Your search keyword '"Seki, Yuta"' showing total 5 results

1. Sweat lactate sensor for detecting anaerobic threshold in heart failure: a prospective clinical trial (LacS-001)

Author

Katsumata, Yoshinori, Muramoto, Yuki, Ishida, Noriyuki, Takemura, Ryo, Nagashima, Kengo, Ikoma, Takenori, Kawamatsu, Naoto, Araki, Masaru, Goda, Ayumi, Okawara, Hiroki, Sawada, Tomonori, Ichihara, Yumiko Kawakubo, Hattori, Osamu, Yamaoka, Koki, Seki, Yuta, Ryuzaki, Toshinobu, Ikura, Hidehiko, Nakashima, Daisuke, Nagura, Takeo, Nakamura, Masaya, Sato, Kazuki, and Shiraishi, Yasuyuki

Published

2024

2. Anaerobic threshold using sweat lactate sensor under hypoxia.

Author

Okawara, Hiroki, Iwasawa, Yuji, Sawada, Tomonori, Sugai, Kazuhisa, Daigo, Kyohei, Seki, Yuta, Ichihara, Genki, Nakashima, Daisuke, Sano, Motoaki, Nakamura, Masaya, Sato, Kazuki, Fukuda, Keiichi, and Katsumata, Yoshinori

Subjects

ANAEROBIC threshold, HYPOXEMIA, EXERCISE tests, LACTATES, INTRACLASS correlation, LACTATION

Abstract

We aimed to investigate the reliability and validity of sweat lactate threshold (sLT) measurement based on the real-time monitoring of the transition in sweat lactate levels (sLA) under hypoxic exercise. In this cross-sectional study, 20 healthy participants who underwent exercise tests using respiratory gas analysis under hypoxia (fraction of inspired oxygen [FiO2], 15.4 ± 0.8%) in addition to normoxia (FiO2, 20.9%) were included; we simultaneously monitored sLA transition using a wearable lactate sensor. The initial significant elevation in sLA over the baseline was defined as sLT. Under hypoxia, real-time dynamic changes in sLA were successfully visualized, including a rapid, continual rise until volitionary exhaustion and a progressive reduction in the recovery phase. High intra- and inter-evaluator reliability was demonstrated for sLT's repeat determinations (0.782 [0.607–0.898] and 0.933 [0.841–0.973]) as intraclass correlation coefficients [95% confidence interval]. sLT correlated with ventilatory threshold (VT) (r = 0.70, p < 0.01). A strong agreement was found in the Bland–Altman plot (mean difference/mean average time: − 15.5/550.8 s) under hypoxia. Our wearable device enabled continuous and real-time lactate assessment in sweat under hypoxic conditions in healthy participants with high reliability and validity, providing additional information to detect anaerobic thresholds in hypoxic conditions. [ABSTRACT FROM AUTHOR]

Published

2023

3. Real-Time Estimation of Anaerobic Threshold during Exercise Using Electrocardiogram in Heart Failure Patients.

Author

Ryuzaki, Toshinobu, Shiraishi, Yasuyuki, Miura, Kotaro, Ikura, Hidehiko, Seki, Yuta, Azuma, Koichiro, Sato, Kazuki, Fukuda, Keiichi, and Katsumata, Yoshinori

Subjects

HEART failure patients, ANAEROBIC threshold, HEART beat, EXERCISE tests, EXERCISE therapy

Abstract

Exercise therapy at the aerobic level is highly recommended to improve clinical outcomes in patients with heart failure, in which cardiopulmonary exercise testing (CPX) is required to determine anaerobic thresholds (ATs) but is not available everywhere. This study aimed to validate a method to estimate the AT using heart rate variability (HRV) analysis from electrocardiography data in patients with heart failure. Between 2014 and 2019, 67 patients with symptomatic heart failure underwent CPXs in a single university hospital. During the CPX, RR intervals was measured continuously and the HRV threshold (HRVT), defined as the inflection point of <5 ms2 of a high-frequency component (HFC) using the power spectrum analysis, was determined. Patients were divided into two groups according to the mean HFC at rest (high-HFC group, n = 34 and low-HFC group, n = 33). The high-HFC group showed good correlation between the VO2 at AT and HRVT (r = 0.63, p < 0.001) and strong agreement (mean difference, −0.38 mL/kg, p = 0.571). The low-HFC group also showed modest correlation (r = 0.41, p = 0.017) but poor agreement (mean differences, 3.75 mL/kg, p < 0.001). In conclusion, the HRVT obtained from electrocardiography may be a useful indicator for estimating AT in patients with heart failure. [ABSTRACT FROM AUTHOR]

