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Bacterial cellulose

December 18, 2023

Bacterial cellulose is an organic compound with the formula (C
6H
10O
5)
n produced by certain types of bacteria. While cellulose is a basic structural material of most plants, it is also produced by bacteria, principally of the genera Acetobacter, Sarcina ventriculi and Agrobacterium. Bacterial, or microbial, cellulose has different properties from plant cellulose and is characterized by high purity, strength, moldability and increased water holding ability.[1] In natural habitats, the majority of bacteria synthesize extracellular polysaccharides, such as cellulose, which form protective envelopes around the cells. While bacterial cellulose is produced in nature, many methods are currently being investigated to enhance cellulose growth from cultures in laboratories as a large-scale process. By controlling synthesis methods, the resulting microbial cellulose can be tailored to have specific desirable properties. For example, attention has been given to the bacteria Komagataeibacter xylinum due to its cellulose's unique mechanical properties and applications to biotechnology, microbiology, and materials science. Historically, bacterial cellulose has been limited to the manufacture of Nata de coco, a South-East Asian food product.[2] With advances in the ability to synthesize and characterize bacterial cellulose, the material is being used for a wide variety of commercial applications including textiles, cosmetics, and food products, as well as medical applications. Many patents have been issued in microbial cellulose applications and several active areas of research are attempting to better characterize microbial cellulose and utilize it in new areas.[1]

A wet microbial cellulose pellicle being removed from a culture.

History edit

As a material, cellulose was first discovered in 1838 by Anselme Payen. Payen was able to isolate the cellulose from the other plant matter and chemically characterize it. In one of its first and most common industrial applications, cellulose from wood pulp was used to manufacture paper. It is ideal for displaying information in print form due to its high reflectivity, high contrast, low cost and flexibility. The discovery of cellulose produced by bacteria, specifically from the Acetobacter xylinum, was accredited to A.J. Brown in 1886 with the synthesis of an extracellular gelatinous mat.[3] However, it was not until the 20th century that more intensive studies on bacterial cellulose were conducted. Several decades after the initial discovery of microbial cellulose, C.A. Browne studied the cellulose material obtained by fermentation of Louisiana sugar cane juice and affirmed the results by A.J. Brown.[4] Other researchers reported the formation of cellulose by other various organisms such as the Acetobacter pasteurianum, Acetobacter rancens, Sarcina ventriculi, and Bacterium xylinoides. In 1931, Tarr and Hibbert published the first detailed study of the formation of bacterial cellulose by conducting a series of experiments to grow A. xylinum on culture mediums.[5]

In the mid-1900s, Hestrin et al. proved the necessity of glucose and oxygen in the synthesis of bacterial cellulose. Soon after, Colvin detected cellulose synthesis in samples containing cell-free extract of A. xylinum, glucose and ATP.[6] In 1949, the microfibrillar structure of bacterial cellulose was characterized by Muhlethaler.[7] Further bacterial cellulose studies have led to new uses and applications for the material.

Biosynthesis edit

 
Chemical structure of cellulose

Bacterial sources edit

Bacteria that produce cellulose include Gram-negative bacteria species such as Acetobacter, Azotobacter, Rhizobium, Pseudomonas, Salmonella, Alcaligenes, and Gram-positive bacteria species such as Sarcina ventriculi.[8] The most effective producers of cellulose are A. xylinum, A. hansenii, and A. pasteurianus. Of these, A. xylinum is the model microorganism for basic and applied studies on cellulose due to its ability to produce relatively high levels of polymer from a wide range of carbon and nitrogen sources.[9]

General process edit

 
Biochemical Pathway for Cellulose Synthesis

The synthesis of bacterial cellulose is a multistep process that involve two main mechanisms: the synthesis of uridine diphosphoglucose (UDPGIc), followed by the polymerization of glucose into long and unbranched chains (the β-1→4 glucan chain) by cellulose synthase. Specifics on the cellulose synthesis has been extensively documented.[10][11] The former mechanism is well known while the latter still needs exploring. The production of UDPGIc starts with carbon compounds (such as hexoses, glycerol, dihydroxyacetone, pyruvate, and dicarboxylic acids) entering the Krebs cycle, gluconeogenesis, or the pentose phosphate cycle depending on what carbon source is available. It then goes through phosphorylation along with catalysis, followed by isomerization of the intermediate, and a process known as UDPGIc pyrophosphorylase to convert the compounds into UDPGIc, a precursor to the production of cellulose. The polymerization of glucose into the β-1→4 glucan chain has been hypothesized to either involve a lipid intermediate[12] or not to involve a lipid intermediate,[10] though structural enzymology studies and in vitro experiments indicate that polymerization can occur by direct enzymatic transfer of a glucosyl moiety from a nucleotide sugar to the growing polysaccharide.[13] A. xylinum usually converts carbon compounds into cellulose with around 50% efficiency.[12]

Fermentation production edit

Bacterial Strains that Produce Cellulose
Micro­organism Carbon source Supple­ment Culture time (h) Yield (g/L)
A. xylinum BRCS glucose ethanol, oxygen 50 15.30
G. hansenii PJK (KCTC 10505 BP) glucose oxygen 48 1.72
glucose ethanol 72 2.50
Aceto­bacter sp. V6 glucose ethanol 192 4.16
Aceto­bacter sp. A9 glucose ethanol 192 15.20
A. xylinum ssp. Sucro­fermentans BPR2001 molasses none 72 7.82
fructose agar oxygen 72 14.10
fructose agar 56 12.00
fructose oxygen 52 10.40
fructose agar oxygen 44 8.70
A. xylinum E25 glucose no 168 3.50
G. xylinus K3 mannitol green tea 168 3.34
G. xylinus IFO 13773 glucose lignosulphonate 168 10.10
A. xylinum NUST4.1 glucose sodium alginate 120 6.00
G. xylinus IFO 13773 sugar cane molasses no 168 5.76
G. xylinus sp. RKY5 glycerol no 144 5.63
Glucon­aceto­bacter sp. St-60-12 and Lacto­bacillus Mali JCM1116 (co-culture) sucrose no 72 4.20

Cellulose production depends heavily on several factors such as the growth medium, environmental conditions, and the formation of byproducts. The fermentation medium contains carbon, nitrogen, and other macro and micro nutrients required for bacteria growth. Bacteria are most efficient when supplied with an abundant carbon source and minimal nitrogen source.[14] Glucose and sucrose are the most commonly used carbon sources for cellulose production, while fructose, maltose, xylose, starch, and glycerol have been tried.[15] Sometimes, ethanol may be used to increase cellulose production.[16] The problem with using glucose is that gluconic acid is formed as a byproduct which decreases the pH of the culture and in turn, decreases the production of cellulose. Studies have shown that gluconic acid production can be decreased in the presence of lignosulfonate.[17] Addition of organic acids, specifically acetic acid, also helped in a higher yield of cellulose.[18] Studies of using molasses medium in a jar fermentor[19] as well as added components of sugarcane molasses[20] on certain strains of bacteria have been studied with results showing increases in cellulose production.

Addition of extra nitrogen generally decreases cellulose production while addition of precursor molecules such as amino acids[21] and methionine improved yield. Pyridoxine, nicotinic acid, p-aminobenzoic acid and biotin are vitamins important for cellulose production whereas pantothenate and riboflavin have opposing effects.[22] In reactors where the process is more complex, water-soluble polysaccharides such as agar,[23] acetan, and sodium alginate[24] are added to prevent clumping or coagulation of bacterial cellulose.

