Journal of Textile Research ›› 2022, Vol. 43 ›› Issue (05): 109-115.doi: 10.13475/j.fzxb.20210502907

• Textile Engineering • Previous Articles     Next Articles

Effect of far infrared polyamide fabrics on proliferation of breast cancer cells

MU Yifei1, JIN Zimin1(), YAN Yuxiu2, WU Dehao3, ZHOU Wenlong1,4, TAO Jianwei5   

  1. 1. College of Textile Science and Engineering(International Institute of Silk), Zhejiang Sci-Tech University,Hangzhou, Zhejiang 310018, China
    2. School of Fashion Design & Engineering, Zhejiang Sci-Tech University,Hangzhou, Zhejiang 310018, China
    3. Cancer Institute of Zhejiang University, Hangzhou, Zhejiang 310009,China
    4. Wenzhou University of Technology, Wenzhou, Zhejiang 325035, China
    5. Zhejiang Bangjie Digital Knitwear Co., Ltd., Yiwu, Zhejiang 322000, China
  • Received:2021-05-13 Revised:2021-12-29 Online:2022-05-15 Published:2022-05-30
  • Contact: JIN Zimin E-mail:kivenjin@163.com

Abstract:

In order to explore the adjuvant effect of far-infrared fabrics on breast cancer patients, 6 types of far infrared polyamide fabrics were compared with the ordinary polyamide fabrics in irradiating 3 breast cancer cells, i.e., MCF7, Bcap37 and MDA-MB-231, and the effects of fabrics and radiation duration on the proliferation of 3 types of breast cancer cells were examined. The results show that the emissivities of different far infrared polyamide fabrics are different, and the far infrared emissivity of tea carbon polyamide is the strongest among the 6 far infrared fabrics. The 6 types of far infrared fabrics inhibit the proliferation of MCF7 and Bcap37 breast cancer cells to different degrees, but not significantly in the case of MDA-MB-231 cell. With the increase of far infrared radiation time, the higher the far infrared emissivity of the fabric, the more significant the effect of inhibiting the proliferation of breast cancer cells. This study shows that far infrared fabrics are able to inhibit but not promote the proliferation of breast cancer cells from the perspective of cell biology, and provide a theoretical basis for exploring the wearing of far-infrared fabrics as adjuvant therapy for breast cancer patients.

Key words: polyamide, far infrared fiber, far infrared fabric, breast cancer cell, cell proliferation

CLC Number: 

  • TS101.4

Tab.1

Specification of fabrics"

织物
编号
厚度/
mm
面密度/
(g·m-2)
横密/(线圈数·
(10 cm)-1)
纵密/(线圈数·
(10 cm)-1)
BCF 0.81 0.029 6 168 214
CCF 0.82 0.029 6 168 234
GF 0.82 0.029 6 168 212
BGF 0.82 0.029 5 168 236
TCF 0.82 0.029 8 168 224
VF 0.81 0.029 7 168 217
NC 0.74 0.021 8 168 226

Fig.1

Fabric radiation incubator"

Fig.2

Surface morphology of ordinary polyamide and 6 kinds of far infrared polyamide (×400)"

Tab.2

Far infrared emissivity of ordinary polyamide and 6 kinds of far infrared polyamide fabrics"

织物编号 织物远红外光发射率
BCF 0.967 0
CCF 0.967 3
GF 0.965 0
BGF 0.964 3
TCF 0.972 0
VF 0.969 3
NC 0.832 0

Fig.3

3 kinds of breast cancer cells appearance in ordinary polyamide and TCF surface(×40).(a)MCF7 cells(NC fabric);(b)MCF7 cells(TCF fabric);(c)Bcap37 cells(NC fabric);(d)Bcap37 cells(TCF fabric);(e)MDA-MB-231 cells (NC fabric);(f)MDA-MB-231 cells(TCF fabric)"

Fig.4

Proliferation curve of breast cancer cells on different polyamide fabric"

Fig.5

Effect of far infrared radiation duration on proliferation of breast cancer cells"

Fig.6

Relationship between far infrared emissivity and proliferation of breast cancer cells"

