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Edit Comment Close Premium member Presentation Transcript S1 L5 Surgical dressings : S1 L5 Surgical dressings Anna Drew NOTES: Linked with carbohydrates (Semester 3 of pharmacognosy) Traditionally plant fibres were used With recent advances in wound-healing many materials of non-vegetable origin are now used Surgical dressings & sutures : Surgical dressings & sutures Composed of fibres A solid characterized by Flexibility Fineness High ratio of length: thickness length at least 1000 times their breadth Important to: Forensic science Pharmacy For quality control To determine price v quality for bulk purchasing Identification Macroscopical examination Chemical tests Performed on a microscope slide Observed under the microscope Classification of fibres used in surgical dressings : Classification of fibres used in surgical dressings Animal fibres : Animal fibres WOOL From the fleece of the sheep Ovis aries Treated before use to degrease it Washed with water, then soap solution, then bleached with sulphuric acid, (acetone removes wool fat), combed, graded Made of protein (keratin) [flame tested by burning] Stretched (unstable) form β keratin Elastic when let go Unstretched (stable) form α keratin Forms peptide links in chain strands Also contains cysteine in sulphur bridges which give elasticity [test for sulphur] Slide 6: Uses Chiropody ie to spread toes Crepe bandages with cotton/rayon Wool gives elasticity and warmth Microscopically Covered by epithelial scales Marked; shape and arrangement varies in different breeds Number of scales per 100 µm length is fairly constant (average 9.7-12.1) in different wools Counts can distinguish x 130 Slide 8: SILK Prepared fibre from the cocoons of silk worms Bombyx mori Also from other Bombyx, Antheraea species China, Japan, India, Asia Minor, Italy, France etc ‘Wild silks’ A. mylitta (India) A. assama (India) A. pernyi (China) A. yama-mai (Japan) Caterpillar -> chrysalis / pupal stage Secretes an oval cocoon 2-5cm long around itself Made of continuous thread up to 1200m long! Chrysalis killed by 60-80ºC few hours or a short steam burst Graded, hot water, beaten to remove outer layer and soften glue Loose ends of 2-15 cocoons spun into a single thread Generally 5 cocoons ie 5 bave, 10 brins (>6 brins too fine) Slide 9: Made of 2 silk or fibroin fibres cemented together with silk glue / sericin Sericin removed by hot soap solution fully extended chains of alanine and glycine Non-elastic, don’t double up like wool Contain no sulphur [negative sulphur test] Uses Dressings a bit eg Oil Silk BPC in surgery to stop other dressings drying out, cover them Sutures, ligatures Non-absorbable Quite strong Do not disintegrate when wet Microscopically A solid rod-like fibre Lack of cellular structure No distinguishing features Slide 11: Animal fibres - different microscopically, differentiated by following chemical tests: Vegetable fibres : Vegetable fibres COTTON Cheap and used a lot USA produces about half; rest Eqypt, India, South America Source epidermal trichomes covering seeds of Gossypium herbaceum Ginning – removes long hairs (better quality) Linter – removes remaining short hairs Gives poorer quality cotton (-> cotton wool) Made into chemical pulp or viscose rayon Then seeds are pressed to get cotton seed oil Then seeds used as animal crop Slide 13: Production Raw cotton has a waxy (fatty) cuticle covering the trichome Making it fairly non-absorbent Removed by soaking (or pressure heating) loosened cotton in alkali (NaOH, KOH) To get absorbent cotton (trichome wall is absorbent) Then washed, bleached and mechanically loosened ‘scutched’ Grades Raw cotton very impure, only used to absorb spillages Hospital quality absorbent cotton wool poorer quality to BPC BPC has some impurities almost impossible to remove all as too expensive BPC has limits certain amount of shell & leaf material allowable Want a minimum for surgical procedures (rarely used in the body cavity or wrapped in gauze first to prevent loose fibres going into the body) Slide 14: Made of Primary and secondary