Next Article in Journal
Novel Hybrid Flax Reinforced Supersap Composites in Automotive Applications
Previous Article in Journal
Use of Fiber-Reinforced Cements in Masonry Construction and Structural Rehabilitation
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Review

Agave Americana Leaf Fibers

Department of Textiles, D.K.T.E. Society's Textile and Engineering Institute, Ichalkaranji 416115, India
*
Author to whom correspondence should be addressed.
These authors contributed equally to this work.
Submission received: 3 October 2014 / Revised: 25 November 2014 / Accepted: 19 January 2015 / Published: 5 February 2015

Abstract

:
The growing environmental problems, the problem of waste disposal and the depletion of non-renewable resources have stimulated the use of green materials compatible with the environment to reduce environmental impacts. Therefore, there is a need to design products by using natural resources. Natural fibers seem to be a good alternative since they are abundantly available and there are a number of possibilities to use all the components of a fiber-yielding crop; one such fiber-yielding plant is Agave Americana. The leaves of this plant yield fibers and all the parts of this plant can be utilized in many applications. The “zero-waste” utilization of the plant would enable its production and processing to be translated into a viable and sustainable industry. Agave Americana fibers are characterized by low density, high tenacity and high moisture absorbency in comparison with other leaf fibers. These fibers are long and biodegradable. Therefore, we can look this fiber as a sustainable resource for manufacturing and technical applications. Detailed discussion is carried out on extraction, characterization and applications of Agave Americana fiber in this paper.

1. Introduction

In view of recent global environmental issues, scientists worldwide have begun to show interest in exploiting the full potential of natural fibers and their diverse uses [1,2]. There are plenty of renewable resources obtainable from the plant kingdom [3,4], and a vast resource for different natural fibers viz. Jute, Banana, Coir, etc., which are abundantly available in many parts of world. However, there are still a number of other vegetable fibers which have not been used as textile fibers [2]. From the plant kingdom, one of the abundant sources of strong natural fiber is “Agave Americana”. Agave Americana fibers are also called “Pita Fibers”. These fibers are cellulosic in nature [3,4]. The Agave Americana plant is shown in Figure 1.
Figure 1. Agave Americana plant. Illustration courtesy: crop production guide Tamil Nadu Agricultural University, Coimbatore.
Figure 1. Agave Americana plant. Illustration courtesy: crop production guide Tamil Nadu Agricultural University, Coimbatore.
Fibers 03 00064 g001
Common names for Agave Americana are: century plant, maguey or American aloe, which is a species of flowering plant in the family Agavaceae [3,4,5,6,7]. The plant is originally native to Mexico, Arizona and Texas but cultivated worldwide as an ornamental plant. It has become naturalized in many regions of the world [2,6,8]. The genus Agave has about 275 species [9]. Agave blossoms only once during its life time and then dies, but produces suckers or adventitious shoots from the base, which continue its growth [5,6,9]. Agave plants are grown along railway lines, roadsides, and river banks and as hedge plants in dry land areas throughout many regions of the world. To date it has been grown in patches and as a border crop even in neglected conditions [9]. It has grown naturally, especially in arid and semi-arid climates [2,8]. The crop is able to grow on dry soils unsuitable for crop cultivation, and grows vigorously on dry, well drained sandy loam soils [9].
The leaves are ready for harvesting from the 3rd year onwards and the older leaves with length not less than a meter are harvested. Each plant yields 40–50 leaves/year. The life cycle of the plant is up to 8–30 years [5,6,7,9,10]. The content of fiber varies with variety from 2.5%–4.5%. The fiber color varies from milky white to golden yellow [3,4,9], and it has a hard touch due to the existence of lignin on its surface. The yield per hectare of this plant is 300 tons per annum, which gives about 6 tons of fiber [3,4].
Agave is a short stemmed plant bearing a rosette about 1.2 m wide of gray-green leaves up to 1.8 m long erect fleshy leaves, each with a spiny margin and a heavy spike at the tip. When it flowers, the spike has big yellow flowers and may reach 2.4 m to 7.6 m in height [2,5,6,9,10,11,12].

