupov, R. Study of molecular dynamics of microcrystalline cellulose by the ESR method. . Zhurnal Prikladnoi Spektroskopii, 56, 424-428 (1992).

[15]. Krinichnyi, V. I. 2-mm wave band ESR spectroscopy of condensed systems, Boca Raton, CRC Press, 1994.

[16]. Krinichnyi V. I., Grinberg, O. Ya, Yusupov I. Kh., Marupov, R. M., Bobodzhanov P. Kh., Likhtenshtein G. I., Lebedev Ya. S. Two-millimeter band ESR study of spin-labeled cotton fiber. Biofizika 31, 482-485 (1986) .

[17]. Kulikov A. I. and Likhtenshtein GI. The use of spin-relaxation phenomena in the investigation of the structure of model and biological systems by method of spin labels. Adv Molecul Relax Proc 10:47-78 (1977)..

[18]. Dushkin A. V., Troitskaya I. B., Boldyrev, V. V., Grigor'ev I. A. Mechanochemical method for introduction of a spin marker in cellulose, Russian Chemical Bulletin, 54, 1155-1159 (2005).

[19]. Yusupov I. Kh., Bobodzhanov P. Kh., Marupov R., Islomov S., Antsiferova L. I., Kol'tover, V. K., Likhtenshtein G. I. Spin label study of molecular dynamics of cotton fiber. Vysokomolekulyarnye Soedineniya, Seriya A, 26, 369-373 (1984].

[20]. Ysupov I. Kh., Likhtenshtein G. I. Study of Microstructure and Molecular Dynamics of Cotton and Cellulose Fibers by Methods of Physical Labels. International Research Journal of Pure & Applied Chemistry. 6(3), 105-119, (2015)

[21]. Krinichnyi, V. I. 2-mm wave band ESR spectroscopy of condensed systems, Boca Raton, CRC Press, 1994.

[22]. Krinichnyi V. I., Grinberg, O. Ya, Yusupov I. Kh., Marupov, R. M., Bobodzhanov P. Kh., Likhtenshtein G. I., Lebedev Ya. S. Two-millimeter band ESR study of spin-labeled cotton fiber. Biofizika 31, 482-485 (1986) .

[23]. Yusupov I. Kh, Fogel V. R., Kotelnikov A. I., Bobodzhanov P. Kh., Marupov R. M. Study of molecular dynamics of cotton fibers by methods of luminescence labels. Biofisika, 33, 508- 511 (1988).

[24]. Yusupov I.Kh. Likhtenshtein G.I. Phosphorescence quenching as an approach for estimating localization of triplet label in cotton fibers. Biophysics, 57, 197–200 (2012).

[25]. Likhtenshtein G. I. Depth of immersion of paramagnatic centers. In: Magnetic Resonance in Biology (Berliner L., Eaton S. and Eaton G. eds. ) Kluwer Academic Publishers. Dordrecht, 2000, pp 1-36.

[26]. Kulikov A. V, Likhtenstein G. I. Application of saturation curves for evaluating distances in biological objects by the method of double spin-labels. Biofisika, 19:420-424 (1974).

[27]. Kulikov A. V. Determination of distance between the nitroxide label and a paramagnetic center in spin-labeled proteins from the parameters of the saturation curve of the ESR spectrum of the label at 77 K. Mol Biol (Moscow), 10:109-116 (1976).

[28]. Kulikov A. I., Likhtenshtein GI. The use of spin-relaxation phenomena in the investigation of the structure of model and biological systems by method of spin labels. Adv Molecul Relax Proc 10:47-78 (1977)..

[29]. Kulikov A. V., Yusupov I. Kh, Bobodzhanov P. Kh., Marupov R. M., Likhtenshtein G. I. Study of tertiary structure of cellulose by the spin labeling methods. Zhurnal Prikladnoy Spectroscopii, 55, 961-965 (1991)

[30]. Zhurkov S. N., Egorov E. A. Effect of tensile stress on the molecular mobility in oriented polymers. Doklady Akademii Nauk SSSR, 152, 1155-1158 (1963).

[31]. Gilyarov B .L. . Kinetic conception of stability and selforganization at destortion of materials. Phys. Tverd. Tela 47, 808-811(2005).

