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Yoshio Okamoto - One of the best experts on this subject based on the ideXlab platform.
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the Absolute Voltage and the lead vector of wilson s central terminal
Japanese Heart Journal, 1996Co-Authors: Norio Miyamoto, Genyo Nishiyama, Yutaka Shimizu, Saburo Mashima, Yoshio OkamotoAbstract:The Absolute potential value of Wilson's central terminal was calculated at 2 msec intervals during a cardiac cycle in 60 clinical cases. Starting from the body surface potential data at 128 thoracic locations, the effect of immersion of the body into an infinite conductor on the surface potential was calculated to obtain values with reference to zero potential at infinity. The conductivity of the outside medium was then made to approach zero.Comparison of the result with the original map showed nearly a constant shift of the potential, corresponding to the Voltage of Wilson's terminal. In addition, the cardiac vector was calculated as the first approximation of the cardiac electromotive force and the lead vector of Wilson's terminal was obtained in order that the scalar product of the cardiac vector and the lead vector approximated the observed Voltage of Wilson's terminal.The results indicate that the Voltage of the Wilson electrode depended on the surface Voltage with a peak value near the maximal QRS force in most of the cases. The peak Voltage of Wilson's terminal was either positive or negative, and was 0.15mV in Absolute value on average. Voltage variations of Wilson's terminal during a cardiac cycle were 0.20mV as an average of all cases. The Voltage of Wilson's terminal also depended on the direction of the equivalent cardiac vector. The lead vector of Wilson's terminal was found to be directed superiorly in most of the cases. The average magnitude of the lead vector of Wilson's terminal was 0.097Ω/cm, which corresponded to about 1/4 of that of lead I.
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the Absolute Voltage and the lead vector of wilson s central terminal
Japanese Heart Journal, 1996Co-Authors: Norio Miyamoto, Genyo Nishiyama, Yutaka Shimizu, Saburo Mashima, Yoshio OkamotoAbstract:The Absolute potential value of Wilson's central terminal was calculated at 2 msec intervals during a cardiac cycle in 60 clinical cases. Starting from the body surface potential data at 128 thoracic locations, the effect of immersion of the body into an infinite conductor on the surface potential was calculated to obtain values with reference to zero potential at infinity. The conductivity of the outside medium was then made to approach zero. Comparison of the result with the original map showed nearly a constant shift of the potential, corresponding to the Voltage of Wilson's terminal. In addition, the cardiac vector was calculated as the first approximation of the cardiac electromotive force and the lead vector of Wilson's terminal was obtained in order that the scalar product of the cardiac vector and the lead vector approximated the observed Voltage of Wilson's terminal. The results indicate that the Voltage of the Wilson electrode depended on the surface Voltage with a peak value near the maximal QRS force in most of the cases. The peak Voltage of Wilson's terminal was either positive or negative, and was 0.15 mV in Absolute value on average. Voltage variations of Wilson's terminal during a cardiac cycle were 0.20 mV as an average of all cases. The Voltage of Wilson's terminal also depended on the direction of the equivalent cardiac vector. The lead vector of Wilson's terminal was found to be directed superiorly in most of the cases. The average magnitude of the lead vector of Wilson's terminal was 0.097 omega/cm, which corresponded to about 1/4 of that of lead I.
Norio Miyamoto - One of the best experts on this subject based on the ideXlab platform.