2. Extraction of Agave American Fibers

Mature Agave Americana plant leaves are harvested from the field for fiber extraction. All lower leaves, standing at an angle of more than 45° to the vertical are cut away from the plant by means of a sharp cutting tool. After harvesting, the leaves are transported to a factory for fiber extraction. Before extraction, thorns on the leaf margins and the spine at the leaf tip are removed [1]. The methods used for extraction of Agave Americana fibers from plant leaves are similar to the methods that are used for extraction of sisal fibers [12]. There are three major fiber extraction methods: mechanical extraction, chemical extraction and retting process. After extraction of fibers by any of these methods, all extracted leaves are washed away before drying. Proper drying is important as the moisture content in fiber affects fiber quality. Artificial drying results in higher grade fibers than sun drying [13]. The fibers were dried under a shade to avoid bleaching by direct sunlight. Dry fibers are then combed, sorted into different grades and packed into bales [3,4].

2.1. Mechanical Method

Historically, hand decortication was done by rural folk whereby the leaves were pounded and the pulp was scraped away with a knife [3,4,14,15,16]. Hand decortication is time consuming and needs a lot of manpower. Nowadays, decortication can be done efficiently by using mechanical decorticator. In the mechanical decoration process, leaves are crushed and beaten by a rotating wheel set with blunt knives, so that only fibers remain [3,4]. Some decorticators are fed by hand and the pulp is first scraped from half of a leaf, the leaf is withdrawn, and then the opposite half is inserted for scraping. In some machines, the whole leaf is decorticated in single insert [14].
Figure 2 gives a sectional view of the most important parts of fiber stripper/decorticator. Agave Americana plant leaf is fed through the mouthpiece, then it passes through the fluted feed rollers, which hold the leaves as they are fed in against a stationary bar, while the stripping drum is beating out the vegetable matter as the leaf passes between it and the beater bar. The stripping drum diameter, width and speed vary according to different makes. The drum, scraping against the leaf, held in position by the beating bar and feed rollers beats off the bulk of the vegetable matter and leaves the fibers somewhat roughened and with a residue of vegetable matter remaining upon it [17].
After completion of decortication and washing, the fibers are dried either with mechanical driers or in the sun. The operations of fiber removal, washing and drying must be done promptly after the leaves are cut, otherwise the gums in the leaves harden, causing the pulp to adhere with the fibers and making it difficult to clean the fibers properly [15,16,17]. Mechanical extraction methods are not efficient in the removal of cementing compounds (mostly waxes, hemicelluloses, lignin and hydrocarbons) between fibers [3,4].
Figure 2. Sketch of simple fiber decorticator.
Figure 2. Sketch of simple fiber decorticator.
Fibers 03 00064 g002

2.2. Chemical Method

Chemical fiber extraction involves the use of acids, alkali and enzymes. The use of acids in cellulosic fiber extraction hydrolyses lignin and hemicellulose into shorter chain pentose molecules. Acid treatment results in the formation of reactive groups and causes fibers to fibrillate, revealing a higher degree of crystallinity of fibrils. Alkali used in fiber extraction dissolves the lignocellulosic material between fibers and separates structural linkages between lignin and cellulose, which leads to increased surface area as well as a degree of polymerization and lowers the breaking strength of fibers. In enzymatic process of fiber extraction, there is degradation of lignocellulosic component in fibers by enzymes resulting increased fiber swelling and lowers the degree of polymerization. Fibers extracted by using enzymes are more pliable and softer [3,4].

2.3. Retting Process

Retting is a well studies method of extraction of fibers by a natural microbial process. Retting involves the degradation of non-fibrous matter which acts as glue between the fibers in woody plant parts and fibers without damaging the fiber cellulose. This process allows easy separation of individual fiber strands and the woody core. Since retting is a biological process, it requires both moisture and a warm temperature for microbial action to occur [18].

