Ritsumeikan University Researcher Database
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HIMENO YUKIKO
Department / Course
College of Life Sciences Department of Bioinformatics
Title / Position
Assistant Professor
Papers
1.
2022/11/09
Gradient-based parameter optimization method to determine membrane ionic current composition in human induced pluripotent stem cell-derived cardiomyocytes │ Scientific Reports │ 12 (1),pp.19110 (Co-authored)
2.
2021/06/01
Effects of Heat Stress on Heart Rate Variability in Free-Moving Sheep and Goats Assessed With Correction for Physical Activity. │ Front Vet Sci │ ,pp.658763 (Co-authored)
3.
2020/05/27
Exploring the role of fatigue-related metabolite activity during high-intensity exercise using a simplified whole-body mathematical model │ Informatics in Medicine Unlocked │ 19,pp.100355 (Co-authored)
4.
2020
THE “WAY OF FLOWERS” AND THE CARE OF PERSONS WITH AMYOTROPHIC LATERAL
SCLEROSIS IN JAPAN │ Arxiu d'Etnografia de Catalunya │ 20 (Co-authored)
5.
2019/06
Mechanisms Underlying Spontaneous Action Potential Generation Induced by Catecholamine in Pulmonary Vein Cardiomyocytes: A Simulation Study │ International Journal of Molecular Sciences │ 20 (12),pp.2913 (Co-authored)
6.
2018/08
Correcting the Activity-specific Component of Heart Rate Variability Using Dynamic Body Acceleration Under Free-moving Conditions │ Frontiers in Physiology │ 9,pp.1063 (Co-authored)
7.
2018/07
Regulation of the glucose supply from capillary to tissue examined by developing a capillary model │ J Physiol Sci │ 68 (4),pp.355-367. (Co-authored)
8.
2016/12
A simulation study on the constancy of cardiac energy metabolites during workload transition. │ J Physiol │ 594 (23),pp.6929-6945 (Co-authored)
9.
2016/06
Influence of Activation Time on Hemodynamic Parameters: a Simulation Study │ Advanced Biomedical Engineering │ 5,pp.94-104 (Co-authored)
10.
2016/03
A Method for Determining Scale Parameters in a Hemodynamic model incorporating Cardiac Cellular Contraction model │ Advanced Biomedical Engineering │ 5,pp.32-42 (Co-authored)
11.
2016/03
Mechanisms underlying the volume regulation of the interstitial fluid by capillaries: a simulation study │ Integrative Medicine Research │ 5 (1),pp.11-21 (Co-authored)
12.
2015/06
A human ventricular myocyte model with a refined representation of excitation-contraction coupling │ Biophys J │ ,pp.415-27 (Co-authored)
13.
2011/07
Ionic mechanisms and Ca2+ dynamics underlying the glucose response of pancreatic β-cells: A simulation study │ THE ROCKEFELLER UNIVERSITY PRESS, 『J Gen Physiol』 │ 138 (1),pp.21-37 (Co-authored)
14.
2011/06
Reply to “Letter to the editor: ‘Validating the requirement for beat-to-beat coupling of the Ca2+ clock and M clock in pacemaker cell normal automaticity'” │ American Physiological Society, 『Am J Physiol Heart Circ Physiol』 │ 300 (6),pp.H2325-H2326 (Co-authored)
15.
2011/01
Minor contribution of cytosolic Ca2+ transients to the pacemaker rhythm in guinea pig sinoatrial node cells │ American Physiological Society, 『Am J Physiol Heart Circ Physiol』 │ 300 (1),pp.H251-61 (Co-authored)
16.
2009/12
A Novel Method to Quantify Contribution of Channels and Transporters to Membrane Potential Dynamics │ Biophysical Society, 『Biophys J』 │ 97 (12),pp.3086-94 (Co-authored)
17.
2008/02
Ionic Mechanisms Underlying the Positive Chronotropy Induced by b1-Adrenergic Stimulation in Guinea Pig Sinoatrial Node Cells: a Simulation Study │ Springer, 『J Physiol Sci』 │ 58 (1),pp.53-65 (Co-authored)
18.
2003
Series analysis of traditional milk processing systems through milk processing elements (2) Classification and the central goal-oriented intentions of milk processing elements │ Milk Science │ 52 (1),pp.41-47 (Co-authored)
19.
2002
Series Analysis of Traditional Milk Processing Systems Through Milk Processing Elements (1) Extraction of Milk Processing Elements │ Milk Science │ 51 (3),pp.121-132 (Co-authored)