The other main environmental factors affecting cellulose production are pH, temperature, and dissolved oxygen. According to experimental studies, the optimal temperature for maximum production was between 28 and 30 °C.[25] For most species, the optimal pH was between 4.0 and 6.0.[15] Controlling pH is especially important in static cultures as the accumulation of gluconic, acetic, or lactic acid decreases the pH far lower than the optimal range. Dissolved oxygen content can be varied with stirrer speed as it is needed for static cultures where substrates need to be transported by diffusion.[26]

Reactor based production edit

Static and agitated cultures are conventional ways to produce bacterial cellulose. Both static and agitated cultures are not feasible for large-scale production as static cultures have a long culture period as well as intensive manpower and agitated cultures produce cellulose-negative mutants alongside its reactions due to rapid growth.[27] Thus, reactors are designed to lessen culture time and inhibit the conversion of bacterial cellulose-producing strains into cellulose-negative mutants. Common reactors used are the rotating disk reactor,[28] the rotary biofilm contactor (RBC),[27] a bioreactor equipped with a spin filter,[29] and a reactor with a silicone membrane.[30]

Structure and properties edit

Types of cellulose[1]
Genus Cellulose type Biological role
Acetobacter Extracellular pellicle,
ribbons 		Maintain aerobic
environment
Achromobacter Ribbons Flocculation
Aerobacter Fibrils Flocculation
Agrobacterium Short fibrils Attachment to plants
Alcaligenes Fibrils Flocculation
Pseudomonas Non-distinct Flocculation
Rhozobium Short fibrils Attachment to plants
Sarcina Amorphous Unknown

Differences between plant and bacterial cellulose edit

As the Earth's most common organic material, cellulose can be classified into plant cellulose and bacterial cellulose, both of which are naturally occurring. Plant cellulose, which makes up the cell walls of most plants, is a tough, mesh-like bulkwork in which cellulose fibrils are the primary architectural elements. While bacterial cellulose has the same molecular formula as plant cellulose, it has significantly different macromolecular properties and characteristics.[6] In general, microbial cellulose is more chemically pure, containing no hemicellulose or lignin, has a higher water holding capacity and hydrophilicity, greater tensile strength resulting from a larger amount of polymerization, ultrafine network architecture. Furthermore, bacterial cellulose can be produced on a variety of substrates and can be grown to virtually any shape due to the high moldability during formation.[31] Additionally, bacterial cellulose has a more crystalline structure compared to plant cellulose and forms characteristic ribbon-like microfibrils.[1] A hallmark of microbial cellulose, these thin microfibrils are significantly smaller than those in plant cellulose, making bacterial cellulose much more porous.[7]

 
Three way branching point mechanism

Macro structure edit

Cellulose is composed of carbon, oxygen, and hydrogen, and is classified as a polysaccharide, indicating it is a carbohydrate that exhibits polymeric characteristics. Cellulose is composed of straight chain polymers, whose base units of glucose are held together by beta-linkages. The structural role of cellulose in cell walls has been likened to that of the glass strands of fiberglass or to the supporting rods within reinforced concrete.[citation needed] Cellulose fibrils are highly insoluble and inelastic and, because of their molecular configuration, have a tensile strength comparable to that of steel.[citation needed] Consequently, cellulose imparts a unique combination of chemical resilience and mechanical support and flexibility to the tissues in which it resides.[32] Bacterial cellulose, produced by Acetobacter species, displays unique properties, including high mechanical strength, high water absorption capacity, high crystallinity, and an ultra-fine and highly pure fiber network structure.[33] One of the most important features of bacterial cellulose is its chemical purity. In addition to this, bacterial cellulose is stable towards chemicals and at high temperatures.[34] Bacterial cellulose has been suggested to have a construction like a ‘cage' which protects the cell from foreign material and heavy-metal ions, while still allowing nutrients to be supplied easily by diffusion.[2][35] Bacterial cellulose was described by Louis Pasteur as "a sort of moist skin, swollen, gelatinous and slippery." Although the solid portion in the gel is less than one percent, it is almost pure cellulose containing no lignin and other foreign substances.[2] Although bacterial cellulose is obtained in the form of a highly swollen gel, the texture is quite unique and different from typical gels. Cellulose has a high swollen fiber network resulting from the presence of pore structures and tunnels within the wet pellicle. Plant cellulose water retention values 60%, while bacterial cellulose has a water retention value of 1000%.[31] The formation of the cellulose pellicle occurs on the upper surface of the supernatant film. A large surface area is important for a good productivity. The cellulose formation occurs at the air/cellulose pellicle interface and not at the medium/cellulose interface. Thus oxygen is an important factor for cellulose production.[1] After an inducing and a rapid growth period, the thickness increases steadily. Fibrils appear to be not necessarily linear but contain some "three-way branching points" along their length. This type of branching is considered to be related to the unique characteristics of this material and occurs from branching points produced by binary fission.[36]

 
Sizes of synthetic and naturally occurring fibers[37]

Properties and characterization edit

Sheet-shaped material prepared from bacterial cellulose has remarkable mechanical properties. According to Brown, the pellicle of bacterial cellulose was "very tough, especially if an attempt was made to tear it across its plane of growth".[2] The Young's modulus for bacterial cellulose has been reported to be as high as 15 GPa across the plane of the sheet, whereas the highest values attained in the past by polymeric films or sheets is < 10GPa at most. The sheet's high Young's modulus has been attributed to the unique super-molecular structure in which fibrils of biological origin are preserved and bound tightly by hydrogen bonds. This Young's modulus does not vary with temperature nor the cultivation process used. The very high Young's modulus of this material must be ascribed to its super-molecular structure.[35][36]

This property arises from adjacently aligned glucan chains participating in inter- and intrachain hydrogen bonding.[32] Bacterial cellulose subfibrils are crystallized into microfibrils which group to form bundles, that then form 'ribbons'. These fibers are two orders of magnitude thinner than cellulose fibers produced by pulping wood.[6] Today, it is known that the pellicle comprises a random assembly of fibrils (< 130 nm wide), which are composed of a bundle of much finer microfibrils (2 to 4 nm diameter). It is also known that the pellicle gives a film or sheet when dried if the shrinkage across the plane is restricted.[36] The ultrafine ribbons of microbial cellulose form a dense reticulated structure, stabilized by extensive hydrogen bonding. Bacterial cellulose is also distinguished from its plant counterpart by a high crystallinity index (above 60%). Two common crystalline forms of cellulose, designated as I and II, are distinguishable by X-ray, nuclear magnetic resonance (NMR), Raman spectroscopy, and infrared analysis.[6] Bacterial cellulose belongs crystallographically to Cellulose I, common with natural cellulose of vegetable origin, in which two cellulose units are arranged parallel in a unit cell.[2][38] The term Cellulose I is used for this parallel arrangement, whereas crystalline fibrils bearing antiparallel polyglucan chains arise forming the thermodynamically stable Cellulose II.[32] The molecular arrangement in the sheet, confirmed by X-ray diffraction, was such that the molecular chain axis lay randomly perpendicular to the thickness such that the (1 1 0) plane was oriented parallel to the surface.[36]

Although cellulose forms a distinct crystalline structure, cellulose fibers in nature are not purely crystalline. In addition to the crystalline and amorphous regions, cellulose fibers contain various types of irregularities, such as kinks or twists of the microfibrils, or voids such as surface micropores, large pits, and capillaries. Thus, the total surface area of a cellulose fiber is much greater than the surface area of an ideally smooth fiber of the same dimension. The net effect of structural heterogeneity within the fiber is that the fibers are at least partially hydrated by water when immersed in aqueous media, and some micropores and capillaries are sufficiently spacious to permit penetration.[35]

Scanning electron microscopy of a fractured edge has revealed a pile of very thin layers. It is suggested that these fibrils in layers are bound through interfibrillar hydrogen bonds, just as in pulp-papers, but the density of the interfibrillar hydrogen bonds must be much higher as the fibrils are finer, hence the contact area is larger.[36]

Applications edit

Bacterial cellulose has a wide variety of current and potential future applications. Due to its many unique properties, it has been used in the food industry, the medical field, commercial and industrial products, and other technical areas. Bacterial cellulose is a versatile structural material, allowing it to be shaped in a variety of ways to accommodate different uses. A number of patents have been issued for processes involving this material.[39] . Bacterial cellulose pellicles were proposed as a temporary skin substitute in case of human burns and other dermal injuries [44. Fontana, J.D. et al (1990) "Acetobacter cellulose pellicle as a temporary skin substituite". .Applie d Biochemistry and Biotechnology (Humana Press) 24-25 : 253-264].