2.3.1. Natural Retting

It is a preferential rotting process to separate the fiber from lignocellulosic biomass without damaging the fiber cellulose. Retting is the microbial freeing of plant fibers from their surroundings [19]. The process takes up to three weeks. Retting microbes consume the non-fibrous cementing materials mainly pectin and hemicellulose. This gradually softens the leaves by the destruction of the less resisting intercellular adhesive substances. When fermentation has reached the appropriate stage, the fibers can be separated quite easily from the leaves. If retting process is allowed beyond this point, fibers decline in quality. Under-retting causes incomplete removal of gummy materials such as pectin substances, and extraction of fiber becomes difficult. Hence, the progress of retting must be observed carefully at intervals to avoid fiber damage. Though the natural retting takes more time, the process is economical.
There are two traditional types of retting include water retting and field or dew retting. In water retting, plant leaves are immersed in water (river, pond or tanks). In field or dew retting, the crop is spread in the field where rain or dew provide moisture for retting. Water retting produces fibers of greater uniformity and higher quality than fibers extracted by field retting [14].

2.3.2. Enzymatic Retting

Enzymatic retting is the process in which the pectin materials surrounding the fiber bundles are degraded by industrially produced enzymes. Enzymatic retting is faster than natural fermentation retting and results into softer fibers. It has the potential to simplify and reduce fiber extraction costs. Enzymatic retting is expected to offer greater process control, increased fiber yield and shorter processing time. Enzyme solution used in retting can be recycled several times, which makes the process eco-friendly and cost effective [14,20].
Pectinases and xylanases are the enzymes which can be used for retting plant portions for fiber release. The enzyme can be used at higher concentrations to speed up the retting process. For example: 1.5 gpl (grams per liter) of water or 3.0 gpl of water or 5.0 gpl of water can be used. The enzyme cellulase should be avoided in any enzymatic retting process of cellulosic fibers, since this will reduce the strength of the fibers [14,20,21,22].

3. Evaluation of Fibers

Agave is noted for its strong and coarse fibers, which are superior and more flexible than Manila hemp [9]. These natural cellulosic fibers are characterized by high moisture absorbency up to 9%, low-density of 1.36 gm/cm3 and high tenacity in the range of 16–41 cN/tex. The fibers obtained are flexible, smooth and lustrous and had similar burning characteristics like other known cellulosic fibers [2]. The fibers contain about 73%–78% of lignified form of cellulose [9]. Fiber surface is covered with lignin. After removal of lignin from fiber surface, fibers becomes flexible, smooth and lustrous. The fibers are very long with a mean length of 652 mm and coarser with an average linear density equal to 24 tex [3,4,13]. Generally, natural fibers are hydrophilic in nature and this was evident with Agave Americana fiber with a moisture regain and moisture content up to 9%. Agave Americana fibers greatly vary in their properties with grade as well as within the same leaf. These fibers disintegrate when exposed to strong acid and alkalis, but were resistant to weak acids and alkalis [3,4,13].
Each Agave Americana fiber consists of a number of cells, generally referred as ultimates or ultimate cells. The overlapping ultimates are held together with a waxy film to form the filament fibers. This implies that an individual fiber is made up of a complete vascular bundle or group of vascular bundles. The vascular bundle consists of transportation tissue vessels surrounded by a thick sheave of fibers cells. Each ultimate is polygonal in shape and has a lumen. Agave Americana fibers in a leaf consist of both xylem and phloem and various ensheafing cells, found scattered through a leaf pithy matrix. The cells are lignified to a greater or lesser degree and are hard in comparison with soft fibers. The entire fibro-vascular bundle serves as a unit fiber [23]. The diameter of Agave Americana fibers varies throughout the length and depends on how many ultimates are there in the cross section [24].

3.1. Fiber Morphology

Figure 3 depicts the longitudinal (Figure 3a) and cross-section (Figure 3b) views of an agave Americana fiber. By examining Agave Americana fibers with an SEM (Scanning Electron Microscope), we can observe longitudinal streaks which are characteristics of long vegetable fibers. The fiber has a composite structure. Ultimate fibers (Figure 3c) are held together by sticky and waxy substances such as lignin, pectin and hemicelluloses. The fiber surface is also covered with these substances. Due to this natural coating, Agave Americana fibers present a high resistance when they are exposed to the influence of some external factors like weak chemical agents such as acids and alkalis, as well as to UV (108 h). Agave Americana fibers occur as a technical fiber, having oval and irregular sections with a large lumen and appears as a helical structure of square shape spires. These fibers can be characterized by two parameters: the average length of a spiral side which is about 10.1 μm and the average diameter which is equal to 3.1 μm. The average diameter is very small compared to other natural fibers such as flax, sisal and alfa. This particular structure will be used to explain the mechanical behavior of the technical fibers [12,25].
Figure 3. (a) Longitudinal view of fiber; (b) cross-sectional view of fiber; (c) single elementary fiber.
Figure 3. (a) Longitudinal view of fiber; (b) cross-sectional view of fiber; (c) single elementary fiber.
Fibers 03 00064 g003

