Precise Estimation of Intravascular Pressure Gradients

This study presents a method for non-invasive pressure gradient estimation, which allows the detection of small pressure differences with a higher precision compared to invasive catheters. It combines a new method for estimating the temporal acceleration of the flowing blood with the Navier-Stokes e...

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Veröffentlicht in:	IEEE transactions on ultrasonics, ferroelectrics, and frequency control ferroelectrics, and frequency control, 2023-05, Vol.70 (5), p.1-1
Hauptverfasser:	Haslund, Lars Emil, Jorgensen, Lasse Thurmann, Stuart, Matthias Bo, Traberg, Marie Sand, Jensen, Jorgen Arendt
Format:	Artikel
Sprache:	eng
Schlagworte:	Acceleration Blood Flow Velocity Blood Pressure Carotid arteries Carotid Arteries - diagnostic imaging Carotid Artery, Common - diagnostic imaging Catheterization Catheters Cross correlation Data acquisition Differential equations Estimation Flow velocity Linear arrays Mathematical models Operators (mathematics) Pressure Pressure gradients Pressure measurement Pulse repetition frequency Streaming media Synthetic apertures Temporal resolution Ultrasonic imaging Ultrasonic methods Ultrasonic testing Ultrasonic variables measurement Ultrasonography - methods
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creator	Haslund, Lars Emil Jorgensen, Lasse Thurmann Stuart, Matthias Bo Traberg, Marie Sand Jensen, Jorgen Arendt
description	This study presents a method for non-invasive pressure gradient estimation, which allows the detection of small pressure differences with a higher precision compared to invasive catheters. It combines a new method for estimating the temporal acceleration of the flowing blood with the Navier-Stokes equation. The acceleration estimation is based on a double cross-correlation approach, which is hypothesized to minimize the influence of noise. Data are acquired using a 256 elements, 6.5 MHz GE L3-12-D linear array transducer connected to a Verasonics research scanner. A synthetic aperture interleaved sequence with 2×12 virtual sources evenly distributed over the aperture and permuted in emission order is used in combination with recursive imaging. This enables a temporal resolution between correlation frames equal to the pulse repetition time at a frame rate of half the pulse repetition frequency. The accuracy of the method is evaluated against a computational fluid dynamic simulation. Here, the estimated total pressure difference complies with the CFD reference pressure difference, which yields a R-square of 0.985 and a RMSE of 3.03 Pa. The precision of the method is tested on experimental data, measured on a carotid phantom of the common carotid artery. The volume profile used during measurement was set to mimic flow in the carotid artery with a peak flow rate of 12.9 mL/s. The experimental setup showed that the measured pressure difference changes from -59.4 to 31 Pa throughout a single pulse cycle. This was estimated with a precision of 5.44% (3.22 Pa) across ten pulse cycles. The method was also compared to invasive catheter measurements in a phantom with a 60% cross-sectional area reduction. The ultrasound method detected a maximum pressure difference of 72.3 Pa with a precision of 3.3% (2.22 Pa). The catheters measured a maximum pressure difference of 105 Pa with a precision of 11.2% (11.4 Pa). This was measured over the same constriction and with a peak flow rate of 12.9 mL/s. The double cross-correlation approach revealed no improvement compared to a normal differential operator. The method's strength, thus, lies primarily in the ultrasound sequence, which allows precise and accurate velocity estimations, at which acceleration and pressure differences can be acquired.
