Home Physical Sciences A comparative study on the degradation of cotton linters induced by carbonate and hydroxyl radicals generated from peroxynitrite
Article
Licensed
Unlicensed Requires Authentication

A comparative study on the degradation of cotton linters induced by carbonate and hydroxyl radicals generated from peroxynitrite

  • Magnus Carlsson , David Stenman , Gábor Merényi and Torbjörn Reitberger
Published/Copyright: June 1, 2005
Holzforschung
From the journal Volume 59 Issue 2

Abstract

Carbonate (CO3•−) and hydroxyl (HO) radicals were chemically produced in cotton linter suspensions using peroxynitrite as a radical precursor. Both radicals could degrade cotton linters, as shown by viscosity and GPC-SEC measurements. As evidenced by the viscosity measurements, the presence of oxygen during the cotton linter treatments slightly increased cellulose degradation by both radicals. For the carbonate radical, more than 90% of the viscosity losses could be recovered by reductive NaBH4 treatment before measuring the viscosity, whereas only approximately 40% of the viscosity was recovered after hydroxyl radical degradation and subsequent NaBH4 treatment. This indicates that carbonate radicals mainly abstract H-atoms adjacent to hydroxyl groups, i.e., at C2, C3 and C6. This intramolecular selectivity may reflect a polar effect, whereby hydrogen atom abstractions from these positions are favoured. In addition, abstraction at C6 would be sterically and statistically favoured.

Keywords: carbonate radical; cellulose; cotton linters; degradation; fibre; hydroxyl radical; intramolecular selectivity; peroxynitrite
:
Corresponding author.

References

Al-Ajlouni, A.M. and E.S. Gould. 1996. Electron transfer 132. Oxidations with peroxynitrite. Inorg. Chem.35, 7892–7896.Search in Google Scholar

Alfassi, Z.B. and R.H. Schuler. 1985. Reaction of azide radicals with aromatic compounds. Azide as a selective oxidant. J. Phys. Chem.89(15), 3359–3363.Search in Google Scholar

Alfassi, Z.B., T. Dhanasekaran, R.E. Huie and P. Neta. 1999. On the reactions of CO3 radicals with NOx radicals. Radiat. Phys. Chem.56, 475–482.Search in Google Scholar

Argyropoulos, D., Ed. 2000. Oxidative Delignification Chemistry – Fundamentals and Catalysis. ACS Symposium Series 785.10.1021/bk-2001-0785Search in Google Scholar

Barat, F., B. Hickel and J. Sutton. 1969. Flash photolysis of aqueous solutions of azide and nitrate ions. Chem. Commun.1969, 125–126.Search in Google Scholar

Benton, D.J. and P. Moore. 1970. Kinetics and mechanism of the formation and decay of peroxynitrous acid in perchloric acid solutions. J. Chem. Soc. A1970, 3179–3182.Search in Google Scholar

Berthold, F., K. Gustafsson, E. Sjöholm and M. Lindström. 2001. An improved method for determination of softwood Kraft pulp molecular mass distribution. In: 11th ISWPC, Nice, France, 11–14 June 2001. pp. 363–366.Search in Google Scholar

Blough, N.V. and O.C. Zafiriou. 1985. Reaction of superoxide with nitric oxide to form peroxonitrite in alkaline solution. Inorg. Chem.24, 3502–3504.Search in Google Scholar

Coddington, J.W., J.K. Hurst and S.V. Lymar. 1999. Hydroxyl radical formation during peroxynitrous acid decomposition. J. Am. Chem. Soc.121, 2438–2443.Search in Google Scholar

Dizdaroglu, M., D. Hennerberg, G. Schomburg and C. Von Sonntag. 1975. Radiation chemistry of carbohydrates, VI. G-Radiolysis of glucose in deoxygenated N2O-saturated aqueous solution. Z. Naturforsch.30b, 416–425.Search in Google Scholar

Draganic, Z.D., A. Negron-Mendoza, K. Sehested, S.I Vujosevic, R. Navarro-Gonzales, M.G. Albarran-Sanches and I.G. Draganic. 1991. Radiolysis of aqueous solutions of ammonium bicarbonate over a large dose range. Radiat. Phys. Chem.38, 317–321.Search in Google Scholar