3.2. Fiber Length

Agave Americana fibers are somehow longer than sisal fibers. The bundles have a long effective length. If fiber is removed from the full length of leaf sheaths by hand stripping, the fiber strands from the middle sheaths may run as long as 2.8 m.

3.3. Fiber Diameter

The Agave Americana fibers appear as in bundles, which contain many ultimate fibers imperfectly held together by some sticky and waxy substances. The thickness of the fiber when determined using projection microscope, it was in the range of 100–150 µm. Agave Americana fibers are relative thick fiber as a result of the numerous cell ultimates that form the fiber bundle [14].

3.4. Moisture Absorption Properties

The fiber shows hydrophilic properties. This fiber absorbs more water than its own weight. Moisture content as well as moisture regain of Agave Americana fiber is found to be around 8%–9%, which is comparable to other cellulosic fibers [1,13].

3.5. Visual and Hand Evaluation

In visual and hand evaluation of Agave Americana fibers, the observation of fiber shape, color, surface texture are visually evaluated [14].

3.5.1. Physical Shape

The fiber is long, round and generally taper to a point, having one side thicker. The fibers from the lower side of the leaf are particularly finer.

3.5.2. Color

The color of the Agave Americana fiber ranges from off-white to yellowish, which is depending upon the processing technique and the processing time used for fiber extraction. The retted fiber was darkened, which can be discolored with a naturally looking light brown color, which is due to bacterial action.

3.5.3. Luster

The fibers are semi dull in appearance and one has a reason to believe that this is due to the fact that they have the uneven surface and cross-sectional shape. A fiber with an irregular cross-section scatters light in all directions, resulting in a dull appearance with few high lights. Whereas properly extracted fibers appear lustrous.

3.5.4. Texture

The fiber feels strong and durable. The dry Agave Americana fiber is stiff, harsh, coarse and hard-surfaced, which is typical characteristic of all the leaf fibers. However when fibers are wet, they become flexible, smooth and slippery.

3.6. Burning Test

When the fiber sample was brought near the flame, it burnt brightly. In the flame the fiber continued burning readily with a yellow-bright flame and continued burning even after removal of flame. The smell of burning Agave Americana fiber is like burning paper. Agave Americana fiber becomes very fragile when exposed to high temperature of up to 108 °C. The burning behavior of Agave Americana fibers is similar to that of other natural cellulosic fibers [13].

3.7. Tensile Properties

3.7.1. Mechanical Behavior

Tenacity of Agave Americana fiber is in the range of 16–41 cN/tex. The elongation of fiber at rupture is in the range of 2%–4%. This implies that Agave Americana fiber can perform well where instantaneous forces act on the fibers during the use of end product. Higher values of tensile properties of these fibers indicated that it is strong enough to be a textile fiber. It is thought that its strength is due to high degree of cellulose polymerization and crystallization processes that may be due to many years of growth. This tensile strength implies that Agave Americana fiber can function well for furnishing fabrics, carpets, floor mats, rugs, upholstery fabrics as well as in nonwovens and fiber reinforced composites.
The tensile properties of Agave Americana fiber are not uniform. This can be explained by the fact that it is a natural fiber and natural fibers are subject to growth irregularities to the extent that fibers from the same plant are not uniform in size and properties. The outer leaf sheaths produce the strongest fibers while the inner sheaths produce the weakest fibers. The innermost fibers have a high fracture strain while the peripheral fibers have lower tensile strength [14,26]. The outermost fibers have more elongation before breaking than inner fibers. The fibers are difficult to extend. This means Agave Americana fiber is rigid and has low elongation. The fiber is having lower elongation at break values. Therefore the end product manufactured using this fiber will be rigid one. The wet strength of fiber is lower than that of dry fiber. However, elongation of the break is higher when the fiber is in wet conditions [14,16]. Table 1 exhibits the comparison of mechanical properties between textile fibers.
Table 1. Comparison of mechanical properties between textile fibers.
Table 1. Comparison of mechanical properties between textile fibers.
FibersTenacity (cN/tex)Strain (%)Initial modulus (N/tex)Work fracture (mN/tex)
Agave Americana21–412–40.2–1.457.7–25.4
Sisal40–492–325–26
Flax25–262.7–3.3188
Jute29–561.2–1.917.22.7
Cotton28–483–10510.7
E Glass822.529.49.8
Polyester (HT)61713.222