Food edit

The oldest known use of bacterial cellulose is as the raw material of nata de piña, a traditional sweet candy dessert of the Philippines. Several natural colored pigments (oxycarotenoids, anthocyanins and related antioxidants and free radical scavengers) were incorporated in to bacterial cellulose cubes in order to render the dessert more attractive [45. Fontana, J.D. et al (2017)  Handbook of Food Bioengineering, Elsevier / Academic Press, chapter 7 : New Insights on Bacterial Cellulose, pages 213-249]. Bacterial cellulose has also been used as a thickener to maintain the viscosity in food and as a stabilizing agent. Due to its texture and fiber content, it has been added to many food products as a dietary fiber. A specific example is Cellulon ®, which is a bulking agent used as a food ingredient to act as a thickener, texturizer, and/or calorie reducer.[40] Microbial cellulose has also been used as an additive in diet beverages in Japan since 1992, specifically kombucha, a fermented tea drink.[7]

Commercial products edit

Bacterial cellulose also has wide applications in commercial industries. In papermaking, it is used as an ultra-strength paper and as a reticulated fine fibre network with coating, binding, thickening and suspending characteristics.[33] Due to its high sonic velocity and low dynamic loss, bacterial cellulose has been used as an acoustic or filter membrane in hi-fidelity loudspeakers and headphones as marketed by the Sony Corporation.[2] Bacterial cellulose is also used as an additive in the cosmetic industry. Furthermore, it is being tested in the textile industry, with the possibility of manufacturing cellulose based clothing.[33]

Medical edit

In more modern applications, microbial cellulose has become relevant in the medical sector. It has been tested and successfully used as a wound dressing, especially in burn cases. Studies have shown that burns treated with microbial cellulose coverings healed faster than traditional treatments and had less scarring. The microbial cellulose topical applications are effective due to the cellulose's water holding ability and water vapor permeability. The high water holding ability provides a moist atmosphere at the injury site, which is critical in healing, while the wicking ability allows seepage from the wound to be removed from the site. Also, the microbial cellulose molds very well to the surface of the skin, providing a conformal covering even in usually difficult places to dress wounds, such as areas on the face. This technique has been so successful that commercial microbial cellulose products, such as Biofill ®, have been developed.[1] Another microbial cellulose commercial treatment product is XCell produced by the Xylos Corporation, which is mainly used to treat wounds from venous ulcers.[41] Studies have also been performed where traditional gauze dressings are treated with a microbial cellulose biopolymer to enhance the properties of the gauze. In addition to increasing the drying time and water holding abilities, liquid medicines were able to be absorbed by the microbial cellulose coated gauze, allowing them to work at the injury site.[42]

Microbial cellulose has also been used for internal treatments, such as bone grafts and other tissue engineering and regeneration. A key ability of microbial cellulose for medical applications is that it can easily be molded into various shapes while still retaining all of its useful properties. By molding microbial cellulose into long, hollow tubes, they can be used as replacement structures for several different areas, such as the cardiovascular system, the digestive tract, urinary tract, or the trachea. A recent application of microbial cellulose has been as synthetic blood vessels and stents. The cellulose can also be modeled into mesh membranes that can be used for internal replacement structures, such as the brain's outer membrane, the dura mater. In addition to replacement, these structures have also been used as grafts to interact with existing internal biological material. Microbial cellulose has also been used in guided tissue regeneration.[41] Bioprocess ® and Gengiflex ® are some of the common trademarked products of microbial cellulose that now have wide applications in surgery and dental implants. One example involves the recovery of periodontal tissues by separating oral epithelial cells and gingival connective tissues from the treated root surface.[1]

Current research/future applications edit

An area of active research on microbial cellulose is in the area of electronic paper. Currently, plant cellulose is used to produce the bulk of traditional paper, but due to its low purity it must be mixed with other substances such as lignin. However, due to microbial cellulose's higher purity and microfibril structure, it may prove to be an excellent candidate for an electronic paper substrate. Microbial cellulose can be fashioned into sheets approximately 100 micrometers thick, about the thickness of normal paper, by a wet synthesis process. The microbial cellulose produces a sturdy substrate with a microfibril structure that allows the paper to be implanted with dopants. Through the application of solutions to the microbial cellulose paper, conductive dopants and electrochromic dyes can be placed into the microfibril structure. The bistable dyes change from clear to dark upon the application of the appropriate voltages, which when placed in a pixel structure, would allow images to be formed. This technology is still in the research stage and has not yet been scaled to commercial production levels. Further research has been done to apply bacterial cellulose as a substrate in electronic devices with the potential to be used as e-book tablets, e-newspapers, dynamic wall papers, rewritable maps and learning tools.[43] Another possible example of bacterial cellulose use in the electronics industry includes the manufacture of organic light-emitting diodes (OLEDs).[33]

Challenges/limitations edit

Due to the inefficient production process, the current price of bacterial cellulose remains too high to make it commercially attractive and viable on a large scale.[33] Traditional production methods cannot produce microbial cellulose in commercial quantities, so further advancements with reactor based production must be achieved to be able to market many microbial cellulose products.[27]

