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13.10.2015 | Original Paper

Use of bacterial cellulose in degraded paper restoration. Part I: application on model papers

verfasst von: Sara M. Santos, José M. Carbajo, Nuria Gómez, Ester Quintana, Miguel Ladero, Arsenio Sánchez, Gary Chinga-Carrasco, Juan C. Villar

Erschienen in: Journal of Materials Science | Ausgabe 3/2016

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Abstract

The disappearance of bibliographic heritage is one of the biggest problems facing libraries. One of the most common methods used to restore paper, lining, is to apply a reinforcing layer to the document. This study focuses on lining papers with bacterial cellulose (BC) sheets from Gluconacetobacter sucrofermentans. For this purpose, several model papers have been selected. They have been characterized before and after the lining with this BC and a specific Japanese paper (JP) to compare both materials. Taking into account the differences between bacterial and vegetal cellulose is expected that the results may be similar to other BC and JP. The samples have been characterized before and after an aging process. There are no significant differences in some of the characteristics studied. Nevertheless, BC-lined papers present higher gloss values and b* coordinate. The wettability decreases with both BC and JP. However, in papers lined with BC, the wettability decreases more markedly and independently of the model paper used. This is related to the sealing of the surface structure by BC, which also leads to a reduction of air permeability. When the lined papers go through an aging process, there are no significant changes in any characteristic, except in b* and L* color coordinates. Additionally, the wettability rate decreases in all cases. This study indicates that papers lined with BC are stable over time. Finally, the use of BC as reinforcing material may offer advantages for specific conservation treatments, being more suitable for certain types of paper than JP.

Vorheriger Artikel The effects of thermal nitridation on phosphorus diffusion in strained SiGe and SiGe:C

Nächster Artikel Use of bacterial cellulose in degraded paper restoration. Part II: application on real samples

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Bielecki S, Krystynowicz A, Turkiewicz M, Kalinowska H (2005) Bacterial cellulose. In: Steinbuchel A (ed) Biotechnology of polymer: from synthesis to patents. Wiley, Weinheim, pp 381–434

Iguchi M, Yamanaka S, Budhiono A (2000) Bacterial cellulose: a masterpiece of nature’s arts. J Mater Sci 35:261–270CrossRef

Ramana KV, Tomar A, Singh L (2000) Effect of various carbon and nitrogen sources on cellulose synthesis by Acetobacter xylinum. World J Microbiol Biotechnol 16:245–248CrossRef

Santos SM, Carbajo JM, Villar JC (2013) The effect of carbon and nitrogen sources on bacterial cellulose production and properties from Gluconacetobacter sucrofermentans CECT 7291 focused on its use in degraded paper restoration. BioResources 8:3630–3645

Jonas R, Farah LF (1998) Production and application of microbial cellulose. Polym Degrad Stab 59:101–106CrossRef

Yamanaka S, Ishihara M, Sugiyama J (2000) Structural modification of bacterial cellulose. Cellulose 7:213–225CrossRef

Brett CT (2000) Cellulose microfibrils in plants: biosynthesis, deposition and integration into the cell wall. Int Rev Cytol 199:161–199CrossRef

Nakagaito AN, Nogi M, Yano H (2010) Displays from transparent films of natural nanofibers. MRS Bull 35:214–218CrossRef

Castro C, Zuluaga R, Putaux JL, Caro G, Mondragon I, Gañán P (2011) Structural characterization of bacterial cellulose produced by Gluconacetobacter swingsii sp. from Colombian agroindustrial wastes. Carbohydr Polym 84:96–102CrossRef

10.

Brown RM Jr (1989) Bacterial Cellulose. In: Kennedy JF, Phillips GO, Williams PA (eds) Cellulose: structural and functional aspects. Ellis Horwood Ltd, New York, pp 145–151

11.

Watanabe K, Eto Y, Takano S, Nakamori S, Shibai H, Yoshinaka S (1993) A new bacterial cellulose substrate for mammalian cell culture. Cytotechnology 13:107–114CrossRef

12.

Sokolnicki AM, Fischer RJ, Harrah TP, Kaplan D (2006) Permeability of bacterial cellulose membranes. J Membr Sci 272:15–27CrossRef

13.

Czaja WK, Young DJ, Kawecki M, Brown RM (2007) The future prospects of microbial cellulose in biomedical applications. Biomacromolecules 8:1–12CrossRef

14.

Wan W, Millon L (2005) Poly (vinyl alcohol)-bacterial cellulose nanocomposite, US Patent 2005/0037082 A1

15.

Bäckdahl H, Helenius G, Bodin A, Nannmark U, Johansson BR, Risberg B, Gatenholm P (2006) Mechanical properties of bacterial cellulose and interactions with smooth muscle cells. Biomaterials 27:2141–2149CrossRef

16.

Yano S, Maeda H, Nakajima M, Hagiwara T, Sawaguchi T (2008) Preparation and mechanical properties of bacterial cellulose nanocomposites loaded with silica nanoparticles. Cellulose 15:111–120CrossRef

17.

Pommet M, Juntaro J, Heng JYY, Mantalaris A, Lee AF, Wilson K, Kalinka G, Shaffer MSP, Bismarck A (2008) Surface modification of natural fibers using bacteria: depositing bacterial cellulose onto natural fibers to create hierarchical fiber reinforced nanocomposites. Biomacromolecules 9:1643–1651CrossRef

18.

Surma-Ślusarska B, Danielewicz D, Presler S (2008) Properties of composites of unbeaten birch and pine sulphate pulps with bacterial cellulose. Fibres Text East Eur 16:127–129

19.

