A YARN COMPRISING GEL-FORMING FILAMENTS OR FIBRES |
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申请号 | EP12798352.6 | 申请日 | 2012-11-29 | 公开(公告)号 | EP2785901B1 | 公开(公告)日 | 2018-03-21 |
申请人 | ConvaTec Technologies Inc.; | 发明人 | BONNEFIN, Wayne; WROE, Sarah; PRENTICE, Amelia; | ||||
摘要 | A wound dressing for use in vacuum wound therapy comprising a wound contact layer which is an open structure comprising a yarn comprising gel-forming filaments or fibres, the structure having a porosity which allows exudate to flow through it. | ||||||
权利要求 | |||||||
说明书全文 | This invention relates to a yarn comprising gel-forming filaments or fibres and particularly one used to make a woven or knitted wound dressing or other gelling fabric structure. It is known to make wound dressings from gel forming fibres. Typically such fibres are derived from a polysaccharide such as cellulose or alginate which is chemically modified in order to enhance the absorbency and gelling properties of the fibre. Gel-forming fibres tend to be fragile and because of this their use has been confined to simple fabric structures such as those made using non woven techniques, for instance carding fibres into a non woven felt, layering the felts and needle punching to give a fabric with some integrity. This means that the variety of dressing types that can be made with staple gel forming fibres is restricted to those that can be made from non woven fabrics and thus their use is limited. For instance, it is difficult to prepare a wound dressing comprising gel forming fibres in a format that is to be subjected to tension as its non woven character means that it is weak in tension. It is also difficult to make certain shapes, for instance tubes or socks. It would therefore be desirable to be able to make a yarn comprising gel-forming filaments or fibres, the yarn having sufficient strength that it can be processed into fabrics by weaving or knitting. Accordingly the present invention provides a yarn comprising a blend of from 60% to 100% by weight gel-forming fibres and 0% to 40% by weight textile fibres, wherein the individual fibres are carded to form a continuous web, the web drawn to produce a sliver and the sliver rotor-spun into a yarn. By the term yarn is meant a thread or strand of continuous filament or staple fibres. By gel forming filaments or fibres is meant hygroscopic filaments or fibres which upon the uptake of wound exudate become moist slippery or gelatinous and thus reduce the tendency for the surrounding fibres to adhere to the wound. The gel forming fibres can be of the type which retain their structural integrity on absorbtion of exudate or can be of the type which lose their fibrous form and become a structureless gel. The gel forming filaments or fibres are preferably spun sodium carboxymethylcellulose fibres or filaments, chemically modified cellulosic fibres or filaments, pectin fibres or filaments, alginate fibres or filaments, chitosan fibres or filaments, hyaluronic acid fibres or filaments, or other polysaccharide fibres or fibres or filaments derived from gums. The cellulosic fibres preferably have a degree of substitution of at least 0.05 carboxymethyl groups per glucose unit. The gel forming fibres or filaments preferably have an absorbency of at least 2 grams 0.9% saline solution per gram of fibre (as measured by the free swell absorbency method BS EN 13726-1:2002 Test methods for primary wound dressings - Part 1 : Aspects of absorbency, Method 3.2 free swell absorptive capacity). Preferably the gel forming fibres or filaments have an absorbency of at least 10g/g as measured in the free swell absorbency method, more preferably between 15g/g and 25g/g. The fibres present in the yarn preferably have a staple length of 30 to 60mm, more preferably 40 to 55mm and most preferably 45 to 55mm. Preferably the textile fibres or filaments have an absorbency of less than 10g/g as measured by the free swell method and more preferably less than 5 g/g. Preferably the textile or filaments fibres are Tencel®, cotton or viscose and may comprise lycra or other elastic fibre. The yarns of the present invention have a dry tensile strength of at least 10cN/tex, preferably from 10 to 40 cN/tex and most preferably from 16 to 35 cN/tex as measured by British Standard ISO 2062 2009. A yarn made according to the processes of the present invention need not contain textile fibres enabling structures to be produced which consist wholly of gel-forming fibres. The yarn of the invention can be made in various ways. The first is to spin gel-forming fibres to produce a spun gelling yarn. For example gel forming fibres which are for instance modified cellulose, or carboxymethyl cellulose or alginate can be spun into yarns comprising various blends of gel-forming staple fibres and textile fibres. The spinning may be done by first carding the fibres in the blend and spinning a yarn from the carded blend. The second is to chemically convert a cellulosic yarn to a gelling yarn either by starting with a spun cellulosic yarn or a filament cellulosic yarn. We have found that particularly suitable yarns can be formed by rotor spinning or open end spinning. In such a process, staple gel-forming fibres are blended with textile fibres and carded to produce a continuous web. The web is condensed to produce a card sliver and then rotor spun. In rotor spinning, a high speed centrifuge is used to collect and twist individual fibres into a yarn. The yarns produced from this technique have the characteristics of a sufficient tensile strength to enable them to be further processed using knitting or weaving machinery. A further embodiment of the invention provides a process for making a yarn comprising gel-forming fibres comprising the steps of:
The fibres present in the spun yarn preferably have a staple length of 30 to 60mm, more preferably 40 to 55mm and most preferably 45 to 55mm. A yarn made according to this process need not contain textile fibres enabling structures to be produced which consist of gel-forming fibres. Alternatively a gelling yarn can be produced using a spun yarn consisting of natural cellulose fibres or solvent spun cellulose staple fibres or a blend of cellulose fibres and other textile fibres or by using a filament yarn of solvent spun cellulose which is then converted to chemically modify the yarns to produce gelling properties. For example, Lyocell yarns can be used as a starting material and converted in a kier process to impart gel- forming behaviour to the yarn. A preferred method of converting the yarns or fabrics is described in The invention is illustrated in the following drawings in which:
The invention will now be illustrated by the following examples. Lyocell fibres and carboxymethyl cellulose staple fibres in blends of 50:50, 60:40 and 70:30 CMC:Lyocell were made by carding on a Trutzschler cotton card and spinning the resulting sliver at a twist of 650 turns/meter. Yarns were converted in the laboratory using a mini trier. In both trials, staple and filament lyocell yarns were converted. The yarns used for the conversion were staple 33 Tex Tencel®; HF-2011/090; and 20 Tex filament lyocell batches HF-2011/051 (trial 1) and HF-2011/125 (trial 2). Tencel® is a Lenzing owned, trademarked brand of lyocell and the Tencel® yarn used was a spun staple yarn. The filament lyocell was supplied by Acelon chemicals and Fiber Corporation (Taiwan) via Offtree Ltd. The advantages of converting a yarn are that complete cones of yarn could potentially be converted in one relatively simple process, and the processing of gelling fibres is avoided, thus reducing the number of processing steps required and damage to the fibres. In this trial, Tencel® yarn was tightly wrapped around the perforated core of the kier using an electric drill to rotate the core and pull the yarn from the packages for speed. This meant that the yarn was wrapped tightly around the core under tension. The yarn was converted by a process as described in The conversion was successful and both staple and filament gelling yarns were produced; HF-2011/103 and HF-2011/105 respectively. Due to the tight and uneven wrapping of the staple yarn around the core, it had to be removed using a scalpel which left multiple short lengths (approximately 14cm) of the converted yarn. The aim of the second trial was to produce longer lengths of converted yarns for testing hence a small hank was made of each the staple and filament lyocell yarns by hand and these were placed between layers of fabric for the conversion. The yarn was converted by placing the hanks in a kier and converting to form a gel-forming fibre yarn as described above for Trial 1. The conversion was successful and both staple and filament gelling yarns were produced; HF-2011/146 and HF-2011/147 respectively. With the exception of HF-2011/051, all of the yarns were tested for wet and dry tensile strength. Adaptations were made to the standard method BS EN ISO 2062:2009; "Textiles - Yarns from packages: Determination of single-end breaking force and elongation at break using constant rate of extension (CRE) tester". A Zwick tensile testing machine was used with a gauge length of 100mm. The test uses a 100N or 20N load cell to exert a constant rate of extension on the yarn until the breaking point is reached. Wet tensile testing was measured by wetting the samples with 0.2ml of solution A in the central 3 to 4cm of each yarn and leaving for 1 minute. The wetted sample was then placed in the jaws of the Zwick and clamped shut. Tensile strength was tested as the yarns produced need to be strong enough to withstand the tensions and forces applied during knitting, weaving and embroidery. The results are shown in Figure 1. All of the yarns were stronger when they were dry than when they were wet, with HF-2011/108, the 70:30 gelling yarn, showing the largest proportional strength decrease. Of the yarns tested, HF-2011/108 was the weakest yarn both when wet and dry with tensile strengths of 12.4 and 3.4cN/Tex respectively, despite containing 30% lyocell fibres. Although this was the weakest yarn, it was successfully weft knitted; HF-2011/120 and woven; HF-2011/169 into fabrics, it is believed that all of the other yarns would also be strong enough to be converted into fabrics. Both approaches successfully produced gelling yarns. For converted yarns, the spun and filament yarns behaved equivalently showing no advantage or disadvantage to having a twisted material in terms of fluid handling and strength of an 100% CMC yarn. Yarns have been produced using open end spinning technology utilising 50mm staple length CMC fibre. CMC has been blended with Tencel® fibres in order to help the spinning process.