See also edit

References edit

  1. ^ a b c d e f g Jonas, R.; Farah, Luiz F. (1998). "Production and application of microbial cellulose". Polymer Degradation and Stability. 59 (1–3): 101–106. doi:10.1016/S0141-3910(97)00197-3.
  2. ^ a b c d e f Iguchi, M.; Yamanaka, S.; Budhiono, A. (2000). "Bacterial cellulose' a masterpiece of nature's arts". Journal of Materials Science. 35 (2): 261–270. Bibcode:2000JMatS..35..261I. doi:10.1023/A:1004775229149. S2CID 81685441.
  3. ^ Brown, A.J. J. Chem. Soc.,49,172, 432(1886);51,643(1887)
  4. ^ Browne, C.A., J. Chem. Soc., 28, 453 (1906)
  5. ^ Tarr, H.L.A., Hibbery, H. Can. J. Research, 4, 372 (1931)
  6. ^ a b c d A. Steinbuhel, "Bacterial Cellulose." Biopolymers. Weinheim: Wiley-VCH, 2001. Print.
  7. ^ a b c Bajaj, I; Chawla, P; Singhal, R; Survase, S. "Microbial cellulose: fermentative production and applications". Food Technology and Biotechnology. 47 (2): 107–124.
  8. ^ M. Shoda, Y. Sugano (2005) Recent advances in bacterial cellulose production, Biotechnol. Bioprocess Eng. 10 1-8
  9. ^ S. Bielecki, A. Krystynowicz, M. Turkiewicz, H. Kalinowska: Bacterial Cellulose. In: Polysaccharaides and Polyamides in the Food Industry, A. Steinbuchel, S.K. Rhee (Eds.), Wiley-VCH Verlag, Weinhein, Germany (2005) pp. 31-85
  10. ^ a b Brown, Jr (1987). "The biosynthesis of cellulose". Food Hydrocolloids. 1 (5–6): 345–351. doi:10.1016/S0268-005X(87)80024-3.
  11. ^ Delmer, D.P.; Amor, Y. (1995). "Cellulose biosynthesis". Plant Cell. 7 (7): 987–1000. doi:10.1105/tpc.7.7.987. PMC 160898. PMID 7640530.
  12. ^ a b Iannino, N.I. De; Couso, R.O.; Dankert, M.A. (1998). "Lipid-linked intermediates and the synthesis of acetan in Acetobacter xylinum". J. Gen. Microbiol. 134 (6): 1731–1736. doi:10.1099/00221287-134-6-1731.
  13. ^ Morgan, Jacob L. W.; McNamara, Joshua T.; Fischer, Michael; Rich, Jamie; Chen, Hong-Ming; Withers, Stephen G.; Zimmer, Jochen (2016). "Observing cellulose biosynthesis and membrane translocation in crystallo". Nature. 531 (7594): 329–334. doi:10.1038/nature16966. ISSN 0028-0836. PMC 4843519. PMID 26958837.
  14. ^ Ramana, K.V.; Singh, L.; Singh, Lokendra (2000). "Effect of various carbon and nitrogen sources on cellulose synthesis by Acetobacter xylinum". World J. Microbiol. Biotechnol. 16 (3): 245–248. doi:10.1023/A:1008958014270. S2CID 83658095.
  15. ^ a b Masaoka, S.; Ohe, T.; Sakota, N. (1993). "Production of cellulose from glucose by Acetobacter xylinum". J. Ferment. Bioeng. 75: 18–22. doi:10.1016/0922-338X(93)90171-4.
  16. ^ Park, J.K.; Jung, J.Y.; Park, Y.H. (2003). "Cellulose production by Gluconacetobacter hansenii in a medium containing ethanol". Biotechnol. Lett. 25 (24): 2055–2059. doi:10.1023/B:BILE.0000007065.63682.18. PMID 14969408. S2CID 6660565.
  17. ^ Keshk, S.; Sameshima, K. (2006). "Influence of lignosulfonate on crystal structure and productivity of bacterial cellulose in a static culture". Enzyme and Microbial Technology. 40: 4–8. doi:10.1016/j.enzmictec.2006.07.037.
  18. ^ Toda, K.; Asakura, T.; Fukaya, M.; Entani, E.; Kawamura, Y. (1997). "Cellulose production by acetic acid-resistant Acetobacter xylinum". J. Ferment. Bioeng. 84 (3): 228–231. doi:10.1016/S0922-338X(97)82059-4.
  19. ^ Bae, S.; Shoda, M. (2005). "Statistical optimization of culture conditions for bacterial cellulose production using Box-Behnken design". Biotechnol. Bioeng. 90 (1): 20–28. doi:10.1002/bit.20325. PMID 15712301.
  20. ^ Premjet, S.; Premjet, D.; Ohtani, Y. (2007). "The effect of ingredients of sugar cane molasses on bacterial cellulose production by Acetobacter xylinum ATCC 10245". Sen-I Gakkaishi. 63 (8): 193–199. doi:10.2115/fiber.63.193.
  21. ^ Son, H.J.; Kim, H.G.; Kim, K.K.; Kim, H.S.; Kim, Y.G.; Lee, S.J. (2003). "Increased production of bacterial cellulose by Acetobacter sp. V6 in synthetic media under shaking culture conditions". Bioresour. Technol. 86 (3): 215–219. doi:10.1016/S0960-8524(02)00176-1. PMID 12688462.
  22. ^ Matsunaga, M.; Tsuchida, T.; Matsushita, K.; Adachi, O.; Yoshinaga, F. (1996). "A synthetic medium for bacterial cellulose production by Acetobacter xylinum subsp. Sucrofermentans". Biosci. Biotechnol. Biochem. 60 (4): 575–579. doi:10.1271/bbb.60.575.
  23. ^ Chao, Y.; Mitari, M.; Sugano, Y.; Shoda, M. (2001). "Effect of addition of water-soluble polysaccharides on bacterial production in a 50-L airlift reactor". Biotechnol. Prog. 17 (4): 781–785. doi:10.1021/bp010046b. PMID 11485444. S2CID 33497254.
  24. ^ Zhou, L.L.; Sun, D.P.; Hu, L.Y.; Li, Y.W.; Yang, J.Z. (2007). "Effect of addition of sodium alginate on bacterial cellulose production by Acetobacter xylinum". J. Ind. Microbiol. Biotechnol. 34 (7): 483–489. doi:10.1007/s10295-007-0218-4. PMID 17440758.
  25. ^ Hestrin, S.; Schramm, M. (1954). "Synthesis of cellulose by Acetobacter xylinum: II. Preparation of freeze-dried cells capable of polymerizing glucose to cellulose". Biochem. J. 58 (2): 345–352. doi:10.1042/bj0580345. PMC 1269899. PMID 13208601.
  26. ^ Shirai, A.; Takahashi, M.; Kaneko, H.; Nishimura, S.; Ogawa, M.; Nishi, N.; Tokura, S. (1994). "Biosynthesis of a novel polysaccharide by Acetobacter xylinum". Int. J. Biol. Macromol. 16 (6): 297–300. doi:10.1016/0141-8130(94)90059-0. PMID 7727342.
  27. ^ a b c Kim, J.Y.; Kim, J.N.; Wee, Y.J.; Park, D.H.; Ryu, H.W. (2007). "Bacterial cellulose production by Gluconacetobacter sp. RKY5 in a rotary biofilm contactor". Appl. Biochem. Biotechnol. 137–140 (1–12): 529–537. doi:10.1007/s12010-007-9077-8. PMID 18478414. S2CID 38869200.
  28. ^ Krystynowicz, A.; Czaja, W.; Wiktorowska-Jezierska, A.; Goncalves-Miskiewicz, M.; Turkiewicz, M.; Bielecki, S. (2002). "Factors affecting the yield and properties of bacterial cellulose". J. Ind. Microbiol. Biotechnol. 29 (4): 189–195. doi:10.1038/sj.jim.7000303. PMID 12355318. S2CID 505777.
  29. ^ Jung, J.Y.; Khan, T.; Park, J.K.; Chang, H.N. (2007). "Production of bacterial cellulose by Gluconacetobacter hansenii using a novel bioreactor equipped with a spin filter". Korean J. Chem. Eng. 24 (2): 265–271. doi:10.1007/s11814-007-5058-4. S2CID 56424486.
  30. ^ Yoshino, T.; Asakura, T.; Toda, K. (1996). "cellulose production by Acetobacter pasteurianus on silicone membrane". J. Ferment. Bioeng. 81: 32–36. doi:10.1016/0922-338X(96)83116-3.
  31. ^ a b Klemm, D.; Schumann, D.; Udhardt, U.; Marsch, S. (2001). "Bacterial synthesized cellulose — artificial blood vessels for microsurgery". Progress in Polymer Science. 26 (9): 1561–1603. doi:10.1016/S0079-6700(01)00021-1.
  32. ^ a b c Ross, P.; Mayer, R.; Benziman, M. (1991). "Cellulose biosynthesis and function in bacteria". Microbiol. Mol. Biol. Rev. 55 (1): 35–58. doi:10.1128/mr.55.1.35-58.1991. PMC 372800. PMID 2030672.
  33. ^ a b c d e Vandamme, E.J.; Baets, S. De; Vanbaelen, A.; Joris, K.; Wulf, P. De (1998). "Improved production of bacterial cellulose and its application potential". Polymer Degradation and Stability. 59 (1–3): 93–99. doi:10.1016/S0141-3910(97)00185-7.
  34. ^ Sun, D.; Yang, J.; Wan, X. (2010). "Bacterial cellulose/TiO2 hybrid nanofibers prepared by the surface hydrolysis method with molecular precision". Nanoscale. 2 (2): 287–292. Bibcode:2010Nanos...2..287S. doi:10.1039/b9nr00158a. PMID 20644807.
  35. ^ a b c Lynd, L.; Weimer, P.; Van Zyl, WH; Pretorius, IS (2002). "Microbial Cellulose Utilization: Fundamentals and Biotechnology". Microbiology and Molecular Biology Reviews. 66 (3): 506–577. doi:10.1128/MMBR.66.3.506-577.2002. PMC 120791. PMID 12209002.
  36. ^ a b c d e Nishi, Y.; et al. (1990). "The structure and mechanical properties of sheets prepared from bacterial cellulose". Journal of Materials Science. 25 (6): 2997–3001. Bibcode:1990JMatS..25.2997N. doi:10.1007/BF00584917. S2CID 135518566.
  37. ^ Yoshinaga, Fumihiro; Tonouchi, N.; Watanabe, K. (1997). "Research progress in production of bacterial cellulose by aeration and agitation culture and its application as a new industrial material". Biosci. Biotechnol. Biochem. 61 (2): 219–224. doi:10.1271/bbb.61.219.
  38. ^ Kuga, S.; Brown, R. M. (1988). "Silver labeling of the reducing ends of bacterial cellulose". Carbohydrate Research. 180 (2): 345–350. doi:10.1016/0008-6215(88)80091-0.
  39. ^ Legge, Raymond (1990). "Microbial cellulose as a speciality chemical". Biotechnology Advances. 8 (2): 303–319. doi:10.1016/0734-9750(90)91067-Q. PMID 14546639.
  40. ^ Okiyama, A., Motoki, M. and Yamanaka, S., Food Hydeocoll., 1992, 6, 479.
  41. ^ a b Czaja, Wojciech; et al. (2007). "The Future Prospects of Microbial Cellulose in Biomedical Applications". Biomacromolecules. 8 (1): 1–12. doi:10.1021/bm060620d. PMID 17206781.
  42. ^ Meftahi, A.; et al. (2009). "The effects of cotton gauze coating with microbial cellulose". Cellulose. 17: 199–204. doi:10.1007/s10570-009-9377-y. S2CID 97758926.
  43. ^ Shah, J.; Brown, M. (2005). "Towards electronic paper displays made from microbial cellulose". Applied Microbiology and Biotechnology. 66 (4): 352–355. doi:10.1007/s00253-004-1756-6. PMID 15538556. S2CID 25566915.

