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Tytuł artykułu

Functional Design of Supportive Men’s Underwear with a Microbial Barrier

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Warianty tytułu
PL
Projektowanie funkcjonalnej bielizny męskiej z barierą mikrobiologiczną
Języki publikacji
EN
Abstrakty
EN
A functional modelling of supportive clothing is proposed in this paper. Body forms and measures were analysed. The digitisation of the human body was performed by 3D scanning, and based on point clouds measurements were taken. and the forms of body parts for which the pattern of clothing was developed, were defined. Pattern parts of the male supportive underwear model proposed were translated into numeric form, and a program was developed in the C++ programming language through which the pattern parts are adjusted to individual measurements and to the material used for the compression of parts of the body. Since clothing can be used post-operatively as well, an analysis of the biodegradable Tencel® materials proposed to be used for these applications was conducted. Material samples were subjected to steam sterilisation at 134 °C, after which tests of microbial barrier permeability were performed using the new method. Aerobic bacterial endospores were used. Based on the samples tested and their properties, the construction of supportive medical clothing which, by their design, enhance the functionality and possibility of preventing infections of a body part subjected to surgery was carried out.
PL
W artykule zaproponowano projektowanie funkcjonalnej bielizny męskiej. Analizowano kształt ciała i wymiary. Digitalizacja ludzkiego ciała została przeprowadzona za pomocą skanowania 3D, wykonano pomiary na podstawie „chmur” punktów i określono kształt ciała, dla których opracowano wzór bielizny. Proponowane fragmenty męskiego modelu bielizny zostały przekształcone na postać numeryczną, a program został opracowany w języku programowania C++, dzięki czemu części wzoru zostały dostosowane do indywidualnych pomiarów i materiału użytego do kompresji ciała. Ponieważ bielizna funkcjonalna może być również używana pooperacyjnie, przeprowadzono analizę materiałów biodegradowalnych Tencel® proponowanych do zastosowania w tych przypadkach. Próbki materiału poddano sterylizacji parowej w temperaturze 134 °C, po czym przeprowadzono testy przepuszczalności barier mikrobiologicznych przy użyciu nowej metody. W oparciu o przebadane próbki i ich właściwości wykonano funkcjonalną bieliznę medyczną, która poprzez swoją funkcjonalną konstrukcję poprawiła możliwość zapobiegania zakażeniom części ciała po zabiegach chirurgicznych.
Rocznik
Strony
43--49
Opis fizyczny
Bibliogr. 35 poz., rys., tab.
Twórcy
  • University of Zagreb, Faculty of Textile Technology, Department for Clothing Technology, Prilaz baruna Filipovića 28a, 10 000 Zagreb, Croatia
  • University of Zagreb, Faculty of Textile Technology, Department for Clothing Technology, Prilaz baruna Filipovića 28a, 10 000 Zagreb, Croatia
  • University of Zagreb, Faculty of Science, Bijenička 30 10 000 Zagreb, Croatia
Bibliografia
  • 1. Duffield Portus M, Edge J. Comparison of three types of full-body compression garments on throwing and repeat-sprint performance in cricket players. J Sports Med 2007; 41(7): 409–414.
  • 2. Doan Kwon YH, Newton RU, Shim J, et al. Evaluation of a lower-body compression garment. J Sports Sci 2003; 21(8): 601-10.
  • 3. Bochmann RP, Seibel W, Haase E, Hietschold V, Rodel H, Deussen A. External compression increases forearm perfusion. J Appl Physiol 2005; 99: 2337-2344.
  • 4. Davies V, Thompson KG, Cooper SM. The effects of compression garments on recovery. The Journal of Strength & Conditioning Research 2009; 23: 1786-1794.
  • 5. Kraemer WJ, Bush JA, Wickham RB, et al. Influence of compression therapy on symptoms following soft tissue injury from maximal eccentric exercise. J Orthop Sports Phys Ther 2001; 31: 282-290.
  • 6. Matthew W, Driller S, Halson L. The effects of lower-body compression garments on recovery between exercise bouts in highly-trained cyclists. J Sci Cycling 2012; 2(1): 45- 50.
  • 7. Sigel B, Edelstein AL, Savitch L, Hasty JH, Felix Jr. WR. Type of compression for reducing venous stasis: a study of lower extremities during inactive recumbency. Arch Surg 1975; 110: 171-175.
  • 8. O'Donnell TF, Rosenthal DA, Callow AD, Ledig BL. Effect of compression on venous hemodynamics in postphlebitic limbs. JAMA 1979; 242: 2766-2768.
  • 9. Gandhi DB, Palmar JR, Lewis B, Schraibman IG. Clinical comparison of elastic supports for venous diseases of the lower limb. Postgrad Med J 1984; 60: 349-352.
  • 10. Perlau R, Frank C, Fick G. The effect of elastic bandages on human knee proprioception in the uninjured population. J Sports Med 1995; 23: 251-255.
  • 11. Marinović Kulišić S. Primjena kompresivne terapije u liječenju limfedema. Acta Med Croatica 2015; 69: 11-18.