Gerasimov, O.V. and S.V. Lymar. 1999. The yield of hydroxyl radical from the decomposition of peroxynitrous acid. Inorg. Chem.38, 4317–4321.Search in Google Scholar

Gilbert, B.C., J.R. Lindsay Smith, P. Taylor, S. Ward and A.C. Whitwood. 1999. The interplay of electronic, steric and stereoelectronic effects in hydrogen-atom abstraction reactions of SO4, revealed by EPR spectroscopy. J. Chem. Soc. Perkin Trans.2, 1631–1637.Search in Google Scholar

Gleu, V.K. and E. Roell. 1929. Die entwirkung von Ozon auf Alkaliazid. Persalpetrige Säure 1. Z. Anorg. Allg. Chem.179, 233–266.Search in Google Scholar

Goldstein, S. and G. Czapski. 1995a. The reaction of NO with O2•− and HO2: a pulse radiolysis study. Free Radic. Biol. Med.19, 505–510.Search in Google Scholar

Goldstein, S. and G. Czapski. 1995b. Direct and indirect oxidations by peroxynitrite. Inorg. Chem.34, 4041–4048.Search in Google Scholar

Goldstein, S. and G. Czapski. 1996. Formation of peroxynitrite from the nitrosation of hydrogen peroxide by an oxygenated nitric oxide solution. Inorg. Chem.35, 5935–5940.Search in Google Scholar

Goldstein, S. and G. Czapski. 1998. Formation of peroxynitrite from the reaction of peroxynitrite with CO2: evidence for carbonate radical production. J. Am. Chem. Soc.120, 3458–3463.Search in Google Scholar

Goldstein, S., A. Saha, S.V. Lymar and G. Czapski. 1998. Oxidation of peroxynitrite by inorganic radicals: a pulse radiolysis study. J. Am. Chem. Soc.120, 5549–5554.Search in Google Scholar

Goldstein, S., D. Meyerstein, R. van Eldik and G. Czapski. 1999. Peroxynitrous acid decomposes via homolysis: evidence from high-pressure pulse radiolysis. J. Phys. Chem. A103, 6587–6590.Search in Google Scholar

Goldstein, S., G. Czapski, J. Lind and G. Merenyi. 2001. Carbonate radical ion is the only observable intermediate in the reaction of peroxynitrite with CO2. Chem. Res. Toxicol.14, 1275–1276.Search in Google Scholar

Goldstein, S., J. Lind and G. Merényi. 2002. The reaction of ONOO with carbonyls: estimation of the half-lives of ONOOC(O)O and O2NOOC(O)O. Dalton Trans.2002, 808–810.Search in Google Scholar

Grätzel, M., A. Henglein and S. Taniguchi. 1970. Pulsradiolytische beobachtungen über die Reduktion des NO3−•-Ions und über die Bildung und Zerfall der persalpetrigen Säure in wäßriger Lösung. Ber. Bunsen Ges. Phys. Chem.94, 292–298.Search in Google Scholar

Halfpenny, E. and P.L. Robinson. 1952. The reaction between hydrogen peroxide and nitrous acid. J. Chem. Soc.1952, 928–938.Search in Google Scholar

Hodges, G.R. and K.U. Ingold. 1999. Cage-escape of geminate radical pairs can produce peroxynitrate from peroxynitrite under a wide variety of experimental conditions. J. Am. Chem. Soc.121, 10695–10701.Search in Google Scholar

Hughes, M.N. and H.G. Nicklin. 1968. The chemistry of pernitrites. Part I: kinetics of decomposition of pernitrous acid. J. Chem. Soc.1968, 450–45210.1039/j19680000450Search in Google Scholar

Hughes, M.N. and H.G. Nicklin. 1971. Autoxidation of hydroxylamine in alkaline solutions. J. Chem. Soc. A1971, 164–168.Search in Google Scholar

