School of Molecular Sciences, Faculty of Science, University of Western Australia, Perth, Australia.
School of Chemistry and Molecular Sciences, University of Queensland, Brisbane, Queensland, Australia.
J Mammary Gland Biol Neoplasia. 2019 Jun;24(2):177-184. doi: 10.1007/s10911-019-09426-2. Epub 2019 Feb 13.
Milk ejection is essential for effective milk removal during breastfeeding and pumping, and for continued milk synthesis. Many women are unable to accurately sense milk ejection to determine whether their infant is receiving milk or, when pumping, to switch the pump to a more effective expression pattern. To determine if changes in bioimpedance parameters are associated with milk ejection in the lactating breast during pumping. 30 lactating women participated in 2 pumping sessions within 2 weeks of each other. During pumping the breasts were monitored with bioimpedance spectroscopy (on either the pumped or the non- pumped breast), and milk flow rate and volume were measured simultaneously. All mothers completed 24-h milk productions. Linear mixed effects models were used to determine associations between milk flow rate and bioimpedance changes. Changes in bioimpedance parameters were greater at the first milk ejection when measured on the pumped breast (median (IQR): R zero: -7 (-17, -4,) % (n = 30); R infinity: -8 (-20, -2) % (n = 29); membrane capacitance: -24 (-59, -7) % (n = 27). Changes in bioimpedance detected in the non-pumped breast were lower at the first milk ejection, R zero: -3 (-8, -2) % (n = 25); R infinity: -5 (-8, -2) % (n = 23); membrane capacitance: -9 (-17, 15) % (n = 24). Smaller less consistent decreases in the bioimpedance characteristics were detected at the second milk ejection in both breasts. Bioimpedance parameters showed a consistent decrease associated with the first milk ejection when electrodes were placed on the pumped breast. Smaller decreases were observed when the non-pumped breast was monitored for the first and second milk ejection. There was wide variation in the magnitude of changes observed, and hence further development of the methodology is needed to ensure reliability.
乳汁排出对于母乳喂养和泵吸时有效排乳以及持续泌乳至关重要。许多女性无法准确感知乳汁排出,以确定婴儿是否在接受乳汁,或者在泵吸时切换到更有效的表达模式。为了确定在泵吸期间,泌乳乳房的生物阻抗参数变化是否与乳汁排出有关。30 名哺乳期妇女在彼此相隔 2 周的 2 次泵吸期间参与了研究。在泵吸过程中,使用生物阻抗光谱法(在被泵吸或未被泵吸的乳房上)监测乳房,并同时测量奶流率和奶量。所有母亲均完成了 24 小时的奶产量。使用线性混合效应模型确定奶流率与生物阻抗变化之间的关联。当在被泵吸的乳房上测量时,第一次乳汁排出时生物阻抗参数的变化更大(中位数(IQR):R zero:-7(-17,-4)%(n=30);R infinity:-8(-20,-2)%(n=29);膜电容:-24(-59,-7)%(n=27))。在非被泵吸的乳房上检测到的生物阻抗变化在第一次乳汁排出时较低,R zero:-3(-8,-2)%(n=25);R infinity:-5(-8,-2)%(n=23);膜电容:-9(-17,15)%(n=24)。在两个乳房的第二次乳汁排出时,生物阻抗特征的变化较小且一致性较差。当在被泵吸的乳房上放置电极时,生物阻抗参数与第一次乳汁排出呈一致的下降趋势。当监测第一次和第二次乳汁排出时,非被泵吸的乳房观察到的下降幅度较小。观察到的变化幅度差异很大,因此需要进一步开发该方法以确保可靠性。
