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Natural fibers or natural fibres (see spelling differences) are fibers that are produced by plants, animals, and geological processes. They can be used as a component of composite materials, where the orientation of fibers impacts the properties. Natural fibers can also be matted into sheets to make products such as paper or felt.
The earliest evidence of humans using fibers is the discovery of wool and dyed flax fibers found in a prehistoric cave in the Republic of Georgia that date back to 36,000 BP. Now, natural fibers can be used for high-tech applications, such as composite parts for automobiles. Compared to composites reinforced with glass fibers, composites with natural fibers have advantages such as lower density, better thermal insulation, and reduced skin irritation. Further, unlike glass fibers, natural fibers can be broken down by bacteria once they are no longer in use.
|Seed fiber||Fibers collected from seeds or seed cases, e.g. cotton and kapok|
|Leaf fiber||Fibers collected from leaves, e.g. abaca, date palm, pineapple, banana and agave|
|Bast fiber||Bast fibers are collected from the outer cell layers of the plant's stem. These fibers are used for durable yarn, fabric, packaging, and paper. Some examples are flax, jute, kenaf, industrial hemp, ramie, rattan, and vine fibers.|
|Fruit fiber||Fibers collected from the fruit of the plant, e.g. coconut fiber (coir)|
|Stalk fiber||Fibers from the stalks of plants, e.g. straws of wheat, rice, barley, bamboo and straw|
- Animal hair (wool or hairs): Fiber or wool taken from animals or hairy mammals. e.g. sheep's wool, goat hair (cashmere, mohair), alpaca hair, horse hair, etc.
- Silk fiber: Fiber secreted by glands (often located near the mouth) of insects during the preparation of cocoons.
- Avian fiber: Fibers from birds, e.g. feathers and feather fiber.
Chitin is the second most abundant natural polymer in the world, with collagen being the first. It is a “linear polysaccharide of β-(1-4)-2-acetamido-2-deoxy-D-glucose”. Chitin is highly crystalline and is usually composed of chains organized in a β sheet. Due to its high crystallinity and chemical structure, it is insoluble in many solvents. It also has a low toxicity in the body and is inert in the intestines. Chitin also has antibacterial properties.
Chitin forms crystals that make fibrils that become surrounded by proteins. These fibrils can bundle to make larger fibers that contribute to the hierarchical structure of many biological materials. These fibrils can form randomly oriented networks that provide the mechanical strength of the organic layer in different biological materials.
Chitin provides protection and structural support to many living organisms. It makes up the cell walls of fungi and yeast, the shells of mollusks, the exoskeletons of insects and arthropods. In shells and exoskeletons, the chitin fibers contribute to their hierarchical structure.
In nature, pure chitin (100% acetylation) does not exist. It instead exists as a copolymer with chitin's deacetylated derivative, chitosan. When the acetylized composition of the copolymer is over 50% acetylated it is chitin. This copolymer of chitin and chitosan is a random or block copolymer.
Chitosan is a deacetylated derivative of chitin. When the acetylized composition of the copolymer is below 50% it is chitosan. Chitosan is a semicrystalline “polymer of β-(1-4)-2-amino-2-deoxy-D-glucose”. One difference between chitin and chitosan is that chitosan is soluble in acidic aqueous solutions. Chitosan is easier to process that chitin, but it is less stable because it is more hydrophilic and has pH sensitivity. Due to its ease of processing, chitosan is used in biomedical applications.
Collagen is a structural protein, often referred to as “the steel of biological materials”. There are multiple types of collagen: Type I (comprising skin, tendons and ligaments, vasculature and organs, as well as teeth and bone); Type II (a component in cartilage); Type III (often found in reticular fibers); and others. Collagen has a hierarchical structure, forming triple helices, fibrils, and fibers.
Keratin is a structural protein located at the hard surfaces in many vertebrates. Keratin has two forms, α-keratin and β-keratin and are used by different classes of animals. The naming convention for proteins follows that for keratin, alpha keratin is helical and beta keratin is sheet like. Alpha keratin is found in mammalian hair, skin, nails, horn and quills, while beta keratin can be found in avian and reptilian species in scales, feathers, and beaks. The two different structures of keratin have dissimilar mechanical properties, as seen in their dissimilar applications. The relative alignment of the keratin fibrils has a significant impact on the mechanical properties. In human hair the filaments of alpha keratin are highly aligned, giving a tensile strength of approximately 200MPa. This tensile strength is an order of magnitude higher than human nails (20MPa), because human hair’s keratin filaments are more aligned. 
Compared to synthetic fibers, natural fibers tend have decreased stiffness and strength.
|Material||Fiber||Elastic Modulus (GPa)||Strength (MPa)|
|Mud Crab Exoskeleton (wet)||Chitin||0.48||30|
|Prawn Exoskeleton (wet)||Chitin||0.55||28|
Properties also decrease with the age of the fiber. Younger fibers tend to be stronger and more elastic than older ones. Many natural fibers exhibit strain rate sensitivity due to their viscoelastic nature. Bone contains collagen and exhibits strain rate sensitivity in that the stiffness increases with strain rate, also known as strain hardening. Spider silk has hard and elastic regions that together contribute to its strain rate sensitivity, these cause the silk to exhibit strain hardening as well. Properties of natural fibers are also dependent on the moisture content in the fiber.