[1] SHUI S, WANG X, CHIANG J Y, et al. Far-infrared therapy for cardiovascular, autoimmune, and other chronic health problems: a systematic review[J]. Experimental Biology & Medicine, 2015, 240(10): 1257-1265.
[2] ZHAO Q, DONG C, LIU Z F, et al. The effectiveness of aquatic physical therapy intervention on disease activity and function of ankylosing spondylitis patients: a meta-analysis[J]. Psychology, Health & Medicine, 2020, 25(7):832-843.
[3] GUSTAV J D, PETRA V, ILKA S, et al. Integrative oncology for breast cancer patients: introduction of an expert-based model[J]. Bmc Cancer, 2012, 12(1):539.
doi: 10.1186/1471-2407-12-539
[4] CHENG B, HE H C, HUANG T, et al. Gold nanosphere gated mesoporous silica nanoparticle responsive to near-infrared light and redox potential as a theranostic platform for cancer therapy[J]. Journal of Biomedical Nanotechnology, 2016, 12(3):435-449.
doi: 10.1166/jbn.2016.2195
[5] ANA D, NINA K, MARIA J A, et al. Probing intermolecular interactions in water/ionic liquid mixtures by far-infrared spectroscopy[J]. The Journal of Physical Chemistry B, 2007, 111(17): 4446-4452.
doi: 10.1021/jp068777n
[6] LI K, XIA L, LIU N F, et al. Far infrared ray (FIR) therapy: an effective and oncological safe treatment modality for breast cancer related lymphedemal[J]. Journal of Photochemistry & Photobiology B: Biology, 2017, 172: 95-101.
[7] LI J, LYV Z, LI Y, et al. A theranostic prodrug delivery system based on Pt(Ⅳ) conjugated nano-graphene oxide with synergistic effect to enhance the therapeutic efficacy of Pt drugl[J]. Biomaterials, 2015, 51: 12-21.
doi: 10.1016/j.biomaterials.2015.01.074
[8] 吴继辉, 邹婉晴, 汤明竹, 等. 负离子远红外功能织物对乳腺增生大鼠模型的影响[J]. 纺织学报, 2019, 40(6):69-73.
WU Jihui, ZOU Wanqing, TANG Mingzhu, et al. Effect of anion far infrared functional fabric on rat model of mammary gland hyperplasia[J]. Journal of Textile Research, 2019, 40 (6): 69-73.
[9] NAGASAWA H, INADA K, ISHIGAME H, et al. Different schedules of whole-body hyperthermia with or without glucose for the inhibition of mammary tumors and uterine adenomyosis in SHN mice[J]. Bulletin of the Faculty of Agriculture Meiji University, 2001, 127: 43-51.
[10] JIA Y P, SONG Y, QU Y, et al. Mesoporous PtPd nanoparticles for ligand-mediated and imaging-guidedchemo-photothermal therapy of breast cancer[J]. Nano Research, 2020, 13: 1739-1748.
doi: 10.1007/s12274-020-2800-2
[11] WEI L L, CHUNG F J K. Development of a warmingmulti-functional fabric: part I: the analytichierarchy process combined with thetechnique for order preference bysimilarity to an ideal solution for theoptimization of the multi-quality meltspinning parameters in far-infrared functional yarn[J]. Textile Research Journal, 2018, 89(11): 2247-2259.
doi: 10.1177/0040517518790972
[12] 龚佳佳, 顾学平, 肖俊, 等. 纺织品远红外功能整理[J]. 针织工业, 2018(11): 78-80.
GONG Jiajia, GU Xueping, XIAO Jun, et al. Far-infrared functional finishing of textiles[J]. Knitting Industries, 2018(11): 78-80.
[13] AUDRONE S, VITALIJA R, DIANA K, et al. Investigation of thermal behavior of 3D PET knitswith different bioceramic additives[J]. Polymers, 2020, 12(6):1319.
doi: 10.3390/polym12061319
[14] 吴迪. 几种功能纺织品远红外发射率试验方法的比对研究[C]// 全国第十五届红外加热暨红外医学发展研讨会论文及论文摘要集. 锦州: 锦州市光学学会, 2015: 250-258.
WU Di. Comparative study on test methods for far infrared emissivity of several functional textiles[C]// Proceedings and Abstracts of the 15th National Symposium on Infrared Heating and Infrared Medicine Development. Jinzhou: The Optical Society of Jinzhou, 2015: 250-258.
[15] REN J, LI P, ZHAO H, et al. Assessment of tissue perfusion changes in port wine stains after vascular targeted photodynamic therapy: a short-term follow-up study[J]. Lasers in Medical Science, 2014, 29(2): 781-788.
doi: 10.1007/s10103-013-1420-4
[16] 许强. 远红外混纺纤维含量分析初探[J]. 中国纤检, 2014(21):80-83.
XU Qiang. Analysis of far infrared blended fiber content[J]. China Fiber Inspection, 2014(21): 80-83.
[17] ZHAO F, HAO Z, ZHONG Y, et al. Discovery of breast cancer risk genes and establishment of a prediction model based on estrogen metabolism regulation[J]. BMC Cancer, 2021, 21(1): 194.
doi: 10.1186/s12885-021-07896-4
[18] JUN I, KIKUJI Y, TATSUO I, et al. The effects inhibiting the proliferation of cancer cells by far-infrared radiation (FIR) are controlled by the basal expression level of heat shock protein (HSP) 70A[J]. Med Oncol, 2008, 25: 229-237.
doi: 10.1007/s12032-007-9020-4
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