Sánchez Hernampérez A (1999) Políticas de conservación en bibliotecas. Arco Libros, Madrid

20.

Smook GA (1990) Handbook for pulp and paper technologists. TAPPI Press, Atlanta

21.

Sjöström E, Westermark U (1999) Chemical composition of wood and pulps: basic constituents and their distribution. In: Sjöström E, Alen R (eds) Analytical methods in wood chemistry, pulping, and papermaking. Springer, New York, pp 1–19CrossRef

22.

Lindström T (2009) Sizing. In: Ek M, Gellerstedt G, Henriksson G (eds) Pulp and paper chemistry and technology, vol 3., De Gruyter, Stockholm, Sweden, pp 275–318

23.

Baty JW, Maitland CL, Minter W, Hubbe MA, Jordan-Mowery SK (2010) Deacidification for the conservation and preservation of paper-based works: a review. BioResources 5:1955–2033

24.

Ahn K, Rosenau T, Potthast A (2013) The influence of alkaline reserve on the aging behavior of book papers. Cellulose 20:1989–2001CrossRef

25.

Ardelean E, Bobu E, Niculescu GH, Groza C (2011) Effects of different consolidation additives on ageing behavior of archived document paper. Cellul Chem Technol 45:97–103

26.

Bansa H, Ishii R (1997) The effect of different strengthening methods on different kinds of paper. Restaurator 18:51–72CrossRef

27.

Hestrin S, Schramm M (1954) Synthesis of cellulose by Acetobacter xylinum. 2. Preparation of freeze-dried cells capable of polymerizing glucose to cellulose. Biochem J 58:345–352CrossRef

28.

Chinga-Carrasco G, Kauko H, Myllis M, Timonen J, Wang B, Zhou M, Fossum JO (2008) New advances in the 3D characterization of mineral coating layers on paper. J Microsc 232:212–224CrossRef

29.

Owen A, Fiske B, Barrett T, McClintock TK, Volent P, Nicholson K, Kruth L, Rodger S (1988) Lining. Chap. 29 in paper conservation catalog. American Institute for Conservation Book and Paper Group, Washington D.C. http://cool.conservation-us.org/coolaic/bpg/pcc/17_sizing-resizing.pdf. Accessed 22 Mar 2013

30.

Torres FG, Troncoso OP, Torres C, Grande CJ (2013) Cellulose based blends, composites and nanocomposites. In: Sabu T, Visakh PM, Mathew, Aji P (eds) Advances in natural polymers. Composites and nanocomposites. Springer, New York, pp 21–54CrossRef

31.

Yamauchi T, Murakami K (2001) Porosity and gas permeability. In: Borch J, Lyne MB, Mark RE (eds) Handbook of physical testing of paper, vol 2. Springer, New York, pp 267–302

32.

Swain PS, Lipowsky R (1998) Contact angle on heterogeneous surfaces: a new look at Cassie’s and Wenzel’s laws. Langmuir 14:6772–6780CrossRef

33.

Tåg CM, Pykönen M, Rosenholm JB, Backfolk K (2009) Wettability of model fountain solutions: the influence on topo-chemical and physical properties of offset paper. J Colloid Interface Sci 330:428–436CrossRef

34.

Hubbe MA, Pawlak JJ, Koukoulas AA (2008) Paper’s appearance: a review. BioResources 3:627–665

35.

Karlovits M, Gregor-Svetec D (2011) Comparison of durability between UV inkjet and conventional offset prints exposed to accelerated ageing. JGED 2:10–15

36.

Van der Reyden D, Baker M, Hoffman C (1993) Effects of aging and solvent treatments on some properties of contemporary tracing papers. JAIC 31:177–206

37.

Santos SM, Carbajo JM, Quintana E, Ibarra D, Gómez N, Ladero M, Eugenio ME, Villar JC (2015) Characterization of purified bacterial cellulose focused on its use on paper restoration. Carbohydr Polym 116:173–181CrossRef

38.

Yousefi H, Faezipour M, Hedjazi S, Mousavi MM, Azusa Y, Heidari AH (2013) Comparative study of paper and nanopaper properties prepared from bacterial cellulose nanofibres and fibres/ground cellulose nanofibres of canola straw. Ind Crop Prod 43:732–737CrossRef

39.

Moutinho I, Figueiredo M, Ferreira PJ (2004) Influência dos agentes de colagem superficial na estrutura do papel: uma análise química. In: Jiménez L, Villar JC (eds) Proceedings of III CIADICYP. INIA, Madrid, pp 377–383

40.

Etzler FM, Buche M, Bobalek JF, Weiss MA (1995) Surface free energy of paper and inks: printability issues, papermakers conference. TAPPI Press, Chicago, pp 383–394

41.

Ferreira PJT, Moutinho IMT, Figueiredo MML (2008) How paper topography affects contact angle measurement. In: Turrado J (ed) V Congreso Iberoamericano de Investigación en Celulosa y Papel CIADICYP 2008. Grafisma, Guadalajara, pp 66–69

42.

Andersson C, Jonhed A, Järnström L (2008) Composition and film properties of temperature responsive, hydrophobically modified potato starch. Starch 60:539–550CrossRef

Titel: Use of bacterial cellulose in degraded paper restoration. Part I: application on model papers
verfasst von: Sara M. Santos
José M. Carbajo
Nuria Gómez
Ester Quintana
Miguel Ladero
Arsenio Sánchez
Gary Chinga-Carrasco
Juan C. Villar
Publikationsdatum: 13.10.2015
Verlag: Springer US
Erschienen in: Journal of Materials Science / Ausgabe 3/2016
Print ISSN: 0022-2461
Elektronische ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-015-9476-0

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