cellulose cell walls Secondary wall constitutes the main bulk of cotton Raw cotton consists of 90% cellulose Cellulose molecule made of glucose residues Repeating unit is ‘cellibiose’ = 2 glucose residues linked by a 1-4β glucosidic bond Uses Bandages – gauze linen in very absorbent Microscopically (of unbleached cotton) Unicellular hairs look like flattened twisted hose pipes [Staining with CuOxam -> ballooning] Slide 15: x 130 Slide 16: Cotton fibres in longitudinal view (x 250) and transverse section (x 500) Slide 17: CHEMICAL WOOD PULP (WOOD) Derived from pine and spruce wood ‘off cuts’ Production ‘ Delignified wood’ produced by “Sulphite process” to leave the cellulose Wood chopped into chips – allows penetration Calcium bisulphite and H2SO4 added to hydrolyse any material other than cellulose Then washed, bleached, rolled, pressed into board and dried Composed of cellibiose Uses Cellulose wadding BPC Easily disintegrated no intinsic structure so falls apart when wet not used for dressings but to catch and absorb spillage of wounds, heavy discharge and incontinence Microscopically Looks like tracheids with border pits [distinguishes it from cotton] Slide 18: Cellulose wadding (x 130) Slide 19: JUTE Phloem fibres from stem bark Corchorus capsularis, C. olitorius, other species Bengal delta region, Assam, Bihar, Orissa Fibres separated -> hesian and sacking Remaining short fibres ‘tow’ – jute in pharmacy Lignocellulose; nitric acid, potassium chlorate used to disintegrate bundles FLAX Pericyclic fibres of Linum usitatissimum stem Commercial fibres show fine tranverse injuries from preparation Good quality fibre only lignified in middle lamella HEMP pericyclic fibres of Cannabis sativa stem Mostly cellulose, minimal lignification Fibre ends bluntly rounded, some forked from injury Lumen flattened or oval Slide 20: Above: Flax (x 130) Right: Jute (x 300) A. Strand of fibres B. Apices of isolated fibres C,D. Tranverse sections Slide 21: Vegetable fibres: chemical tests, differentiated micropscopically Regenerated fibres : Regenerated fibres Produced from naturally occurring, long chain molecules isolated, controlled and possibly modified semi-synthetic VISCOSE RAYON viscose rayon, viscose, rayon, regenerated cellulose Made from Linters, inferior grade of cotton short hairs, or wood pulp Cellulose is dissolved by adding alkali and then carbon disulphide to reprecipitate it Precipitate is forced through a metal sheet with holes Into a coagulating fluid to produce fibres of required length/diameter TiO2 is added to the pecipitate solution to delustre rayon (slimey sheen) Hence specks coating the surface can be seen under microscope Can get the desired quality free from impurities Slide 23: Viscose rayon filaments in longitudinal view and transverse section (x 250) Delustred viscose rayon filaments in longitudinal view (x 250) and transverse section (x 300) Slide 24: Use in a mixture with cotton as non-surgical absorbent material Macroscopically Its tensile strength varies from 2/3 to 1.5 that of cotton When wet it loses about 60% of its tensile strength (more than cotton) If more than a certain amount it used material may need to be made water-repellant Eg cotton crepe bandage Microscopically Fibres are solid and transparent Slight twist with grooves along their length From being immersed in the regenerating solution Ends of fibres are abrupt [Seen in chloral hydrate solution and lactophenol] [Invisible in in cresol (same refractive index)] Comparison with cotton: Impurities in cotton Waxy material never completely removed from cotton When stored in a warm temperature pockets of wax move out and coat fibres therefore absorbency lost on storage Slide 25: CELLULOSE ACETATE Largely superseded by synthetic fibres Production: Cotton linters and delignified wood pulp -> purified cellulose Partially acetylated by mixing with glacial acetic acid, acetic anhydride and a catalyst Precipitates as acid-resin flakes These are dissolved in acetone Then the solution is filtered and spun down a column of warm air Produces filaments made of 200-300 ‘glucose’ residue