3.7.2. Rupture Behavior

The fiber is more or less cracked depending on the elongation and this phenomena generates the deformation of the elementary fibers in a bundle. Figure 4 shows different levels of deformations of Agave Americana fibers. At small deformations (Figure 4a), corresponding to elastic behavior, the lignin carries the applied load without passing it to the elementary fibers. Hence we can say that at small deformations, physical and mechanical properties of technical fiber are related to physical and mechanical properties of wax and gummy matter that link elementary fibers. At medium deformations (Figure 4b), i.e., viscoelastic deformation, the elementary fibers begin to switch on without being really deformed.
Figure 4. Agave Americana fibers deformed at different levels. (a) Small deformation; (b) medium deformation; (c) high deformation. Adapted from [26]. Copyright NASA, 2007.
Figure 4. Agave Americana fibers deformed at different levels. (a) Small deformation; (b) medium deformation; (c) high deformation. Adapted from [26]. Copyright NASA, 2007.
Fibers 03 00064 g004
The spring form of the elementary fibers is responsible extension behavior of fiber at this stage. At high deformation (Figure 4c) corresponding to plastic deformation, elementary fibers begin to be deformed until the rupture. Mechanical behavior of technical fiber of Agave Americana fiber is highly related to its fine structure. At high deformation, physical and mechanical properties are related to the properties of elementary fibers. In the rupture zone, the resistance of elementary fibers, their number, their dispersion and their adhesion to the natural matrix (lignin) explain the behavior of technical fiber [26].

3.8. Chemical Properties

3.8.1. Chemical Composition

Agave Americana fibers can be considered as naturally occurring composites consisting mainly of cellulose fibrils embedded in a lignin matrix. The main constituents of these fibers are cellulose, lignin and hemicellulose. However constituents like pectin, waxes, water-soluble substances, etc. are also present in small quantities. The chemical composition of natural fibers like Agave Americana depends on various factors such as type of soil used, weather conditions, age of the plants, etc. The property of each constituent contributes to the overall properties of the fiber. Table 2 exhibits the chemical composition of Agave Americana fibers [1].
Table 2. Chemical composition of Agave Americana fibers.
Table 2. Chemical composition of Agave Americana fibers.
CompositionAmount (%)
Cellulose68–80
Hemicellulose15
Lignin5–17
Wax0.26
Moisture8

3.8.2. Effect of Different Chemicals on Agave Americana Fibers

Agave Americana fibers are stable in weak acids and weak alkalis, and has no effect on structure and tenacity of Agave Americana fibers. Therefore these fibers can be safely treated with bleaches, detergents and dyes which are weak basic or weak acidic in nature. However, in strong acids and strong bases, fibers were dissolved or distorted. The bonds connecting the subunits (i.e., ultimate fibers) are unstable to acid, which leads to loss in tensile strength of fibers. Reaction with concentrated sodium hypochlorite results in the bleaching of fibers, but after prolonged exposure, the fiber looses its strength and disintegrates. This indicates that oxidizing solutions like sodium hypochlorite should only be used when cold, diluted and according to instructions given by the manufacturer. Therefore, chlorine bleaches should be used for a short period of time and must be rinsed out thoroughly to avoid further damage to the fiber [13].