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December 18, 2023
bacterial, cellulose, organic, compound, with, formula, produced, certain, types, bacteria, while, cellulose, basic, structural, material, most, plants, also, produced, bacteria, principally, genera, acetobacter, sarcina, ventriculi, agrobacterium, bacterial, . Bacterial cellulose is an organic compound with the formula C6 H10 O5 n produced by certain types of bacteria While cellulose is a basic structural material of most plants it is also produced by bacteria principally of the genera Acetobacter Sarcina ventriculi and Agrobacterium Bacterial or microbial cellulose has different properties from plant cellulose and is characterized by high purity strength moldability and increased water holding ability 1 In natural habitats the majority of bacteria synthesize extracellular polysaccharides such as cellulose which form protective envelopes around the cells While bacterial cellulose is produced in nature many methods are currently being investigated to enhance cellulose growth from cultures in laboratories as a large scale process By controlling synthesis methods the resulting microbial cellulose can be tailored to have specific desirable properties For example attention has been given to the bacteria Komagataeibacter xylinum due to its cellulose s unique mechanical properties and applications to biotechnology microbiology and materials science Historically bacterial cellulose has been limited to the manufacture of Nata de coco a South East Asian food product 2 With advances in the ability to synthesize and characterize bacterial cellulose the material is being used for a wide variety of commercial applications including textiles cosmetics and food products as well as medical applications Many patents have been issued in microbial cellulose applications and several active areas of research are attempting to better characterize microbial cellulose and utilize it in new areas 1 A wet microbial cellulose pellicle being removed from a culture Contents 1 History 2 Biosynthesis 2 1 Bacterial sources 2 2 General process 2 2 1 Fermentation production 2 2 2 Reactor based production 3 Structure and properties 3 1 Differences between plant and bacterial cellulose 3 2 Macro structure 3 3 Properties and characterization 4 Applications 4 1 Food 4 2 Commercial products 4 3 Medical 4 4 Current research future applications 4 5 Challenges limitations 5 See also 6 References 7 External linksHistory editAs a material cellulose was first discovered in 1838 by Anselme Payen Payen was able to isolate the cellulose from the other plant matter and chemically characterize it In one of its first and most common industrial applications cellulose from wood pulp was used to manufacture paper It is ideal for displaying information in print form due to its high reflectivity high contrast low cost and flexibility The discovery of cellulose produced by bacteria specifically from the Acetobacter xylinum was accredited to A J Brown in 1886 with the synthesis of an extracellular gelatinous mat 3 However it was not until the 20th century that more intensive studies on bacterial cellulose were conducted Several decades after the initial discovery of microbial cellulose C A Browne studied the cellulose material obtained by fermentation of Louisiana sugar cane juice and affirmed the results by A J Brown 4 Other researchers reported the formation of cellulose by other various organisms such as the Acetobacter pasteurianum Acetobacter rancens Sarcina ventriculi and Bacterium xylinoides In 1931 Tarr and Hibbert published the first detailed study of the formation of bacterial cellulose by conducting a series of experiments to grow A xylinum on culture mediums 5 In the mid 1900s Hestrin et al proved the necessity of glucose and oxygen in the synthesis of bacterial cellulose Soon after Colvin detected cellulose synthesis in samples containing cell free extract of A xylinum glucose and ATP 6 In 1949 the microfibrillar structure of bacterial cellulose was characterized by Muhlethaler 7 Further bacterial cellulose studies have led to new uses and applications for the material Biosynthesis edit nbsp Chemical structure of celluloseBacterial sources edit Bacteria that produce cellulose include Gram negative bacteria species such as Acetobacter Azotobacter Rhizobium Pseudomonas Salmonella Alcaligenes and Gram positive bacteria species such as Sarcina ventriculi 8 The most effective producers of cellulose are A xylinum A hansenii and A pasteurianus Of these A xylinum is the model microorganism for basic and applied studies on cellulose due to its ability to produce relatively high levels of polymer from a wide range of carbon and nitrogen sources 9 General process edit nbsp Biochemical Pathway for Cellulose SynthesisThe synthesis of bacterial cellulose is a multistep process that involve two main mechanisms the synthesis of uridine diphosphoglucose UDPGIc followed by the polymerization of glucose into long and unbranched chains the b 1 4 glucan chain by cellulose synthase Specifics on the cellulose synthesis has been extensively documented 10 11 The former mechanism is well known while the latter still needs exploring The production of UDPGIc starts with carbon compounds such as hexoses glycerol dihydroxyacetone pyruvate and dicarboxylic acids entering the Krebs cycle gluconeogenesis or the pentose phosphate cycle depending on what carbon source is available It then goes through phosphorylation along with catalysis followed by isomerization of the intermediate and a process known as UDPGIc pyrophosphorylase to convert the compounds into UDPGIc a precursor to the production of cellulose The polymerization of glucose into the b 1 4 glucan chain has been hypothesized to either involve a lipid intermediate 12 or not to involve a lipid intermediate 10 though structural enzymology studies and in vitro experiments indicate that polymerization can occur by direct enzymatic transfer of a glucosyl moiety from a nucleotide sugar to the growing polysaccharide 13 A xylinum usually converts carbon compounds into cellulose with around 50 efficiency 12 Fermentation production edit Bacterial Strains that Produce Cellulose Micro organism Carbon source Supple ment Culture time h Yield g L A xylinum BRCS glucose ethanol oxygen 50 15 30G hansenii PJK KCTC 10505 BP glucose oxygen 48 1 72glucose ethanol 72 2 50Aceto bacter sp V6 glucose ethanol 192 4 16Aceto bacter sp A9 glucose ethanol 192 15 20A xylinum ssp Sucro fermentans BPR2001 molasses none 72 7 82fructose agar oxygen 72 14 10fructose agar 56 12 00fructose oxygen 52 10 40fructose agar oxygen 44 8 70A xylinum E25 glucose no 168 3 50G xylinus K3 mannitol green tea 168 3 34G xylinus IFO 13773 glucose lignosulphonate 168 10 10A xylinum NUST4 1 glucose sodium alginate 120 6 00G xylinus IFO 13773 sugar cane molasses no 168 5 76G xylinus sp RKY5 glycerol no 144 5 63Glucon aceto bacter sp St 60 12 and Lacto bacillus Mali JCM1116 co culture sucrose no 72 4 20Cellulose production depends heavily on several factors such as the growth medium environmental conditions and the formation of byproducts The fermentation medium contains carbon nitrogen and other macro and micro nutrients required for bacteria growth Bacteria are most efficient when supplied with an abundant carbon source and minimal nitrogen source 14 Glucose and sucrose are the most commonly used carbon sources for cellulose production while fructose maltose xylose starch and glycerol have been tried 15 Sometimes ethanol may be used to increase cellulose production 16 The problem with using glucose is that gluconic acid is formed as a byproduct which decreases the pH of the culture and in turn decreases the production of cellulose Studies have shown that gluconic acid production can be decreased in the presence of lignosulfonate 17 Addition of organic acids specifically acetic acid also helped in a higher yield of cellulose 18 Studies of using molasses medium in a jar fermentor 19 as well as added components of sugarcane molasses 20 on certain strains of bacteria have been studied with results showing increases in cellulose production Addition of extra nitrogen generally decreases cellulose production while