The presence of water plays a crucial role in the mechanical behavior of natural fibers. Hydrated, biopolymers generally have enhanced ductility and toughness. Water plays the role of a plasticizer, a small molecule easing passage of polymer chains and in doing so increasing ductility and toughness. When using natural fibers in applications outside of their native use, the original level of hydration must be taken into account. For example when hydrated, the Young’s Modulus of collagen decreases from 3.26 to 0.6 GPa and becomes both more ductile and tougher. Additionally the density of collagen decreases from 1.34 to 1.18 g/cm^3. 
After World War II, the use and development of synthetic fibers nearly eclipsed that of natural fibers. Now, interest in natural fibers is renewed with growing concerns about the environmental impact associated with the processing of petroleum-based products. This interest is common in the textile, building, plastic, and automotive industries. It is reinforced by the developmental perspectives on the agro-industrial market and local productions, allowing economic development and independence versus imported materials.
France remains the greatest European hemp fiber producer with 50,000 tons yearly (EU 100,000 tons). France also produces the largest range of industrial seeds worldwide. China and Russia are also important producers, but the statistics in that field are not available.
In the industrial domain, the consortium DAIFA group SAS have reached a leading position in Europe in the automotive plastics market. They specialize in injection and thermopress plastics reinforced with natural fibers.
The use of natural fibers at the industrial level improves the environmental sustainability of the parts being constructed, especially within the automotive market. Within the building industry, the interest in natural fibers is mostly economical and technical; natural fibers allow insulation properties higher than current materials.
Natural fiber composites
Natural fibers are also used in composite materials, much like synthetic or glass fibers. These composites are called biocomposites and are a natural fiber in a matrix of synthetic polymers. One of the first biofiber-reinforced plastics in use was a cellulose fiber in phenolics in 1908. Current usage includes applications where energy absorption is important, such as insulation, noise absorbing panels, or collapsable areas in automobiles.
Natural fibers can have different advantages over synthetic reinforcing fibers. Most notably they are biodegradable and renewable. Additionally, they often have low densities and lower processing costs than synthetic materials. Design issues with natural fiber-reinforced composites include poor strength (natural fibers are not as strong as glass fibers) and difficulty with actually bonding the fibers and the matrix. Hydrophobic polymer matrices offer insufficient adhesion for hydrophilic fibers.
Nanocomposites are desirable for their unique mechanical properties. When fillers in a composite are at the nanometer length scale, the surface to volume ratio of the filler material is exceptionally higher and influences the bulk properties of the composite more compared to traditional composites. The properties of these nanosized elements is markedly different than that of its bulk constituent.
In regards to natural fibers, come of the best example of nanocomposites appear in biology. Bone, abalone shell, nacre, and tooth enamel are all examples of biological nanocomposites. As of 2010, most synthetic polymer nanocomposites exhibit inferior toughness and mechanical properties compared to biological nanocomposites.  Completely synthetic nanocomposites do exist, however nanosized biopolymers are also being tested in synthetic matrices. Several types of protein based, nanosized fibers are being used in nanocomposites currently. These include collagen, cellulose, chitin and tunican.  These structural proteins must be processed before use in composites.
To use cellulose as an example, semicrystalline microfibrils are sheared in the amorphous region, resulting in microcrystalline cellulose (MCC). These small, crystalline cellulose fibrils are at this points reclassified as a whisker and can be 2 to 20nm in diameter with shapes ranging from spherical to cylindrical. Whiskers of collagen, chitin and cellulose have all be used to make biological nanocomposites. The matrix of these composites are commonly hydrophobic synthetic polymers such as polyethylene, and polyvinyl chloride and copolymers of polystyrene and polyacrylate. 
Traditionally in composite science a strong interface between the matrix and filler is required to achieve favorable mechanical properties. If this is not the case, the phases tend to separate along the weak interface and makes for very poor mechanical properties. In a MCC composite however this is not the case, if the interaction between the filler and matrix is stronger than the filler-filler interaction the mechanical strength of the composite is noticeably decreased. 
Currently, difficulties in natural fiber nanocomposites arise from dispersity and the tendency small fibers have to aggregate in the matrix. Because of the high surface area to volume ratio the fibers have a tendency to aggregate, more so than in micro-scale composites. Additionally secondary processing of collagen sources to obtain sufficient purity collagen micro fibrils adds a degree of cost and challenge to creating a load bearing cellulose or other filler based nanocomposite.
Natural fibers often show promise as biomaterials in medical applications. Chitin is notable in particular and has been incorporated into a variety of uses. Chitin based materials have also been used to remove industrial pollutants from water, processed into fibers and films, and used as biosensors in the food industry.  Chitin has also been used several of medical applications. It has been incorporated as a bone filling material for tissue regeneration, a drug carrier and excipient, and as an antitumor agent.  Insertion of foreign materials into the body often triggers an immune response, which can have a variety of positive or negative outcomes depending on the bodies response to the material. Implanting something made from naturally synthesized proteins, such as a keratin based implant, has the potential to be recognized as natural tissue by the body. This can lead either to integration in rare cases where the structure of the implant promotes regrowth of tissue with the implant forming a superstructure or degradation of the implant in which the backbones of the proteins are recognized for cleavage by the body.  
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