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the Absolute Voltage and the lead vector of wilson s central terminal
Japanese Heart Journal, 1996Co-Authors: Norio Miyamoto, Genyo Nishiyama, Yutaka Shimizu, Saburo Mashima, Yoshio OkamotoAbstract:The Absolute potential value of Wilson's central terminal was calculated at 2 msec intervals during a cardiac cycle in 60 clinical cases. Starting from the body surface potential data at 128 thoracic locations, the effect of immersion of the body into an infinite conductor on the surface potential was calculated to obtain values with reference to zero potential at infinity. The conductivity of the outside medium was then made to approach zero.Comparison of the result with the original map showed nearly a constant shift of the potential, corresponding to the Voltage of Wilson's terminal. In addition, the cardiac vector was calculated as the first approximation of the cardiac electromotive force and the lead vector of Wilson's terminal was obtained in order that the scalar product of the cardiac vector and the lead vector approximated the observed Voltage of Wilson's terminal.The results indicate that the Voltage of the Wilson electrode depended on the surface Voltage with a peak value near the maximal QRS force in most of the cases. The peak Voltage of Wilson's terminal was either positive or negative, and was 0.15mV in Absolute value on average. Voltage variations of Wilson's terminal during a cardiac cycle were 0.20mV as an average of all cases. The Voltage of Wilson's terminal also depended on the direction of the equivalent cardiac vector. The lead vector of Wilson's terminal was found to be directed superiorly in most of the cases. The average magnitude of the lead vector of Wilson's terminal was 0.097Ω/cm, which corresponded to about 1/4 of that of lead I.
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the Absolute Voltage and the lead vector of wilson s central terminal
Japanese Heart Journal, 1996Co-Authors: Norio Miyamoto, Genyo Nishiyama, Yutaka Shimizu, Saburo Mashima, Yoshio OkamotoAbstract:The Absolute potential value of Wilson's central terminal was calculated at 2 msec intervals during a cardiac cycle in 60 clinical cases. Starting from the body surface potential data at 128 thoracic locations, the effect of immersion of the body into an infinite conductor on the surface potential was calculated to obtain values with reference to zero potential at infinity. The conductivity of the outside medium was then made to approach zero. Comparison of the result with the original map showed nearly a constant shift of the potential, corresponding to the Voltage of Wilson's terminal. In addition, the cardiac vector was calculated as the first approximation of the cardiac electromotive force and the lead vector of Wilson's terminal was obtained in order that the scalar product of the cardiac vector and the lead vector approximated the observed Voltage of Wilson's terminal. The results indicate that the Voltage of the Wilson electrode depended on the surface Voltage with a peak value near the maximal QRS force in most of the cases. The peak Voltage of Wilson's terminal was either positive or negative, and was 0.15 mV in Absolute value on average. Voltage variations of Wilson's terminal during a cardiac cycle were 0.20 mV as an average of all cases. The Voltage of Wilson's terminal also depended on the direction of the equivalent cardiac vector. The lead vector of Wilson's terminal was found to be directed superiorly in most of the cases. The average magnitude of the lead vector of Wilson's terminal was 0.097 omega/cm, which corresponded to about 1/4 of that of lead I.
Genyo Nishiyama - One of the best experts on this subject based on the ideXlab platform.
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the Absolute Voltage and the lead vector of wilson s central terminal
Japanese Heart Journal, 1996Co-Authors: Norio Miyamoto, Genyo Nishiyama, Yutaka Shimizu, Saburo Mashima, Yoshio OkamotoAbstract:The Absolute potential value of Wilson's central terminal was calculated at 2 msec intervals during a cardiac cycle in 60 clinical cases. Starting from the body surface potential data at 128 thoracic locations, the effect of immersion of the body into an infinite conductor on the surface potential was calculated to obtain values with reference to zero potential at infinity. The conductivity of the outside medium was then made to approach zero.Comparison of the result with the original map showed nearly a constant shift of the potential, corresponding to the Voltage of Wilson's terminal. In addition, the cardiac vector was calculated as the first approximation of the cardiac electromotive force and the lead vector of Wilson's terminal was obtained in order that the scalar product of the cardiac vector and the lead vector approximated the observed Voltage of Wilson's terminal.The results indicate that the Voltage of the Wilson electrode depended on the surface Voltage with a peak value near the maximal QRS force in most of the cases. The peak Voltage of Wilson's terminal was either positive or negative, and was 0.15mV in Absolute value on average. Voltage variations of Wilson's terminal during a cardiac cycle were 0.20mV as an average of all cases. The Voltage of Wilson's terminal also depended on the direction of the equivalent cardiac vector. The lead vector of Wilson's terminal was found to be directed superiorly in most of the cases. The average magnitude of the lead vector of Wilson's terminal was 0.097Ω/cm, which corresponded to about 1/4 of that of lead I.