Published

2023

4. A novel device for detecting anaerobic threshold using sweat lactate during exercise.

Author

Seki, Yuta, Nakashima, Daisuke, Shiraishi, Yasuyuki, Ryuzaki, Toshinobu, Ikura, Hidehiko, Miura, Kotaro, Suzuki, Masato, Watanabe, Takatomo, Nagura, Takeo, Matsumato, Morio, Nakamura, Masaya, Sato, Kazuki, Fukuda, Keiichi, and Katsumata, Yoshinori

Subjects

*ANAEROBIC threshold, *CLINICAL trials, *WEARABLE technology, *MEAN value theorems, *EXERCISE

Abstract

The lactate threshold (LT1), which is defined as the first rise in lactate concentration during incremental exercise, has not been non-invasively and conveniently determined in a clinical setting. We aimed to visualize changes in lactate concentration in sweat during exercise using our wearable lactate sensor and investigate the relationship between the lactate threshold (LT1) and ventilatory threshold (VT1). Twenty-three healthy subjects and 42 patients with cardiovascular diseases (CVDs) were enrolled. During exercise, the dynamic changes in lactate values in sweat were visualized in real-time with a sharp continuous increase up to volitional exhaustion and a gradual decrease during the recovery period. The LT1 in sweat was well correlated with the LT1 in blood and the VT1 (r = 0.92 and 0.71, respectively). In addition, the Bland–Altman plot described no bias between the mean values (mean differences: − 4.5 and 2.5 W, respectively). Continuous monitoring of lactate concentrations during exercise can provide additional information for detecting the VT1. [ABSTRACT FROM AUTHOR]

Published

2021

5. Lactate threshold evaluation in swimming using a sweat lactate sensor: A prospective study.

Author

Okawara, Hiroki, Sawada, Tomonori, Nakashima, Daisuke, Fujitsuka, Haruki, Muramoto, Yuki, Hinokuma, Daigo, Oshikiri, Yuta, Ishizaki, Keisuke, Miki, Jiro, Hara, Reira, Sano, Motoaki, Sato, Kazuki, Nakamura, Masaya, Nagura, Takeo, and Katsumata, Yoshinori

Subjects

STATISTICAL correlation, ANAEROBIC threshold, RESEARCH funding, PERSPIRATION, WEARABLE technology, DESCRIPTIVE statistics, LONGITUDINAL method, HEART beat, LACTATES, SWIMMING, EXERCISE tests

Abstract

Since assessing aerobic capacity is key to enhancing swimming performance, a simple and widely applicable technology should be developed. Therefore, we aimed to noninvasively visualize real‐time changes in sweat lactate (sLA) levels during swimming and investigate the relationship between lactate thresholds in sweat (sLT) and blood (bLT). This prospective study included 24 university swimmers (age: 20.7 s ± 1.8 years, 58% male) who underwent exercise tests at incremental speeds with or without breaks in a swimming flume to measure heart rate (HR), bLT, and sLT based on sLA levels using a waterproof wearable lactate sensor attached to the dorsal upper arm on two different days. The correlation coefficient and Bland–Altman methods were used to verify the similarities of the sLT with bLT and personal performance. In all tests, dynamic changes in sLA levels were continuously measured and projected onto the wearable device without delay, artifacts, or contamination. Following an initial minimal current response, with increasing speed the sLA levels increased substantially, coinciding with a continuous rise in HR. The speed at sLT strongly correlated with that at bLT (p < 0.01 and r = 0.824). The Bland–Altman plot showed a strong agreement (mean difference: 0.08 ± 0.1 m/s). This prospective study achieved real‐time sLA monitoring during swimming, even with vigorous movement. The sLT closely approximated bLT; both were subsequently validated for their relevance to performance. Highlights: A new technique using a wearable device can measure sweat lactate (sLA) levels during swimming without artifacts or contamination.Lactate threshold assessed using sLA dynamics is consistent with that calculated from blood samples.The current novel measurement method is expected to promote a personalized training regimen and simultaneous multi‐person measurements. [ABSTRACT FROM AUTHOR]

Published

2024