References
- Alisauskiene, D., & Mikucioniene, D. (2012). Investigation on alteration of compression of knitted orthopaedic supports during exploitation. Material Science, 18(4), 362–366.
- Alisauskiene, D., Mikucioniene, D., & Milasiute, L. (2013). Influence of inlay-yarn properties and insertion density on the compression properties of knitted orthopaedic supports. Fibres & Textiles in Eastern Europe, 21(6), 74–78.
- Cheng, Z., Kuzmichev, V. E., & Adolphe, D. C. (2017). Development of knitted materials selection for compression underwear. Autex Research Journal, 17(2), 177–187. doi:10.1515/aut-2016-0006
- Cieslak, M., Karaszewska, A., Gromadzińska, E., Jasińska, I., & Kamińska, I. (2017). Comparison of methods for measurement of the pressure exerted by knitted fabrics. Textile Research Journal, 87(17), 2117–2126. doi:10.1177/0040517516665255
- Komárková, P., Glombíková, V., & Havelka, A. (2017). Heat and moisture transport of socks. Materials Science and Engineering, 254, 1–6. doi:10.1088/1757-899X/254/18/182004
- Kowalski, K., Mielicka, E., & Kowalski, T. M. (2012). Modelling and designing compression garments with unit pressure assumed for body circumferences of a variable curvature radius. Fibres & Textiles in Eastern Europe, 20(6A), 98–102.
- Laureckiene, G., & Milasius, R. (2017). Behaviour of long-lasting stress relaxation of various types of yarns. Autex Research Journal, 17(4), 379–385. doi:10.1515/aut-2017-0017
- Liu, R., Lao, T. T., Little, T. J., Wu, X., & Ke, X. (2018). Can heterogeneous compression textile design reshape skin pressures? A fundamental study. Textile Research Journal, 88(17), 1915–1930. doi:10.1177/0040517518779254
- Macintyre, L., Stewart, H., & Rae, M. (2016). How can the pressure in anti-embolism stockings be maintained during use? Laboratory evaluation of simulated ‘wear’ and different reconditioning protocols. International Journal of Nursing Studies, 64, 19–24. doi:10.1016/j.ijnurstu.2016.09.004
- Mikucioniene, D., & Alisauskiene, D. (2014). Prediction of compression of knitted orthopaedic supports by inlay-yarn properties. Material Science, 20(3), 311–314.
- Mikucioniene, D., & Milasiute, L. (2017). Influence of knitted orthopaedic suport construction on compression generated by the support. Journal of Industrial Textiles, 47(4), 551–566.
- Milosavljevic, S., & Skundric, P. (2007). Contribution of textile technology to the development of modern compression bandages. Chemical Industry and Chemical Engineering Quarterly, 13(2), 88–102. doi:10.2298/CICEQ0702088M
- Muraliene, L., Mikucioniene, D., Laureckiene, G., & Brazaitis, M. (2018). New approach to evaluation of orthopaedic supports compression properties. Journal of Industrial Textile. doi:10.1177/1528083718783312
- Tvarijonaviciene, B., Mikucioniene, D., & Ciukas, R. (2005). Influence of knitting process conditions and washing on tensile characteristics of knitted ribbon yarns. Fibres & Textiles in Eastern Europe, 13(4), 74–77.
- Valencia, R. A., Garcia, M. J., & Bustamante, J. (2018). A comparative computational study of blood flow pattern in exemplary textile vascular grafts. The Journal of the Textile Institute, 109(7), 858–870. doi:10.1080/00405000.2017.1380872
- Wang, L., Felder, M., & Cai, J. Y. (2011). Study of properties of medical compression garment fabrics. Journal of Fiber Bioengineering and Informatics, 4(1), 15–22. doi:10.3993/jfbi04201102
- Wiegand, C., Hansen, T., Köhnlein, J., Exner, I., Damisch-Pohl, M., Schott, P., … Pohlen, E. (2018). Optimized protocol for the biocompatibility testing of compression stockings and similar products with close skin contact in vitro. The Journal of the Textile Institute, 109(7), 891–902. doi:10.1080/00405000.2017.1383640