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the Absolute Voltage and the lead vector of wilson s central terminal
Japanese Heart Journal, 1996Co-Authors: Norio Miyamoto, Genyo Nishiyama, Yutaka Shimizu, Saburo Mashima, Yoshio OkamotoAbstract:The Absolute potential value of Wilson's central terminal was calculated at 2 msec intervals during a cardiac cycle in 60 clinical cases. Starting from the body surface potential data at 128 thoracic locations, the effect of immersion of the body into an infinite conductor on the surface potential was calculated to obtain values with reference to zero potential at infinity. The conductivity of the outside medium was then made to approach zero. Comparison of the result with the original map showed nearly a constant shift of the potential, corresponding to the Voltage of Wilson's terminal. In addition, the cardiac vector was calculated as the first approximation of the cardiac electromotive force and the lead vector of Wilson's terminal was obtained in order that the scalar product of the cardiac vector and the lead vector approximated the observed Voltage of Wilson's terminal. The results indicate that the Voltage of the Wilson electrode depended on the surface Voltage with a peak value near the maximal QRS force in most of the cases. The peak Voltage of Wilson's terminal was either positive or negative, and was 0.15 mV in Absolute value on average. Voltage variations of Wilson's terminal during a cardiac cycle were 0.20 mV as an average of all cases. The Voltage of Wilson's terminal also depended on the direction of the equivalent cardiac vector. The lead vector of Wilson's terminal was found to be directed superiorly in most of the cases. The average magnitude of the lead vector of Wilson's terminal was 0.097 omega/cm, which corresponded to about 1/4 of that of lead I.
Yutaka Shimizu - One of the best experts on this subject based on the ideXlab platform.
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the Absolute Voltage and the lead vector of wilson s central terminal
Japanese Heart Journal, 1996Co-Authors: Norio Miyamoto, Genyo Nishiyama, Yutaka Shimizu, Saburo Mashima, Yoshio OkamotoAbstract:The Absolute potential value of Wilson's central terminal was calculated at 2 msec intervals during a cardiac cycle in 60 clinical cases. Starting from the body surface potential data at 128 thoracic locations, the effect of immersion of the body into an infinite conductor on the surface potential was calculated to obtain values with reference to zero potential at infinity. The conductivity of the outside medium was then made to approach zero.Comparison of the result with the original map showed nearly a constant shift of the potential, corresponding to the Voltage of Wilson's terminal. In addition, the cardiac vector was calculated as the first approximation of the cardiac electromotive force and the lead vector of Wilson's terminal was obtained in order that the scalar product of the cardiac vector and the lead vector approximated the observed Voltage of Wilson's terminal.The results indicate that the Voltage of the Wilson electrode depended on the surface Voltage with a peak value near the maximal QRS force in most of the cases. The peak Voltage of Wilson's terminal was either positive or negative, and was 0.15mV in Absolute value on average. Voltage variations of Wilson's terminal during a cardiac cycle were 0.20mV as an average of all cases. The Voltage of Wilson's terminal also depended on the direction of the equivalent cardiac vector. The lead vector of Wilson's terminal was found to be directed superiorly in most of the cases. The average magnitude of the lead vector of Wilson's terminal was 0.097Ω/cm, which corresponded to about 1/4 of that of lead I.