  • 12. Planinšek Ručigaj T. Kompresivna terapija. Acta Med Croatica 2011; 65: 75-9.
  • 13. Thomas S. The use of the Laplace Equation in the Calculation of Sub-bandage Pressure. EWMA J 2003; 3: 31-4.
  • 14. Rabe E. Basis of the compression therapy. Vasomed 1996; 8: 256-257.
  • 15. Partsch H, Rabe E, Stemmer R. Compression Therapy of the Extremities. Paris: Editions Phlébologiques Francaises, 2000.
  • 16. Nelson EA, Bell-Syer SE. Compression for prevention (Scottish Intercollegiate Guidelines Network (SIGN). Management of chronic venous leg ulcers. A national clinical guideline. SIGN, 2010; 5: 290-292.
  • 17. Sinožić T, Kovačević J. Rezultati primjene kompresivne terapije u obiteljskoj medicini. Acta Med Croatica 2015; 69: 35-41.
  • 18. Kerry H (2012). Compression Garments - Yes or no? Web site: Available from: http://www.getouttheremag.com/articles/3448/compression-garments-yes-or-no. [homepage on the Internet]. c2012 [updated 2012; cited 2018 Jun 11].
  • 19. Nakić M, Bogović S. Computational Design of Functional Clothing for Disabled People. Tekstilec, 2019; 62(1): 23-33.
  • 20. Kozar T, Rudolf A, Cupar A, Jevšnik S, Stjepanovič Z. Designing an adaptive 3D body model suitable for people with limited body abilities. Journal of Textile Science & Engineering 2014; 4(5): 1-13.
  • 21. Rudolf A, Brajlih T, Drstvenšek, I, Šauperl O. New medical technologies and their impact on functional ability: 3D scanning and simulation of functional garment. In: Lovrenov, Ž. (Ed.). Research, Education, and Practice in Insurance Medicine and Social Security: Book of Abstracts 21st EUMAS Congress. Domus (Ljubljana), 2016 p. 176.
  • 22. Hong Y, Bruniaux P, Zeng X, Liu K., Curteza A, et al. Visual-simulation-based personalized garment block design method for physically disabled people with scoliosis (PDPS). Autex Research Journal 2018; 18(1): 35-45.
  • 23. Bogović S, Stjepanovič Z, Cupar A, Jevšnik S, Rogina-Car B, Rudolf A. The Use Of New Technologies For The Development Of Protective Clothing: Comparative Analysis Of Body Dimensions Of Static And Dynamic Postures And Its Application. Autex Research Journal. First Online (2018), December 31; 1-11.
  • 24. ISO 3801:1977. Textil - Woven fabrics - Determination of mass per unit length and mass per unit area.
  • 25. EN ISO 5084:1996. Textiles - Determination of thickness of textiles and textile products (ISO 5084:1996).
  • 26. Rogina-Car B, Bogović S, Katović D. TENCEL® with a Microbial Barrier for Medical Bras. JFBI 2015; 8(4): 635-643.
  • 27. Schuster KC, Suchomel F, Männer J, Abu-Rous M, Firgo H. Functional and Comfort Properties of Textiles from TENCEL® Fibres Resulting from the Fibres' WaterAbsorbing Nanostructure. A Review. Macromol. Symp 2006; 244: 149-165.
  • 28. Diepgen LT, Schuster KC. Dermatological examinations on the skin compatibility of textiles made from Tencel® fibres. Lenzinger Berichte 2006; 85: 61-67.
  • 29. Rogina-Car B, Budimir A, Turčić V, Katović D. Do multi-use cellulosic textiles provide safe protection against contamination of sterilized items? Cellulose 2014; 21(3): 2101- 2109.
  • 30. Rogina-Car B. Microbial barrier properties of medical textiles. Doctoral thesis, Faculty of Textile Technology, University of Zagreb, Zagreb, Croatia, 2014.
  • 31. Deutsche Bekleidungs-Akademie. Hemden Schnitttechnik, Rundschau-Verlag Otto G. Königer, München, 2014, ISBN 978-3-929305-75-3.
  • 32. Ujević D, Rogale D, Hrastinski M. Tehnike konstruiranja i modeliranja odjeće, Sveučilište u Zagrebu Tekstilno-tehnološki fakultet, Zagreb, 2000, ISBN: 953-96408-1-4.
  • 33. Rogale D, Polanović S. Računalni sustavi konstrukcijske pripreme u odjevnoj industriji, Sveučilište u Zagrebu Tekstilno-tehnološki fakultet, Zagreb, 1996, ISBN 953-96183-9-8.
  • 34. Rašajski B. Analitička Geometrija, Građevinska knjiga, 1973, Beograd.
  • 35. EN ISO 13934-1:1999. Textiles -- Tensile properties of fabrics -- Part 1: Determination of maximum force and elongation at maximum force using the strip method (ISO 13934- 1:1999).
Uwagi
PL
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-9f1a574f-e28d-4a69-ae36-7b0c572db0ad
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