doi_str_mv	10.1109/TUFFC.2023.3255791
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It combines a new method for estimating the temporal acceleration of the flowing blood with the Navier-Stokes equation. The acceleration estimation is based on a double cross-correlation approach, which is hypothesized to minimize the influence of noise. Data are acquired using a 256 elements, 6.5 MHz GE L3-12-D linear array transducer connected to a Verasonics research scanner. A synthetic aperture interleaved sequence with 2×12 virtual sources evenly distributed over the aperture and permuted in emission order is used in combination with recursive imaging. This enables a temporal resolution between correlation frames equal to the pulse repetition time at a frame rate of half the pulse repetition frequency. The accuracy of the method is evaluated against a computational fluid dynamic simulation. Here, the estimated total pressure difference complies with the CFD reference pressure difference, which yields a R-square of 0.985 and a RMSE of 3.03 Pa. The precision of the method is tested on experimental data, measured on a carotid phantom of the common carotid artery. The volume profile used during measurement was set to mimic flow in the carotid artery with a peak flow rate of 12.9 mL/s. The experimental setup showed that the measured pressure difference changes from -59.4 to 31 Pa throughout a single pulse cycle. This was estimated with a precision of 5.44% (3.22 Pa) across ten pulse cycles. The method was also compared to invasive catheter measurements in a phantom with a 60% cross-sectional area reduction. The ultrasound method detected a maximum pressure difference of 72.3 Pa with a precision of 3.3% (2.22 Pa). The catheters measured a maximum pressure difference of 105 Pa with a precision of 11.2% (11.4 Pa). This was measured over the same constriction and with a peak flow rate of 12.9 mL/s. The double cross-correlation approach revealed no improvement compared to a normal differential operator. 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The precision of the method is tested on experimental data, measured on a carotid phantom of the common carotid artery. The volume profile used during measurement was set to mimic flow in the carotid artery with a peak flow rate of 12.9 mL/s. The experimental setup showed that the measured pressure difference changes from -59.4 to 31 Pa throughout a single pulse cycle. This was estimated with a precision of 5.44% (3.22 Pa) across ten pulse cycles. The method was also compared to invasive catheter measurements in a phantom with a 60% cross-sectional area reduction. The ultrasound method detected a maximum pressure difference of 72.3 Pa with a precision of 3.3% (2.22 Pa). The catheters measured a maximum pressure difference of 105 Pa with a precision of 11.2% (11.4 Pa). This was measured over the same constriction and with a peak flow rate of 12.9 mL/s. The double cross-correlation approach revealed no improvement compared to a normal differential operator. 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It combines a new method for estimating the temporal acceleration of the flowing blood with the Navier-Stokes equation. The acceleration estimation is based on a double cross-correlation approach, which is hypothesized to minimize the influence of noise. Data are acquired using a 256 elements, 6.5 MHz GE L3-12-D linear array transducer connected to a Verasonics research scanner. A synthetic aperture interleaved sequence with 2×12 virtual sources evenly distributed over the aperture and permuted in emission order is used in combination with recursive imaging. This enables a temporal resolution between correlation frames equal to the pulse repetition time at a frame rate of half the pulse repetition frequency. The accuracy of the method is evaluated against a computational fluid dynamic simulation. Here, the estimated total pressure difference complies with the CFD reference pressure difference, which yields a R-square of 0.985 and a RMSE of 3.03 Pa. The precision of the method is tested on experimental data, measured on a carotid phantom of the common carotid artery. The volume profile used during measurement was set to mimic flow in the carotid artery with a peak flow rate of 12.9 mL/s. The experimental setup showed that the measured pressure difference changes from -59.4 to 31 Pa throughout a single pulse cycle. This was estimated with a precision of 5.44% (3.22 Pa) across ten pulse cycles. The method was also compared to invasive catheter measurements in a phantom with a 60% cross-sectional area reduction. The ultrasound method detected a maximum pressure difference of 72.3 Pa with a precision of 3.3% (2.22 Pa). The catheters measured a maximum pressure difference of 105 Pa with a precision of 11.2% (11.4 Pa). This was measured over the same constriction and with a peak flow rate of 12.9 mL/s. The double cross-correlation approach revealed no improvement compared to a normal differential operator. The method's strength, thus, lies primarily in the ultrasound sequence, which allows precise and accurate velocity estimations, at which acceleration and pressure differences can be acquired.</abstract><cop>United States</cop><pub>IEEE</pub><pmid>37028315</pmid><doi>10.1109/TUFFC.2023.3255791</doi><tpages>1</tpages><orcidid>https://orcid.org/0000-0002-7896-3136</orcidid><orcidid>https://orcid.org/0000-0003-0809-530X</orcidid><orcidid>https://orcid.org/0000-0003-2824-4819</orcidid><orcidid>https://orcid.org/0000-0002-2426-2502</orcidid><orcidid>https://orcid.org/0000-0001-7090-6607</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Acceleration Blood Flow Velocity Blood Pressure Carotid arteries Carotid Arteries - diagnostic imaging Carotid Artery, Common - diagnostic imaging Catheterization Catheters Cross correlation Data acquisition Differential equations Estimation Flow velocity Linear arrays Mathematical models Operators (mathematics) Pressure Pressure gradients Pressure measurement Pulse repetition frequency Streaming media Synthetic apertures Temporal resolution Ultrasonic imaging Ultrasonic methods Ultrasonic testing Ultrasonic variables measurement Ultrasonography - methods
title	Precise Estimation of Intravascular Pressure Gradients
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