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the Absolute Voltage and the lead vector of wilson s central terminal
Japanese Heart Journal, 1996Co-Authors: Norio Miyamoto, Genyo Nishiyama, Yutaka Shimizu, Saburo Mashima, Yoshio OkamotoAbstract:The Absolute potential value of Wilson's central terminal was calculated at 2 msec intervals during a cardiac cycle in 60 clinical cases. Starting from the body surface potential data at 128 thoracic locations, the effect of immersion of the body into an infinite conductor on the surface potential was calculated to obtain values with reference to zero potential at infinity. The conductivity of the outside medium was then made to approach zero. Comparison of the result with the original map showed nearly a constant shift of the potential, corresponding to the Voltage of Wilson's terminal. In addition, the cardiac vector was calculated as the first approximation of the cardiac electromotive force and the lead vector of Wilson's terminal was obtained in order that the scalar product of the cardiac vector and the lead vector approximated the observed Voltage of Wilson's terminal. The results indicate that the Voltage of the Wilson electrode depended on the surface Voltage with a peak value near the maximal QRS force in most of the cases. The peak Voltage of Wilson's terminal was either positive or negative, and was 0.15 mV in Absolute value on average. Voltage variations of Wilson's terminal during a cardiac cycle were 0.20 mV as an average of all cases. The Voltage of Wilson's terminal also depended on the direction of the equivalent cardiac vector. The lead vector of Wilson's terminal was found to be directed superiorly in most of the cases. The average magnitude of the lead vector of Wilson's terminal was 0.097 omega/cm, which corresponded to about 1/4 of that of lead I.
Saburo Mashima - One of the best experts on this subject based on the ideXlab platform.
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the Absolute Voltage and the lead vector of wilson s central terminal
Japanese Heart Journal, 1996Co-Authors: Norio Miyamoto, Genyo Nishiyama, Yutaka Shimizu, Saburo Mashima, Yoshio OkamotoAbstract:The Absolute potential value of Wilson's central terminal was calculated at 2 msec intervals during a cardiac cycle in 60 clinical cases. Starting from the body surface potential data at 128 thoracic locations, the effect of immersion of the body into an infinite conductor on the surface potential was calculated to obtain values with reference to zero potential at infinity. The conductivity of the outside medium was then made to approach zero.Comparison of the result with the original map showed nearly a constant shift of the potential, corresponding to the Voltage of Wilson's terminal. In addition, the cardiac vector was calculated as the first approximation of the cardiac electromotive force and the lead vector of Wilson's terminal was obtained in order that the scalar product of the cardiac vector and the lead vector approximated the observed Voltage of Wilson's terminal.The results indicate that the Voltage of the Wilson electrode depended on the surface Voltage with a peak value near the maximal QRS force in most of the cases. The peak Voltage of Wilson's terminal was either positive or negative, and was 0.15mV in Absolute value on average. Voltage variations of Wilson's terminal during a cardiac cycle were 0.20mV as an average of all cases. The Voltage of Wilson's terminal also depended on the direction of the equivalent cardiac vector. The lead vector of Wilson's terminal was found to be directed superiorly in most of the cases. The average magnitude of the lead vector of Wilson's terminal was 0.097Ω/cm, which corresponded to about 1/4 of that of lead I.
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the Absolute Voltage and the lead vector of wilson s central terminal
Japanese Heart Journal, 1996Co-Authors: Norio Miyamoto, Genyo Nishiyama, Yutaka Shimizu, Saburo Mashima, Yoshio OkamotoAbstract:The Absolute potential value of Wilson's central terminal was calculated at 2 msec intervals during a cardiac cycle in 60 clinical cases. Starting from the body surface potential data at 128 thoracic locations, the effect of immersion of the body into an infinite conductor on the surface potential was calculated to obtain values with reference to zero potential at infinity. The conductivity of the outside medium was then made to approach zero. Comparison of the result with the original map showed nearly a constant shift of the potential, corresponding to the Voltage of Wilson's terminal. In addition, the cardiac vector was calculated as the first approximation of the cardiac electromotive force and the lead vector of Wilson's terminal was obtained in order that the scalar product of the cardiac vector and the lead vector approximated the observed Voltage of Wilson's terminal. The results indicate that the Voltage of the Wilson electrode depended on the surface Voltage with a peak value near the maximal QRS force in most of the cases. The peak Voltage of Wilson's terminal was either positive or negative, and was 0.15 mV in Absolute value on average. Voltage variations of Wilson's terminal during a cardiac cycle were 0.20 mV as an average of all cases. The Voltage of Wilson's terminal also depended on the direction of the equivalent cardiac vector. The lead vector of Wilson's terminal was found to be directed superiorly in most of the cases. The average magnitude of the lead vector of Wilson's terminal was 0.097 omega/cm, which corresponded to about 1/4 of that of lead I.