[32]. Suhir E. Three-step concept (TSC) in modeling microelectronics reliability (MR): Boltzmann– Arrhenius–Zhurkov (BAZ) probabilistic physics-of-failure equation sandwiched between two statistical models. Microelectronics Reliability54, 2594-2603 (2014) . Fundamentals 33. Stoyko Fakirov of Polymer Science for Engineers. Wiley VCH, 2017

[33]. Islomov S., Marupov R. Zhbankov R. G., Bobodzhanov P. Kh., Zabelin L. V., Marchenko G. N. Spin-label study of structural properties of nitrates based on flax shive cellulose. Zhurnal Prikladnoi Spektroskopii, 45, 633-638 (1986).

[34]. Gulinelli S., Mantovani, E., Zanobi A. EPR characterization of cellulose triacetate fibers used for enzyme immobilization. Applied Biochemistry and Biotechnology, 6, 129-141 (1981).

[35]. Batchelor S. N. Free-Radical and Singlet-Oxygen Mobility in Cotton Probed by EPR Spectroscopy. J. Phys. Chem. B, 103 (32) 6700–6703 (1999)

[36]. R. Scheuermann, and E. RodunerQuantitative Electron Paramagnetic Resonance Study of the Motion, Adsorption, and Aggregation of TEMPOL Radicals in the Nanopores of Dry Cotton. Journal of Physical Chemistry B 105(46), 11474-11479]... ygen Mobility in Cotton Probed by EPR Spectroscopy. J. Phys. Chem. B, (1999) 103 (32) 6700–6703, (2001).

[37]. Frantz S1, Hübner GA, Wendland O, Roduner E, Mariani C, Ottaviani MF, Batchelor SN. Effect of humidity on the supramolecular structure of cotton, studied by quantitative spin probing. J Phys Chem B. 109(23):11572-11579 (2005).

[38]. Frantz, S.; Wendland, O.; Roduner, E.; Whiteoak, C. J.; Batchelor, S. N. Effect of Charge on Spin Probe Interaction and Dynamics in the Nanopores of Cotton Journal of Physical Chemistry C 111(39), 14514-14520 (2007) .

[39]. Marek A, Voinov MA, Smirnov AI. Spin Probe Multi-Frequency EPR Study of Unprocessed Cotton Fibers. Cell Biochem Biophys. 75(2):211-226) (2017)

[40]. Islomov S.; Marupov R., Likhtenshtein G. I. Spin-label study of thermal transitions of plasticized cellulose. Cellulose Chemistry and Technology, 23,13-21 (1989).

[41]. Guillaume, Dietrich, Mathias, Blinco, James P., Hirschbiel, Astrid, Bruns, Michael, Barner, Leonie, & Barner-Kowollik, Christopher Photo-induced macromolecular functionalization of cellulose via nitroxide spin trapping. Biomacromolecules, 13(5), pp. 1700-1705 (2012).

[42]. Abitbol T, Palermo A, Moran- Mirabal J. M., Cranston E. D., Bulota M., Tanpichai S., Hughes M., Eichhorn S. J. Micromechanics of TEMPOoxidized fibrillated cellulose composites, ACS Applied Materials and Interfaces, 4, 331-337 (2012).

[43]. Moreira G., Charles L, Major M., Vacandio F., Guillaneuf Y., Lefay, C., Gigmes D. Stability of SG1 nitroxide towards unprotected sugar and lithium salts: a preamble to cellulose modification by nitroxide-mediated graft polymerization. Beilstein J. Org. Chem., 9, 1589–1600 (2013)

[44]. Liu, Shaojie; Xing, Yubin; Han, Jiangze; Tang, Erjun. Catalytic oxidation of cellulose with a novel amphiphilic nitroxide block copolymer as a recoverable catalyst. Cellulose (Dordrecht, Netherlands) 24(9), 3635- 3644(2017) .

[45]. Garcia-Valdez, Omar; Brescacin, Tiziana; Arredondo, Joaquin; Bouchard, Jean; Jessop, Philip G.; Champagne, Pascale; Cunningham, Michael F Grafting CO2-responsive polymers from cellulose nanocrystals via nitroxidemediated polymerisation .Polymer Chemistry 8(28), 4124-4131(2017) .

Cite this paper

Likhtenshtein Gertz I. (2018) Nitroxides in Cotton and Cellulose Physicochemistry and Technology. 42 Years of History. International Journal of Biology and Biomedicine, 3, 1-15

Copyright © 2018 Author(s) retain the copyright of this article.
This article is published under the terms of the Creative Commons Attribution License 4.0