4. Applications of Agave Americana Fibers

Agave Americana fibers exhibit high tensile strength and have low density. Because of this, historically, they were used in manufacturing twines and ropes for fishing and agricultural purposes. Further, these fibers can be used for the production of nets, carpets, rugs, doormats, bags, sacks, fish stringers, furniture webbing, drapes, upholstery padding, saddle pads, cushion stuffing, brush brittles, baskets, bracelets, headbands, sandals, decorative items, clothing and other woven objects. Papers also have been made from lower grade Agave Americana fibers. Agave Americana fibers are also used for embroidery of leather in a technique known as piteado [3,4,5,6,9,12,13].
Research findings showed that Agave Americana fiber can also be utilized for other industrial purposes. There can be a potential application of Agave Americana fibers in composites as well as in nonwovens. Bio-plastics, geotextiles, carpets, fiber boards, dart boards and molded furniture can also be manufactured using Agave Americana fibers [12,14,27,28].

5. Environmental Benefits of Agave Americana Plant and Fibers

Agave plants have four times more cellulose than the fastest growing eucalyptus tree, and it effectively captures CO2 from the atmosphere. When properly maintained, it requires irrigation only three to four times per year. Agave Americana fibers have minimal environmental impact. The production does not need agricultural chemicals. During processing of Agave Americana fibers, only organic waste is produced which can often be reused. The by-products after the processing of the agave takes the form of bio-degradable organic matter which can be used as “compost” or as an organic material to be returned to the land and as fuel for biogas production. In this way, they enhance soil fertility. Unlike synthetic fibers, Agave Americana fiber is 100% biodegradable during its lifetime and Agave Americana ropes and other products can be recycled as paper. The plants can be also used as an effective hedge to protect crops and land from predators and the extensive root system helps to reduce soil erosion in arid areas. This is truly a “no waste” plant. The “zero-waste” utilization of the plant would enable its production and processing to be translated into a viable and sustainable industry [25].

6. Conclusions

Agave Americana fibers can be used in technical applications such as reinforced composite materials, paper making, non-woven fabrics, geotextiles, etc. The “zero-waste” utilization of the plant would enable its production and processing to be translated into a viable and sustainable industry.