Kleinert, T.N. 1966. Degradation of cellulose by sodium borohydride. Holzforschung20(2), 41–42.Search in Google Scholar

Larm, O., E. Scholander and O. Theander. 1976. Bromine oxidation of methyl α- and β-pyranosides of d-galactose, d-glucose, and d-mannose. Carbohydrate. Res.49, 69–77.Search in Google Scholar

Leis, J.R., M.E. Peña and A. Ríos. 1993. A novel route to peroxynitrite anion. Chem. Commun.1993, 1298–1299.Search in Google Scholar

Løgager, T. and K. Sehested. 1993. Formation and decay of peroxynitrous acid: a pulse radiolysis study. J. Phys. Chem.97, 6664–6669.Search in Google Scholar

Lymar, S.V. and J.K. Hurst. 1995. Rapid reaction between peroxynitrite ion and carbon dioxide: implications for biological activity. J. Am. Chem. Soc.117, 8867–8868.Search in Google Scholar

Lymar, S.V. and J.K. Hurst. 1998. CO2-catalyzed one-electron oxidations by peroxynitrite: properties of the reactive intermediate. Inorg. Chem.37, 294–301.Search in Google Scholar

Lymar, S.V., R.F. Khairutdinov and J.K. Hurst. 2003. Hydroxyl radical formation by O−O bond homolysis in peroxynitrous acid. Inorg. Chem.42, 5259–5266.Search in Google Scholar

Mahoney, L.R. 1970. Evidence for the formation of hydroxyl radicals in the isomerization of pernitrous acid to nitric acid in aqueous solution. J. Am. Chem. Soc.92(17), 5762–5763.Search in Google Scholar

Mark, G., H.-P. Schuchmann and C. Von Sonntag. 2000. Formation of peroxynitrite by sonification of aerated water. J. Am. Chem. Soc.122, 3781–3782.Search in Google Scholar

Merenyi, G. and J. Lind. 1997. Thermodynamics of peroxynitrite and its CO2 adduct. Chem. Res. Toxicol.10(11), 1216–1220.Search in Google Scholar

Merényi, G., J. Lind, S. Goldstein and G. Czapski. 1998. Peroxynitrous acid homolysis into OH and NO2 radicals. Chem Res. Toxicol.11, 712–713.Search in Google Scholar

Merényi, G., J. Lind and S. Goldstein. 2002. The rate of homolysis of adducts of peroxynitrite to the C=O double bond. J. Am. Chem. Soc.124(1), 40–48.Search in Google Scholar

Pryor, W.A. 1995. The chemistry of peroxynitrite: a product from the reaction of nitric oxide with superoxide. Am. J. Physiol.268, L699–L722.Search in Google Scholar

Pryor, W.A., R. Cueto, X. Jin, W.H. Koppenol, M. Ngu-Schwemlein, G.L. Squadrito, P.L. Uppu and R.M. Uppu. 1995. A practical method for preparing peroxynitrite solutions of low ionic strength and free of hydrogen peroxide. Free Radic. Biol. Med.18(1), 75–83.Search in Google Scholar

Saha, A., S. Goldstein, D. Cabelli and G. Czapski. 1998. Determination of optimal conditions for synthesis of peroxynitrite by mixing acidified hydrogen peroxide with nitrite. Free Radic. Biol. Med.24(4), 653–659.Search in Google Scholar

Saran, M., C. Michel and W. Bors. 1990. Reaction of NO with O2•− implications for endothelium-derived relaxing factor (EDRF). Free Radic. Res. Commun.10, 221–226.Search in Google Scholar

Schuchmann, H.P. and C. Von Sonntag. 1978. The effect of oxygen on the OH-radical-induced scission of the glycosidic linkage of cellobiose. Int. J. Radiat. Biol.34(4), 397–400.Search in Google Scholar

Serjeant, E.P. and B. Dempsey. 1979. Ionisation Constants of Organic Acids in Aqueous Solution, 1st Ed. IUPAC Chemical Data Series No. 23, Pergamon Press, Oxford.Search in Google Scholar

