WardLC, BunceI, CornishBH, MiroloB, ThomasBJ, JonesLC. Multifrequency bioelectrical impedance augments the diagnosis and management of lymphedema in post-mastectomy patients. Eur J Clin Invest, 1992; 22:751–754.
2.
YorkSL, WardLC, CzerniecS, LeeMJ, RefshaugeKM, KilbreathSL. Single frequency versus bioimpedance spectroscopy for the assessment of lymphedema. Breast Cancer Res Treat, 2009; 117:177–182.
3.
CzerniecSA, WardLC, RefshaugeKM, BeithJ, LeeMJ, YorkS, KilbreathSL. Assessment of breast cancer-related arm lymphedema—comparison of physical measurement methods and self-report. Cancer Invest, 2010; 28:54–62.
4.
WardLC, DylkeE, CzerniecS, IsenringE, KilbreathSL. Confirmation of the reference impedance ratios used for assessment of breast cancer-related lymphedema by bioelectrical impedance spectroscopy. Lymphat Res Biol, 2011; 9:47–51.
5.
JohanssonK, BranjeE. Lymphoedema in a cohort of breast cancer survivors 10 years after diagnosis. Acta Oncol, 2010; 49; 166–173.
6.
LahtinenT, Seppälä J, Viren T, and Johansson K. Experimental and analytical comparisons of tissue dielectric constant (TDC) and bioimpedance spectroscopy (BIS) in assessment of early arm lymphedema in breast cancer patients after axillary surgery and radiotherapy. Lymphat Res Biol, 13: 176–185.
7.
MayrovitzHN, WeingradD, DaveyS. Local tissue water in at-risk and contralateral forearms of women with and without breast cancer treatment-related lymphedema. Lymphat Res Biol, 2009; 7:153–158.
8.
MayrovitzHN, WeingradD, LopezL. Patterns of temporal changes in tissue dielectric constant (TDC) as indices of localized skin water changes in women treated for breast cancer: A pilot study. Lymphat Res Biol, 2015; 13:20–33.