units Properties: Less absorbent that viscose rayon Unsuitable for surgical dressings Loses less strength when wet Use: component of plastic splinting bandage Like Nylon produces static electricity Macro/microscopically Similar to viscose rayon Slide 26: ALGINATE Laminaria hyperborea, other sp, Ascophyllum Alginic acid comes from cell walls of brown algae Production: Alginate fibres are produced by a similar process to viscose rayon Sodium alginate solution is pumped through a spinneret immersed in a bath of CaCl solution (acidified with HCl) Water insoluble calcium alginate is precipitated as continuous filaments Collected, washed, dried, reduced to staple form which is processed to calcium alginate wool or a fabric Eg gauze Composed of polymers of mannuronic and guluronic acids Uses absorbable haemostatic surgical dressings internal – neurosurgery; external – burns, skin graft sites bacterial swabs Microscopy Similar to viscose rayon (solid grooved rods) Slide 27: Alginate fibres in longitudinal view and transverse section (x 250) Synthetic fibres : Synthetic fibres Polyamides NYLON Condensation polymer Made of adipic acid and hexamethylene diamine Polypeptide chain Like silk structurally Can be autoclaved Very strong material Use: sutures Polyesters TERYLENE Condensation polymer resin Made of ethylene glycol and terephthalic acid Can be autoclaved [Distinguished by chemical tests] Use: sutures, (preparation of artificial grafts) POLYPROPYLENE Addition polymer Can be autoclaved Non-absorbable Use: catheters, sutures Slide 29: Delustred nylon fibres in longitudinal and transverse section (x 750) Delustred terylene fibres in longitudinal and transverse section (x 500) Slide 30: Man-made fibres: solid with limited diagnostic structure, chemical tests more useful You do not have the permission to view this presentation. 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S1 L5 Surgical dressings vinitsharma Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINT lite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 797 Category: Education License: All Rights Reserved Like it (1) Dislike it (0) Added: November 13, 2009 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... By: SHADA2007 (7 month(s) ago) we need to teach our nursing staff not to touch the dressing with bare hands. thanks for help Saving..... Post Reply Close Saving..... Edit Comment Close Premium member Presentation Transcript S1 L5 Surgical dressings : S1 L5 Surgical dressings Anna Drew NOTES: Linked with carbohydrates (Semester 3 of pharmacognosy) Traditionally plant fibres were used With recent advances in wound-healing many materials of non-vegetable origin are now used Surgical dressings & sutures : Surgical dressings & sutures Composed of fibres A solid characterized by Flexibility Fineness High ratio of length: thickness length at least 1000 times their breadth Important to: Forensic science Pharmacy For quality control To determine price v quality for bulk purchasing Identification Macroscopical examination Chemical tests Performed on a microscope slide Observed under the microscope Classification of fibres used in surgical dressings : Classification of fibres used in surgical dressings Animal fibres : Animal fibres WOOL From the fleece of the sheep Ovis aries Treated before use to degrease it Washed with water, then soap solution, then bleached with sulphuric acid, (acetone removes wool fat), combed, graded Made of protein (keratin) [flame tested by burning] Stretched (unstable) form β keratin Elastic when let go Unstretched (stable) form α keratin Forms peptide links in chain strands Also contains cysteine in sulphur bridges which give elasticity [test for sulphur] Slide 6: Uses Chiropody ie to spread toes Crepe bandages with cotton/rayon Wool gives elasticity and warmth Microscopically Covered by epithelial scales Marked; shape and arrangement varies in different breeds Number of scales per 100 µm length is fairly constant (average 9.7-12.1) in different wools Counts can distinguish x 130 Slide 8: SILK Prepared fibre from the cocoons of silk worms Bombyx mori Also