Stanbury, D.M. 1989. Reduction potentials involving inorganic free radicals in aqueous solution. Adv. Inorg. Chem.33, 69–138.Search in Google Scholar

Stenman, D., M. Carlsson, M. Jonsson and T. Reitberger. 2003. Reactivity of the carbonate radical anion towards lignin and carbohydrate model compounds. J. Wood Chem. Technol.23(1),47–69.Search in Google Scholar

Stenman, D., M. Carlsson and T. Reitberger. 2004. Peroxynitrite-mediated delignification of pulp: a comparative study on the bleaching properties of the carbonate and hydroxyl radicals. J. Wood Chem. Technol.24(2) 83–98.Search in Google Scholar

Stern, M.K., M.P. Jensen and K. Kramer. 1996. Peroxynitrite decomposition catalysts. J. Am. Chem. Soc.118, 8735–8736.Search in Google Scholar

Svetlov, B.S., B.A. Lur'e and G.E. Kornilova. 1974. Kinetics of the oxidation of cellulose by nitrogen dioxide. USSR Trudy Inst. Moskovskij Khim. Teknol. Inst. Mendeleva83, 41–47.Search in Google Scholar

Uppu, R.M. and W.A. Pryor. 1996. Synthesis of peroxynitrite in a two-phase system using isoamyl nitrite and hydrogen peroxide. Anal. Biochem.236, 242–249.Search in Google Scholar

Uppu, R.M., G.L. Squadrito, R. Cueto and W.A. Pryor. 1996a. Acceleration of peroxynitrite oxidations by carbon dioxide. Arch. Biochem. Biophys.327(2), 335–343.Search in Google Scholar

Uppu, R.M., G.L. Squadrito, R. Cueto and W.A. Pryor. 1996b. Selecting the most appropriate synthesis of peroxynitrite. Methods Enzymol.269, 285–295.Search in Google Scholar

Von Sonntag, C. and H.-P. Schuchmann. 2001. Carbohydrates in Radiation Chemistry: Present Status and Future Trends, Elsevier Science BV, Amsterdam.10.1016/S0167-6881(01)80020-3Search in Google Scholar

Von Sonntag, C., M. Dizdaroglu and D. Schulte-Frolinde. 1976. Radiation chemistry of carbohydrates, VIII. γ-Radiolysis of cellobiose in N2O-saturated aqueous solution. Part II. Quantitative measurements. Mechanism of the radical-induced scission of the glycosidic linkage. Z. Naturforsch.31b, 857–864.Search in Google Scholar

Wagner, I., H. Strehlow and G. Buse. 1980. Flash photolysis of nitrate ions in aqueous solution. Z. Phys. Chem. Neue Folge123, 1–33.Search in Google Scholar