addition of precursor molecules such as amino acids 21 and methionine improved yield Pyridoxine nicotinic acid p aminobenzoic acid and biotin are vitamins important for cellulose production whereas pantothenate and riboflavin have opposing effects 22 In reactors where the process is more complex water soluble polysaccharides such as agar 23 acetan and sodium alginate 24 are added to prevent clumping or coagulation of bacterial cellulose The other main environmental factors affecting cellulose production are pH temperature and dissolved oxygen According to experimental studies the optimal temperature for maximum production was between 28 and 30 C 25 For most species the optimal pH was between 4 0 and 6 0 15 Controlling pH is especially important in static cultures as the accumulation of gluconic acetic or lactic acid decreases the pH far lower than the optimal range Dissolved oxygen content can be varied with stirrer speed as it is needed for static cultures where substrates need to be transported by diffusion 26 Reactor based production edit Static and agitated cultures are conventional ways to produce bacterial cellulose Both static and agitated cultures are not feasible for large scale production as static cultures have a long culture period as well as intensive manpower and agitated cultures produce cellulose negative mutants alongside its reactions due to rapid growth 27 Thus reactors are designed to lessen culture time and inhibit the conversion of bacterial cellulose producing strains into cellulose negative mutants Common reactors used are the rotating disk reactor 28 the rotary biofilm contactor RBC 27 a bioreactor equipped with a spin filter 29 and a reactor with a silicone membrane 30 Structure and properties editTypes of cellulose 1 Genus Cellulose type Biological roleAcetobacter Extracellular pellicle ribbons Maintain aerobicenvironmentAchromobacter Ribbons FlocculationAerobacter Fibrils FlocculationAgrobacterium Short fibrils Attachment to plantsAlcaligenes Fibrils FlocculationPseudomonas Non distinct FlocculationRhozobium Short fibrils Attachment to plantsSarcina Amorphous UnknownDifferences between plant and bacterial cellulose edit As the Earth s most common organic material cellulose can be classified into plant cellulose and bacterial cellulose both of which are naturally occurring Plant cellulose which makes up the cell walls of most plants is a tough mesh like bulkwork in which cellulose fibrils are the primary architectural elements While bacterial cellulose has the same molecular formula as plant cellulose it has significantly different macromolecular properties and characteristics 6 In general microbial cellulose is more chemically pure containing no hemicellulose or lignin has a higher water holding capacity and hydrophilicity greater tensile strength resulting from a larger amount of polymerization ultrafine network architecture Furthermore bacterial cellulose can be produced on a variety of substrates and can be grown to virtually any shape due to the high moldability during formation 31 Additionally bacterial cellulose has a more crystalline structure compared to plant cellulose and forms characteristic ribbon like microfibrils 1 A hallmark of microbial cellulose these thin microfibrils are significantly smaller than those in plant cellulose making bacterial cellulose much more porous 7 nbsp Three way branching point mechanismMacro structure edit Cellulose is composed of carbon oxygen and hydrogen and is classified as a polysaccharide indicating it is a carbohydrate that exhibits polymeric characteristics Cellulose is composed of straight chain polymers whose base units of glucose are held together by beta linkages The structural role of cellulose in cell walls has been likened to that of the glass strands of fiberglass or to the supporting rods within reinforced concrete citation needed Cellulose fibrils are highly insoluble and inelastic and because of their molecular configuration have a tensile strength comparable to that of steel citation needed Consequently cellulose imparts a unique combination of chemical resilience and mechanical support and flexibility to the tissues in which it resides 32 Bacterial cellulose produced by Acetobacter species displays unique properties including high mechanical strength high water absorption capacity high crystallinity and an ultra fine and highly pure fiber network structure 33 One of the most important features of bacterial cellulose is its chemical purity In addition to this bacterial cellulose is stable towards chemicals and at high temperatures 34 Bacterial cellulose has been suggested to have a construction like a cage which protects the cell from foreign material and heavy metal ions while still allowing nutrients to be supplied easily by diffusion 2 35 Bacterial cellulose was described by Louis Pasteur as a sort of moist skin swollen gelatinous and slippery Although the solid portion in the gel is less than one percent it is almost pure cellulose containing no lignin and other foreign substances 2 Although bacterial cellulose is obtained in the form of a highly swollen gel the texture is quite unique and different from typical gels Cellulose has a high swollen fiber network resulting from the presence of pore structures and tunnels within the wet pellicle Plant cellulose water retention values 60 while bacterial cellulose has a water retention value of 1000 31 The formation of the cellulose pellicle occurs on the upper surface of the supernatant film A large surface area is important for a good productivity The cellulose formation occurs at the air cellulose pellicle interface and not at the medium cellulose interface Thus oxygen is an important factor for cellulose production 1 After an inducing and a rapid growth period the thickness increases steadily Fibrils appear to be not necessarily linear but contain some three way branching points along their length This type of branching is considered to be related to the unique characteristics of this material and occurs from branching points produced by binary fission 36 nbsp Sizes of synthetic and naturally occurring fibers 37 Properties and characterization edit Sheet shaped material prepared from bacterial cellulose has remarkable mechanical properties According to Brown the pellicle of bacterial cellulose was very tough especially if an attempt was made to tear it across its plane of growth 2 The Young s modulus for bacterial cellulose has been reported to be as high as 15 GPa across the plane of the sheet whereas the highest values attained in the past by polymeric films or sheets is lt 10GPa at most The sheet s high Young s modulus has been attributed to the unique super molecular structure in which fibrils of biological origin are preserved and bound tightly by hydrogen bonds This Young s modulus does not vary with temperature nor the cultivation process used The very high Young s modulus of this material must be ascribed to its super molecular structure 35 36 This property arises from adjacently aligned glucan chains participating in inter and intrachain hydrogen bonding 32 Bacterial cellulose subfibrils are crystallized into microfibrils which group to form bundles that then form ribbons These fibers are two orders of magnitude thinner than cellulose fibers produced by pulping wood 6 Today it is known that the pellicle comprises a random assembly of fibrils lt 130 nm wide which are composed of a bundle of much finer microfibrils 2 to 4 nm diameter It is also known that the pellicle gives a film or sheet when dried if the shrinkage across the plane is restricted 36 The ultrafine ribbons of microbial cellulose form a dense reticulated structure stabilized by extensive hydrogen bonding Bacterial cellulose is also distinguished from its plant counterpart by a high crystallinity index above 60 Two common crystalline forms of cellulose designated as I and II are distinguishable by X ray nuclear magnetic resonance NMR Raman spectroscopy and infrared analysis 6 Bacterial cellulose belongs crystallographically to Cellulose I common with natural cellulose of vegetable origin in which two cellulose units are arranged parallel in a unit cell 2 38 The term Cellulose I is used for this