from other Bombyx, Antheraea species China, Japan, India, Asia Minor, Italy, France etc ‘Wild silks’ A. mylitta (India) A. assama (India) A. pernyi (China) A. yama-mai (Japan) Caterpillar -> chrysalis / pupal stage Secretes an oval cocoon 2-5cm long around itself Made of continuous thread up to 1200m long! Chrysalis killed by 60-80ºC few hours or a short steam burst Graded, hot water, beaten to remove outer layer and soften glue Loose ends of 2-15 cocoons spun into a single thread Generally 5 cocoons ie 5 bave, 10 brins (>6 brins too fine) Slide 9: Made of 2 silk or fibroin fibres cemented together with silk glue / sericin Sericin removed by hot soap solution fully extended chains of alanine and glycine Non-elastic, don’t double up like wool Contain no sulphur [negative sulphur test] Uses Dressings a bit eg Oil Silk BPC in surgery to stop other dressings drying out, cover them Sutures, ligatures Non-absorbable Quite strong Do not disintegrate when wet Microscopically A solid rod-like fibre Lack of cellular structure No distinguishing features Slide 11: Animal fibres - different microscopically, differentiated by following chemical tests: Vegetable fibres : Vegetable fibres COTTON Cheap and used a lot USA produces about half; rest Eqypt, India, South America Source epidermal trichomes covering seeds of Gossypium herbaceum Ginning – removes long hairs (better quality) Linter – removes remaining short hairs Gives poorer quality cotton (-> cotton wool) Made into chemical pulp or viscose rayon Then seeds are pressed to get cotton seed oil Then seeds used as animal crop Slide 13: Production Raw cotton has a waxy (fatty) cuticle covering the trichome Making it fairly non-absorbent Removed by soaking (or pressure heating) loosened cotton in alkali (NaOH, KOH) To get absorbent cotton (trichome wall is absorbent) Then washed, bleached and mechanically loosened ‘scutched’ Grades Raw cotton very impure, only used to absorb spillages Hospital quality absorbent cotton wool poorer quality to BPC BPC has some impurities almost impossible to remove all as too expensive BPC has limits certain amount of shell & leaf material allowable Want a minimum for surgical procedures (rarely used in the body cavity or wrapped in gauze first to prevent loose fibres going into the body) Slide 14: Made of Primary and secondary cellulose cell walls Secondary wall constitutes the main bulk of cotton Raw cotton consists of 90% cellulose Cellulose molecule made of glucose residues Repeating unit is ‘cellibiose’ = 2 glucose residues linked by a 1-4β glucosidic bond Uses Bandages – gauze linen in very absorbent Microscopically (of unbleached cotton) Unicellular hairs look like flattened twisted hose pipes [Staining with CuOxam -> ballooning] Slide 15: x 130 Slide 16: Cotton fibres in longitudinal view (x 250) and transverse section (x 500) Slide 17: CHEMICAL WOOD PULP (WOOD) Derived from pine and spruce wood ‘off cuts’ Production ‘ Delignified wood’ produced by “Sulphite process” to leave the cellulose Wood chopped into chips – allows penetration Calcium bisulphite and H2SO4 added to hydrolyse any material other than cellulose Then washed, bleached, rolled, pressed into board and dried Composed of cellibiose Uses Cellulose wadding BPC Easily disintegrated no intinsic structure so falls apart when wet not used for dressings but to catch and absorb spillage of wounds, heavy discharge and incontinence Microscopically Looks like tracheids with border pits [distinguishes it from cotton] Slide 18: Cellulose wadding (x 130) Slide 19: JUTE Phloem fibres from stem bark Corchorus capsularis, C. olitorius, other species Bengal delta region, Assam, Bihar, Orissa Fibres separated -> hesian and sacking Remaining short fibres ‘tow’ – jute in pharmacy Lignocellulose; nitric acid, potassium chlorate used to disintegrate bundles FLAX Pericyclic fibres of Linum usitatissimum stem Commercial fibres show fine tranverse injuries from preparation Good quality fibre only lignified in middle lamella HEMP pericyclic fibres of Cannabis sativa stem Mostly cellulose, minimal lignification Fibre ends bluntly rounded, some