The yarns were tested for their fluid handling capabilities using a modified version of TD-0187 'Liquid handling of dressings using direct immersion technique'. 3m of yarn was used for each repeat and wrapped around a cylinder of 7.5cm to give a constant number of twists. Samples were immersed in 10ml of solution A for 30 minutes before being drained for 30 seconds and their hydrated weight measured. The amount of fluid retained was assessed by applying a vacuum to the sample for 1 minute and the final sample weight measured. Tensile strength of the yarn was measured using the Zwick Universal Testing Machine (UTM). Samples were tested using a 20N load cell with a test speed of 100mm/min and gauge of 100mm. For wet strength, yarns were hydrated with 0.1ml of solution A, prior to testing using the same machine settings. Yarns were visually assessed using an optical microscope in a wet and dry state. The helix angle was also measured. An increased amount of CMC content caused an increase in the retention of the yarns, as shown in Table 1 (Figure 2) and Figure 3.1 and 3.2. There was a slight drop in absorbency when increasing the CMC content from 60% to 70% however the retention was improved. In order to produce a fabric that has a comparative absorbency to Aquacel® of 0.18g/cm2 (2), theoretically a fabric of 256gsm (g/m2) should be formed from the 80% CMC yarn. In comparison Aquacel® has a weight per unit area of 119gsm (g/m2) (2). Increased CMC content within the yarn also caused a decrease in the tensile strength shown in Figure 3.3. However a satisfactory wet strength was still able to be achieved at 80% CMC content, with individual yarns providing more than double the strength of Aquacel® dressing per cm width in the machine direction (0.61N/strand of yarn in comparison to 0.21N/cm Aquacel®(2)), and almost equalling the dressing strength per cm width in the transverse direction (0.61N/strand of yarn in comparison to 0.66N/cm Aquacel®(2)). HF-2012/088 and HF-20122/108 have both been knitted successfully, and therefore the breaking strengths of these yarns are high enough to withstand tensions within the knitting process. HF-2012/108 was also woven using a leno structure; although some problems occurred suggesting a higher breaking strength is required for weaving. Figures 3.3 and 4 (Table 2) show the tensile strength data. Visually the yarns gelled and swelled when hydrated. As the fibres swelled the helix angle of the twist increased, shown in Table 3 (Figure 5), this is due to the increased yarn thickness. Some non gelling fibres are visible at this magnification. The twist factor of a yarn determines the yarn characteristics, and is dependent on the linear density of the yarn and the twist level. Since the twist angle, and properties resulting from this will vary depending upon the twist level and the yarn thickness the twist factor normalises yarns of different linear densities so that their twist properties can be compared. Table 4 outlines the twist factors used for cotton yarns for a number of end processes. HF-2012/080 has a twist level of 580 turns/metre (given by the manufacturer). From this the twist factor can be calculated using the equation 7. Where Kt is the twist factor (using tex count) Tex is the linear density of the yarn in tex tpm is the twist level in turns per metre. This shows that the yarn is at its optimum twist for its strength. |