parallel arrangement whereas crystalline fibrils bearing antiparallel polyglucan chains arise forming the thermodynamically stable Cellulose II 32 The molecular arrangement in the sheet confirmed by X ray diffraction was such that the molecular chain axis lay randomly perpendicular to the thickness such that the 1 1 0 plane was oriented parallel to the surface 36 Although cellulose forms a distinct crystalline structure cellulose fibers in nature are not purely crystalline In addition to the crystalline and amorphous regions cellulose fibers contain various types of irregularities such as kinks or twists of the microfibrils or voids such as surface micropores large pits and capillaries Thus the total surface area of a cellulose fiber is much greater than the surface area of an ideally smooth fiber of the same dimension The net effect of structural heterogeneity within the fiber is that the fibers are at least partially hydrated by water when immersed in aqueous media and some micropores and capillaries are sufficiently spacious to permit penetration 35 Scanning electron microscopy of a fractured edge has revealed a pile of very thin layers It is suggested that these fibrils in layers are bound through interfibrillar hydrogen bonds just as in pulp papers but the density of the interfibrillar hydrogen bonds must be much higher as the fibrils are finer hence the contact area is larger 36 Applications editBacterial cellulose has a wide variety of current and potential future applications Due to its many unique properties it has been used in the food industry the medical field commercial and industrial products and other technical areas Bacterial cellulose is a versatile structural material allowing it to be shaped in a variety of ways to accommodate different uses A number of patents have been issued for processes involving this material 39 Bacterial cellulose pellicles were proposed as a temporary skin substitute in case of human burns and other dermal injuries 44 Fontana J D et al 1990 Acetobacter cellulose pellicle as a temporary skin substituite Applie d Biochemistry and Biotechnology Humana Press 24 25 253 264 Food edit The oldest known use of bacterial cellulose is as the raw material of nata de pina a traditional sweet candy dessert of the Philippines Several natural colored pigments oxycarotenoids anthocyanins and related antioxidants and free radical scavengers were incorporated in to bacterial cellulose cubes in order to render the dessert more attractive 45 Fontana J D et al 2017 Handbook of Food Bioengineering Elsevier Academic Press chapter 7 New Insights on Bacterial Cellulose pages 213 249 Bacterial cellulose has also been used as a thickener to maintain the viscosity in food and as a stabilizing agent Due to its texture and fiber content it has been added to many food products as a dietary fiber A specific example is Cellulon which is a bulking agent used as a food ingredient to act as a thickener texturizer and or calorie reducer 40 Microbial cellulose has also been used as an additive in diet beverages in Japan since 1992 specifically kombucha a fermented tea drink 7 Commercial products edit Bacterial cellulose also has wide applications in commercial industries In papermaking it is used as an ultra strength paper and as a reticulated fine fibre network with coating binding thickening and suspending characteristics 33 Due to its high sonic velocity and low dynamic loss bacterial cellulose has been used as an acoustic or filter membrane in hi fidelity loudspeakers and headphones as marketed by the Sony Corporation 2 Bacterial cellulose is also used as an additive in the cosmetic industry Furthermore it is being tested in the textile industry with the possibility of manufacturing cellulose based clothing 33 Medical edit In more modern applications microbial cellulose has become relevant in the medical sector It has been tested and successfully used as a wound dressing especially in burn cases Studies have shown that burns treated with microbial cellulose coverings healed faster than traditional treatments and had less scarring The microbial cellulose topical applications are effective due to the cellulose s water holding ability and water vapor permeability The high water holding ability provides a moist atmosphere at the injury site which is critical in healing while the wicking ability allows seepage from the wound to be removed from the site Also the microbial cellulose molds very well to the surface of the skin providing a conformal covering even in usually difficult places to dress wounds such as areas on the face This technique has been so successful that commercial microbial cellulose products such as Biofill have been developed 1 Another microbial cellulose commercial treatment product is XCell produced by the Xylos Corporation which is mainly used to treat wounds from venous ulcers 41 Studies have also been performed where traditional gauze dressings are treated with a microbial cellulose biopolymer to enhance the properties of the gauze In addition to increasing the drying time and water holding abilities liquid medicines were able to be absorbed by the microbial cellulose coated gauze allowing them to work at the injury site 42 Microbial cellulose has also been used for internal treatments such as bone grafts and other tissue engineering and regeneration A key ability of microbial cellulose for medical applications is that it can easily be molded into various shapes while still retaining all of its useful properties By molding microbial cellulose into long hollow tubes they can be used as replacement structures for several different areas such as the cardiovascular system the digestive tract urinary tract or the trachea A recent application of microbial cellulose has been as synthetic blood vessels and stents The cellulose can also be modeled into mesh membranes that can be used for internal replacement structures such as the brain s outer membrane the dura mater In addition to replacement these structures have also been used as grafts to interact with existing internal biological material Microbial cellulose has also been used in guided tissue regeneration 41 Bioprocess and Gengiflex are some of the common trademarked products of microbial cellulose that now have wide applications in surgery and dental implants One example involves the recovery of periodontal tissues by separating oral epithelial cells and gingival connective tissues from the treated root surface 1 Current research future applications edit An area of active research on microbial cellulose is in the area of electronic paper Currently plant cellulose is used to produce the bulk of traditional paper but due to its low purity it must be mixed with other substances such as lignin However due to microbial cellulose s higher purity and microfibril structure it may prove to be an excellent candidate for an electronic paper substrate Microbial cellulose can be fashioned into sheets approximately 100 micrometers thick about the thickness of normal paper by a wet synthesis process The microbial cellulose produces a sturdy substrate with a microfibril structure that allows the paper to be implanted with dopants Through the application of solutions to the microbial cellulose paper conductive dopants and electrochromic dyes can be placed into the microfibril structure The bistable dyes change from clear to dark upon the application of the appropriate voltages which when placed in a pixel structure would allow images to be formed This technology is still in the research stage and has not yet been scaled to commercial production levels Further research has been done to apply bacterial cellulose as a substrate in electronic devices with the potential to be used as e book tablets e newspapers dynamic wall papers rewritable maps and learning tools 43 Another possible example of bacterial cellulose use in the electronics industry includes the manufacture of organic light emitting diodes OLEDs 33 Challenges limitations edit Due to the inefficient production process the current price of bacterial cellulose remains too high to make it commercially attractive and viable on a large scale 33 Traditional production methods cannot produce microbial