Published Online: 2005-06-01
Published in Print: 2005-02-01

©2005 by Walter de Gruyter Berlin New York

Articles in the same Issue

  1. Obituary
  2. The role of non-phenolic lignin in chlorate-forming reactions during chlorine dioxide bleaching of softwood kraft pulp
  3. Study of the oxygen effect on mechanical pulp lignin using an improved lignin isolation method
  4. Quantitative 1H NMR analysis of alkaline polysulfide solutions
  5. A comparative study on the degradation of cotton linters induced by carbonate and hydroxyl radicals generated from peroxynitrite
  6. The carbonate radical as one-electron oxidant of carbohydrates in alkaline media
  7. Leaf-fiber lignins of Phormium varieties compared bysolid-state 13C NMR spectroscopy
  8. Antifungal activity of iridoid glycosides from the heartwood of Gmelina arborea
  9. Antioxidant activity of different components of pine species
  10. Dislocations in Norway spruce fibres and their effect on properties of pulp and paper
  11. Isolation and identification of antifungal compounds from Amboyna wood
  12. Biomechanical pulping of spruce wood chips with Streptomyces cyaneus CECT 3335 and handsheet characterization
  13. Three-dimensional visualisation of bacterial decay in individual tracheids of Pinus sylvestris
  14. Mass loss and moisture dynamics of Scots pine (Pinus sylvestris L.) exposed outdoors above ground in Sweden
  15. The influence of cation and anion structure of new quaternary ammonium salts on adsorption and leaching
  16. Speciation of arsenic and chromium in the leachate from chromated copper arsenate (CCA) type C treated southern pine (Pinus spp.)
  17. Metal chelation studies relevant to wood preservation.1. Complexation of propyl gallate with Fe2+
  18. Comparison of UV and confocal Raman microscopy to measure the melamine–formaldehyde resin content within cell walls of impregnated spruce wood
  19. Comparison of Pinus taeda L. wood property calibrations based on NIR spectra from the radial-longitudinal and radial-transverse faces of wooden strips
  20. Detection of failures of adhesively bonded joints using the acoustic emission method
  21. Effect of cross-sectional change of a board specimen on stress wave velocity determination
  22. Comments on the experimental methodology for determination of the hygro-mechanical properties of wood
  23. Properties of chemically and mechanically isolated fibres of spruce (Picea abies [L.] Karst.). Part 1: Structural and chemical characterisation
  24. Properties of chemically and mechanically isolated fibres of spruce (Picea abies[L.] Karst.). Part 2: Twisting phenomena
https://doi.org/10.1515/HF.2005.020
Keywords for this article
carbonate radical; cellulose; cotton linters; degradation; fibre; hydroxyl radical; intramolecular selectivity; peroxynitrite

Articles in the same Issue

  1. Obituary
  2. The role of non-phenolic lignin in chlorate-forming reactions during chlorine dioxide bleaching of softwood kraft pulp
  3. Study of the oxygen effect on mechanical pulp lignin using an improved lignin isolation method
  4. Quantitative 1H NMR analysis of alkaline polysulfide solutions
  5. A comparative study on the degradation of cotton linters induced by carbonate and hydroxyl radicals generated from peroxynitrite
  6. The carbonate radical as one-electron oxidant of carbohydrates in alkaline media
  7. Leaf-fiber lignins of Phormium varieties compared bysolid-state 13C NMR spectroscopy
  8. Antifungal activity of iridoid glycosides from the heartwood of Gmelina arborea
  9. Antioxidant activity of different components of pine species
  10. Dislocations in Norway spruce fibres and their effect on properties of pulp and paper
  11. Isolation and identification of antifungal compounds from Amboyna wood
  12. Biomechanical pulping of spruce wood chips with Streptomyces cyaneus CECT 3335 and handsheet characterization
  13. Three-dimensional visualisation of bacterial decay in individual tracheids of Pinus sylvestris
  14. Mass loss and moisture dynamics of Scots pine (Pinus sylvestris L.) exposed outdoors above ground in Sweden
  15. The influence of cation and anion structure of new quaternary ammonium salts on adsorption and leaching
  16. Speciation of arsenic and chromium in the leachate from chromated copper arsenate (CCA) type C treated southern pine (Pinus spp.)
  17. Metal chelation studies relevant to wood preservation.1. Complexation of propyl gallate with Fe2+
  18. Comparison of UV and confocal Raman microscopy to measure the melamine–formaldehyde resin content within cell walls of impregnated spruce wood
  19. Comparison of Pinus taeda L. wood property calibrations based on NIR spectra from the radial-longitudinal and radial-transverse faces of wooden strips
  20. Detection of failures of adhesively bonded joints using the acoustic emission method
  21. Effect of cross-sectional change of a board specimen on stress wave velocity determination
  22. Comments on the experimental methodology for determination of the hygro-mechanical properties of wood
  23. Properties of chemically and mechanically isolated fibres of spruce (Picea abies [L.] Karst.). Part 1: Structural and chemical characterisation
  24. Properties of chemically and mechanically isolated fibres of spruce (Picea abies[L.] Karst.). Part 2: Twisting phenomena
Sign up now to receive a 20% welcome discount
Institutional Access
How does access work?
Have an idea on how to improve our website?
Please write us.
© 2025 De Gruyter Brill
Downloaded on 29.12.2025 from https://www.degruyterbrill.com/document/doi/10.1515/HF.2005.020/pdf
Scroll to top button