Author Contributions

All authors were equally contributed, read and approved the final manuscript.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Mylsamy, K. Studies on Agave Americana Fibre Reinforced Composite Materials. Ph.D. Thesis, Anna University, Chennai, India, 2011. [Google Scholar]
  2. Chattopadhyay, D.; Khan, J. Agave Americana: A New Source of Textile Fibre. Colourage 2012, 6, 33–36. [Google Scholar]
  3. Kolte, P.; Daberao, A.; Miss Sharma, A. Agave Americana: The natural leaf fibre. Text. Rev. 2012, 7, 1–5. [Google Scholar]
  4. Agave Americana: The Natural Leaf Fibre. Available online: http://vinslinchristblogger.blogspot.in/2012/07/Agave-Americana-natural-leaf-fibre_8153.html (accessed on 26 June 2014).
  5. Flowers of India. Available online: http://www.flowersofindia.net/catalog/slides/century%20Plant.htm (accessed on 26 June 2014).
  6. Agave Americana. Available online: http://en.wikipedia.org/wiki/Agave_Americana (accessed on 26 June 2014).
  7. Msahli, S.; Drean, J.Y.; Sakli, F. Evaluation of the fineness of Agave Americana L. Fibres. Text. Res. J. 2005, 75, 540–543. [Google Scholar] [CrossRef]
  8. Lewin, M. Handbook of Fibre Chemistry, 3rd ed.; CRC Press, Taylor & Francis Group: London, UK, 2007. [Google Scholar]
  9. Crop Production Guide; Tamil Nadu Agricultural University: Coimbatore, India, 2012; p. 243.
  10. Herbert, R.; Mathews, M. Textile of Fibre, Their Physical, Microscopy and Mechanical Properties, 2nd ed.; Chapman & Hall Ltd.: London, UK, 1954; pp. 360–438. [Google Scholar]
  11. Mitchel, J. The Medicinal and Poisonous Plants of Southern and East Africa; E & S Livingstone Ltd.: London, UK, 1962. [Google Scholar]
  12. Msahli, S.; Sakli, F.; Drean, J.Y. Study of textile potential of fibres extracted from tunisian Agave Americana L. AUTEX Res. J. 2006, 6, 9–13. [Google Scholar]
  13. Mbugua, G. Determination of Fibre Properties of Agave Americana Leaves as a Textile Fibre from Mbaruk, Nakuru District. Ph.D. Thesis, Kenyatta University, Nairobi, Kenya, 2009. [Google Scholar]
  14. Steyn, H.J.H. The Evaluation of Conventional Retting versus Solar Baking of Agave Americana Fibres in Terms of Textile Properties. Master’s Thesis, University of Free State, Bloemfontein, South Africa, 2006. [Google Scholar]
  15. Mauersberger, H.R. Mathew’s Textile Fibres, Their Physical, Microscopic and Chemical Properties, 6th ed.; John Wiley and Sons: New York, NY, USA, 1954; pp. 398–399. [Google Scholar]
  16. Young, R.A.; Rowell, R.M. Cellulose Structure, Modification and Hydrolysis; Wiley-Interscience Publication: New York, NY, USA, 1986; pp. 188–189. [Google Scholar]
  17. Carter, H.R. The decortication of fibrous plants with special reference to the Belgian flax industry. J. Text. Inst. 1913, 4, 236–237. [Google Scholar]
  18. Ehrensing, D.T. Feasibility of Industrial Hemp Product, Oregon State University Extension Services, Pacific Northwest. Available online: http://www.naihc.org/hempinformation.html. (accessed on 26 June 2014).
  19. Mignoni, G. Cannabis as a Licit Crop: Recent Developments in Europe; Kenaf Ecofibre: Rome, Italy, 1999. [Google Scholar]
  20. Buschle-Diller, G.; Zeronian, S.H.; Pan, N.; Yoon, M.Y. Enzymatic hydrolysis of cotton, linen, ramie and viscose rayon fabrics. Text. Res. J. 1994, 64, 270–279. [Google Scholar] [CrossRef]
  21. Kashyap, D.R.; Vohra, P.K.; Chopra, S.; Tewari, R. Application of pectinases in commercial sector: A review. Bioresour. Technol. Elsevier Sci. 2001, 77, 215–227. [Google Scholar] [CrossRef]
  22. Etters, J.N. Cotton preparation with alkaline pectinase: An environmental advance. Text. Chem. Color. Am. Dyest. Report. 1999, 1, 33–36. [Google Scholar]
  23. Rolf, M.T.; Dahlgren, R.M.T.; Clifford, H.T. The Monocotyledons—A Comparative Study; Academic Press Inc.: London, UK, 1982. [Google Scholar]
  24. Hatch, K.L. Textile Science; West Publishing Company: Eagan, MI, USA, 1993. [Google Scholar]
  25. Kadole, P.; Hulle, A. Agave Americana Fibres: Extraction, Characterization, Applications; LAP Lambert Academic Publishing: Saarbrucken, Germany, 2014. [Google Scholar]
  26. Msahli, S.; Chaabouni, Y.; Sakli, F.; Drean, Y. Mechanical behavior of Agave Americana L. Fibres: Correlation between fine structure and mechanical properties. J. Appl. Sci. 2007, 7, 3951–3957. [Google Scholar] [CrossRef]
  27. Zwane, P.E.; Masarirambi, M.T.; Magagula, N.T.; Dlamini, A.M.; Bhebhe, E. Exploitation of Agave Americana L. plant for food security in Swaziland. Am. J. Food Nutr. 2011, 1, 82–88. [Google Scholar] [CrossRef]
  28. Boguslavsky, A.; Barkhuysen, F.; Timme, E.; Matsane, R.N. Establishing of Agave Americana industry in South Africa. In Proceedings of the 5th International Conference on New Crops, Southampton, UK, 3–4 September 2007.

Share and Cite

MDPI and ACS Style

Hulle, A.; Kadole, P.; Katkar, P. Agave Americana Leaf Fibers. Fibers 2015, 3, 64-75. https://0-doi-org.brum.beds.ac.uk/10.3390/fib3010064

AMA Style

Hulle A, Kadole P, Katkar P. Agave Americana Leaf Fibers. Fibers. 2015; 3(1):64-75. https://0-doi-org.brum.beds.ac.uk/10.3390/fib3010064

Chicago/Turabian Style

Hulle, Ashish, Pradyumkumar Kadole, and Pooja Katkar. 2015. "Agave Americana Leaf Fibers" Fibers 3, no. 1: 64-75. https://0-doi-org.brum.beds.ac.uk/10.3390/fib3010064

Article Metrics

Back to TopTop