forked from injury Lumen flattened or oval Slide 20: Above: Flax (x 130) Right: Jute (x 300) A. Strand of fibres B. Apices of isolated fibres C,D. Tranverse sections Slide 21: Vegetable fibres: chemical tests, differentiated micropscopically Regenerated fibres : Regenerated fibres Produced from naturally occurring, long chain molecules isolated, controlled and possibly modified semi-synthetic VISCOSE RAYON viscose rayon, viscose, rayon, regenerated cellulose Made from Linters, inferior grade of cotton short hairs, or wood pulp Cellulose is dissolved by adding alkali and then carbon disulphide to reprecipitate it Precipitate is forced through a metal sheet with holes Into a coagulating fluid to produce fibres of required length/diameter TiO2 is added to the pecipitate solution to delustre rayon (slimey sheen) Hence specks coating the surface can be seen under microscope Can get the desired quality free from impurities Slide 23: Viscose rayon filaments in longitudinal view and transverse section (x 250) Delustred viscose rayon filaments in longitudinal view (x 250) and transverse section (x 300) Slide 24: Use in a mixture with cotton as non-surgical absorbent material Macroscopically Its tensile strength varies from 2/3 to 1.5 that of cotton When wet it loses about 60% of its tensile strength (more than cotton) If more than a certain amount it used material may need to be made water-repellant Eg cotton crepe bandage Microscopically Fibres are solid and transparent Slight twist with grooves along their length From being immersed in the regenerating solution Ends of fibres are abrupt [Seen in chloral hydrate solution and lactophenol] [Invisible in in cresol (same refractive index)] Comparison with cotton: Impurities in cotton Waxy material never completely removed from cotton When stored in a warm temperature pockets of wax move out and coat fibres therefore absorbency lost on storage Slide 25: CELLULOSE ACETATE Largely superseded by synthetic fibres Production: Cotton linters and delignified wood pulp -> purified cellulose Partially acetylated by mixing with glacial acetic acid, acetic anhydride and a catalyst Precipitates as acid-resin flakes These are dissolved in acetone Then the solution is filtered and spun down a column of warm air Produces filaments made of 200-300 ‘glucose’ residue units Properties: Less absorbent that viscose rayon Unsuitable for surgical dressings Loses less strength when wet Use: component of plastic splinting bandage Like Nylon produces static electricity Macro/microscopically Similar to viscose rayon Slide 26: ALGINATE Laminaria hyperborea, other sp, Ascophyllum Alginic acid comes from cell walls of brown algae Production: Alginate fibres are produced by a similar process to viscose rayon Sodium alginate solution is pumped through a spinneret immersed in a bath of CaCl solution (acidified with HCl) Water insoluble calcium alginate is precipitated as continuous filaments Collected, washed, dried, reduced to staple form which is processed to calcium alginate wool or a fabric Eg gauze Composed of polymers of mannuronic and guluronic acids Uses absorbable haemostatic surgical dressings internal – neurosurgery; external – burns, skin graft sites bacterial swabs Microscopy Similar to viscose rayon (solid grooved rods) Slide 27: Alginate fibres in longitudinal view and transverse section (x 250) Synthetic fibres : Synthetic fibres Polyamides NYLON Condensation polymer Made of adipic acid and hexamethylene diamine Polypeptide chain Like silk structurally Can be autoclaved Very strong material Use: sutures Polyesters TERYLENE Condensation polymer resin Made of ethylene glycol and terephthalic acid Can be autoclaved [Distinguished by chemical tests] Use: sutures, (preparation of artificial grafts) POLYPROPYLENE Addition polymer Can be autoclaved Non-absorbable Use: catheters, sutures Slide 29: Delustred nylon fibres in longitudinal and transverse section (x 750) Delustred terylene fibres in longitudinal and transverse section (x 500) Slide 30: Man-made fibres: solid with limited diagnostic structure, chemical tests more useful