cellulose in commercial quantities so further advancements with reactor based production must be achieved to be able to market many microbial cellulose products 27 See also editMaterials science Microbiology BiotechnologyReferences edit a b c d e f g Jonas R Farah Luiz F 1998 Production and application of microbial cellulose Polymer Degradation and Stability 59 1 3 101 106 doi 10 1016 S0141 3910 97 00197 3 a b c d e f Iguchi M Yamanaka S Budhiono A 2000 Bacterial cellulose a masterpiece of nature s arts Journal of Materials Science 35 2 261 270 Bibcode 2000JMatS 35 261I doi 10 1023 A 1004775229149 S2CID 81685441 Brown A J J Chem Soc 49 172 432 1886 51 643 1887 Browne C A J Chem Soc 28 453 1906 Tarr H L A Hibbery H Can J Research 4 372 1931 a b c d A Steinbuhel Bacterial Cellulose Biopolymers Weinheim Wiley VCH 2001 Print a b c Bajaj I Chawla P Singhal R Survase S Microbial cellulose fermentative production and applications Food Technology and Biotechnology 47 2 107 124 M Shoda Y Sugano 2005 Recent advances in bacterial cellulose production Biotechnol Bioprocess Eng 10 1 8 S Bielecki A Krystynowicz M Turkiewicz H Kalinowska Bacterial Cellulose In Polysaccharaides and Polyamides in the Food Industry A Steinbuchel S K Rhee Eds Wiley VCH Verlag Weinhein Germany 2005 pp 31 85 a b Brown Jr 1987 The biosynthesis of cellulose Food Hydrocolloids 1 5 6 345 351 doi 10 1016 S0268 005X 87 80024 3 Delmer D P Amor Y 1995 Cellulose biosynthesis Plant Cell 7 7 987 1000 doi 10 1105 tpc 7 7 987 PMC 160898 PMID 7640530 a b Iannino N I De Couso R O Dankert M A 1998 Lipid linked intermediates and the synthesis of acetan in Acetobacter xylinum J Gen Microbiol 134 6 1731 1736 doi 10 1099 00221287 134 6 1731 Morgan Jacob L W McNamara Joshua T Fischer Michael Rich Jamie Chen Hong Ming Withers Stephen G Zimmer Jochen 2016 Observing cellulose biosynthesis and membrane translocation in crystallo Nature 531 7594 329 334 doi 10 1038 nature16966 ISSN 0028 0836 PMC 4843519 PMID 26958837 Ramana K V Singh L Singh Lokendra 2000 Effect of various carbon and nitrogen sources on cellulose synthesis by Acetobacter xylinum World J Microbiol Biotechnol 16 3 245 248 doi 10 1023 A 1008958014270 S2CID 83658095 a b Masaoka S Ohe T Sakota N 1993 Production of cellulose from glucose by Acetobacter xylinum J Ferment Bioeng 75 18 22 doi 10 1016 0922 338X 93 90171 4 Park J K Jung J Y Park Y H 2003 Cellulose production by Gluconacetobacter hansenii in a medium containing ethanol Biotechnol Lett 25 24 2055 2059 doi 10 1023 B BILE 0000007065 63682 18 PMID 14969408 S2CID 6660565 Keshk S Sameshima K 2006 Influence of lignosulfonate on crystal structure and productivity of bacterial cellulose in a static culture Enzyme and Microbial Technology 40 4 8 doi 10 1016 j enzmictec 2006 07 037 Toda K Asakura T Fukaya M Entani E Kawamura Y 1997 Cellulose production by acetic acid resistant Acetobacter xylinum J Ferment Bioeng 84 3 228 231 doi 10 1016 S0922 338X 97 82059 4 Bae S Shoda M 2005 Statistical optimization of culture conditions for bacterial cellulose production using Box Behnken design Biotechnol Bioeng 90 1 20 28 doi 10 1002 bit 20325 PMID 15712301 Premjet S Premjet D Ohtani Y 2007 The effect of ingredients of sugar cane molasses on bacterial cellulose production by Acetobacter xylinum ATCC 10245 Sen I Gakkaishi 63 8 193 199 doi 10 2115 fiber 63 193 Son H J Kim H G Kim K K Kim H S Kim Y G Lee S J 2003 Increased production of bacterial cellulose by Acetobacter sp V6 in synthetic media under shaking culture conditions Bioresour Technol 86 3 215 219 doi 10 1016 S0960 8524 02 00176 1 PMID 12688462 Matsunaga M Tsuchida T Matsushita K Adachi O Yoshinaga F 1996 A synthetic medium for bacterial cellulose production by Acetobacter xylinum subsp Sucrofermentans Biosci Biotechnol Biochem 60 4 575 579 doi 10 1271 bbb 60 575 Chao Y Mitari M Sugano Y Shoda M 2001 Effect of addition of water soluble polysaccharides on bacterial production in a 50 L airlift reactor Biotechnol Prog 17 4 781 785 doi 10 1021 bp010046b PMID 11485444 S2CID 33497254 Zhou L L Sun D P Hu L Y Li Y W Yang J Z 2007 Effect of addition of sodium alginate on bacterial cellulose production by Acetobacter xylinum J Ind Microbiol Biotechnol 34 7 483 489 doi 10 1007 s10295 007 0218 4 PMID 17440758 Hestrin S Schramm M 1954 Synthesis of cellulose by Acetobacter xylinum II Preparation of freeze dried cells capable of polymerizing glucose to cellulose Biochem J 58 2 345 352 doi 10 1042 bj0580345 PMC 1269899 PMID 13208601 Shirai A Takahashi M Kaneko H Nishimura S Ogawa M Nishi N Tokura S 1994 Biosynthesis of a novel polysaccharide by Acetobacter xylinum Int J Biol Macromol 16 6 297 300 doi 10 1016 0141 8130 94 90059 0 PMID 7727342 a b c Kim J Y Kim J N Wee Y J Park D H Ryu H W 2007 Bacterial cellulose production by Gluconacetobacter sp RKY5 in a rotary biofilm contactor Appl Biochem Biotechnol 137 140 1 12 529 537 doi 10 1007 s12010 007 9077 8 PMID 18478414 S2CID 38869200 Krystynowicz A Czaja W Wiktorowska Jezierska A Goncalves Miskiewicz M Turkiewicz M Bielecki S 2002 Factors affecting the yield and properties of bacterial cellulose J Ind Microbiol Biotechnol 29 4 189 195 doi 10 1038 sj jim 7000303 PMID 12355318 S2CID 505777 Jung J Y Khan T Park J K Chang H N 2007 Production of bacterial cellulose by Gluconacetobacter hansenii using a novel bioreactor equipped with a spin filter Korean J Chem Eng 24 2 265 271 doi 10 1007 s11814 007 5058 4 S2CID 56424486 Yoshino T Asakura T Toda K 1996 cellulose production by Acetobacter pasteurianus on silicone membrane J Ferment Bioeng 81 32 36 doi 10 1016 0922 338X 96 83116 3 a b Klemm D Schumann D Udhardt U Marsch S 2001 Bacterial synthesized cellulose artificial blood vessels for microsurgery Progress in Polymer Science 26 9 1561 1603 doi 10 1016 S0079 6700 01 00021 1 a b c Ross P Mayer R Benziman M 1991 Cellulose biosynthesis and function in bacteria Microbiol Mol Biol Rev 55 1 35 58 doi 10 1128 mr 55 1 35 58 1991 PMC 372800 PMID 2030672 a b c d e Vandamme E J Baets S De Vanbaelen A Joris K Wulf P De 1998 Improved production of bacterial cellulose and its application potential Polymer Degradation and Stability 59 1 3 93 99 doi 10 1016 S0141 3910 97 00185 7 Sun D Yang J Wan X 2010 Bacterial cellulose TiO2 hybrid nanofibers prepared by the surface hydrolysis method with molecular precision Nanoscale 2 2 287 292 Bibcode 2010Nanos 2 287S doi 10 1039 b9nr00158a PMID 20644807 a b c Lynd L Weimer P Van Zyl WH Pretorius IS 2002 Microbial Cellulose Utilization Fundamentals and Biotechnology Microbiology and Molecular Biology Reviews 66 3 506 577 doi 10 1128 MMBR 66 3 506 577 2002 PMC 120791 PMID 12209002 a b c d e Nishi Y et al 1990 The structure and mechanical properties of sheets prepared from bacterial cellulose Journal of Materials Science 25 6 2997 3001 Bibcode 1990JMatS 25 2997N doi 10 1007 BF00584917 S2CID 135518566 Yoshinaga Fumihiro Tonouchi N Watanabe K 1997 Research progress in production of bacterial cellulose by aeration and agitation culture and its application as a new industrial material Biosci Biotechnol Biochem 61 2 219 224 doi 10 1271 bbb 61 219 Kuga S Brown R M 1988 Silver labeling of the reducing ends of bacterial cellulose Carbohydrate Research 180 2 345 350 doi 10 1016 0008 6215 88 80091 0 Legge Raymond 1990 Microbial cellulose as a speciality chemical Biotechnology Advances 8 2 303 319 doi 10 1016 0734 9750 90 91067 Q PMID 14546639 Okiyama A Motoki M and Yamanaka S Food Hydeocoll 1992 6 479 a b Czaja Wojciech et al 2007 The Future Prospects of Microbial Cellulose in Biomedical Applications Biomacromolecules 8 1 1 12 doi 10 1021 bm060620d PMID 17206781 Meftahi A et al 2009 The effects of cotton gauze coating with microbial cellulose Cellulose 17 199 204 doi 10 1007 s10570 009 9377 y S2CID 97758926 Shah J Brown M 2005 Towards electronic paper displays made from microbial cellulose Applied Microbiology and Biotechnology 66 4 352 355 doi 10 1007 s00253 004 1756 6 PMID 15538556 S2CID 25566915 External links edit nbsp Wikimedia Commons has media related to Bacterial cellulose Retrieved from https en wikipedia org w index php title Bacterial cellulose amp oldid 1188105305, wikipedia, wiki, book, books, library,

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