Assessment of blood flow velocity and pulsatility in cerebral perforating arteries with 7-T quantitative flow MRI

Thus far, blood flow velocity measurements with MRI have only been feasible in large cerebral blood vessels. High‐field‐strength MRI may now permit velocity measurements in much smaller arteries. The aim of this proof of principle study was to measure the blood flow velocity and pulsatility of cereb...

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Published inNMR in biomedicine Vol. 29; no. 9; pp. 1295 - 1304
Main Authors Bouvy, W. H., Geurts, L. J., Kuijf, H. J., Luijten, P. R., Kappelle, L. J., Biessels, G. J., Zwanenburg, J. J. M.
Format Journal Article
LanguageEnglish
Published England Blackwell Publishing Ltd 01.09.2016
Wiley Subscription Services, Inc
John Wiley and Sons Inc
Subjects
Adult
blood
Blood Flow Velocity - physiology
brain
Cerebral Angiography - methods
Cerebral Arteries - anatomy & histology
Cerebral Arteries - physiology
Cerebrovascular Circulation - physiology
Female
Humans
Image Enhancement - methods
Image Interpretation, Computer-Assisted - methods
Magnetic Fields
Magnetic Resonance Angiography - methods
Male
MRI
Pulsatile Flow - physiology
pulsatility
Qflow
Radiation Dosage
Reproducibility of Results
Sensitivity and Specificity
Special Issue
Special Issue s
velocity
pulsatility
Qflow
velocity
brain
MRI
blood
Online AccessGet full text
ISSN0952-3480
1099-1492
1099-1492
DOI10.1002/nbm.3306

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Abstract Thus far, blood flow velocity measurements with MRI have only been feasible in large cerebral blood vessels. High‐field‐strength MRI may now permit velocity measurements in much smaller arteries. The aim of this proof of principle study was to measure the blood flow velocity and pulsatility of cerebral perforating arteries with 7‐T MRI. A two‐dimensional (2D), single‐slice quantitative flow (Qflow) sequence was used to measure blood flow velocities during the cardiac cycle in perforating arteries in the basal ganglia (BG) and semioval centre (CSO), from which a mean normalised pulsatility index (PI) per region was calculated (n = 6 human subjects, aged 23–29 years). The precision of the measurements was determined by repeated imaging and performance of a Bland–Altman analysis, and confounding effects of partial volume and noise on the measurements were simulated. The median number of arteries included was 14 in CSO and 19 in BG. In CSO, the average velocity per volunteer was in the range 0.5–1.0 cm/s and PI was 0.24–0.39. In BG, the average velocity was in the range 3.9–5.1 cm/s and PI was 0.51–0.62. Between repeated scans, the precision of the average, maximum and minimum velocity per vessel decreased with the size of the arteries, and was relatively low in CSO and BG compared with the M1 segment of the middle cerebral artery. The precision of PI per region was comparable with that of M1. The simulations proved that velocities can be measured in vessels with a diameter of more than 80 µm, but are underestimated as a result of partial volume effects, whilst pulsatility is overestimated. Blood flow velocity and pulsatility in cerebral perforating arteries have been measured directly in vivo for the first time, with moderate to good precision. This may be an interesting metric for the study of haemodynamic changes in aging and cerebral small vessel disease. © 2015 The Authors NMR in Biomedicine Published by John Wiley & Sons Ltd. A two‐dimensional, single‐slice, quantitative flow (Qflow) sequence on a 7‐T system yielded the first non‐invasive in vivo measurements of blood flow velocity and pulsatility in cerebral perforating arteries in the basal ganglia (BG) and semioval centre (CSO), with the middle cerebral artery as reference. The precision of the velocity measurements in individual vessels and the pulsatility index per anatomical region was determined using Bland–Altman analysis. This sequence allows the study of the haemodynamics of cerebral perforating arteries and their association with, for example, vascular lesions.
AbstractList Thus far, blood flow velocity measurements with MRI have only been feasible in large cerebral blood vessels. High-field-strength MRI may now permit velocity measurements in much smaller arteries. The aim of this proof of principle study was to measure the blood flow velocity and pulsatility of cerebral perforating arteries with 7-T MRI. A two-dimensional (2D), single-slice quantitative flow (Qflow) sequence was used to measure blood flow velocities during the cardiac cycle in perforating arteries in the basal ganglia (BG) and semioval centre (CSO), from which a mean normalised pulsatility index (PI) per region was calculated (n = 6 human subjects, aged 23-29 years). The precision of the measurements was determined by repeated imaging and performance of a Bland-Altman analysis, and confounding effects of partial volume and noise on the measurements were simulated. The median number of arteries included was 14 in CSO and 19 in BG. In CSO, the average velocity per volunteer was in the range 0.5-1.0 cm/s and PI was 0.24-0.39. In BG, the average velocity was in the range 3.9-5.1 cm/s and PI was 0.51-0.62. Between repeated scans, the precision of the average, maximum and minimum velocity per vessel decreased with the size of the arteries, and was relatively low in CSO and BG compared with the M1 segment of the middle cerebral artery. The precision of PI per region was comparable with that of M1. The simulations proved that velocities can be measured in vessels with a diameter of more than 80 mu m, but are underestimated as a result of partial volume effects, whilst pulsatility is overestimated. Blood flow velocity and pulsatility in cerebral perforating arteries have been measured directly in vivo for the first time, with moderate to good precision. This may be an interesting metric for the study of haemodynamic changes in aging and cerebral small vessel disease. copyright 2015 The Authors NMR in Biomedicine Published by John Wiley & Sons Ltd. A two-dimensional, single-slice, quantitative flow (Qflow) sequence on a 7-T system yielded the first non-invasive invivo measurements of blood flow velocity and pulsatility in cerebral perforating arteries in the basal ganglia (BG) and semioval centre (CSO), with the middle cerebral artery as reference. The precision of the velocity measurements in individual vessels and the pulsatility index per anatomical region was determined using Bland-Altman analysis. This sequence allows the study of the haemodynamics of cerebral perforating arteries and their association with, for example, vascular lesions.
Thus far, blood flow velocity measurements with MRI have only been feasible in large cerebral blood vessels. High‐field‐strength MRI may now permit velocity measurements in much smaller arteries. The aim of this proof of principle study was to measure the blood flow velocity and pulsatility of cerebral perforating arteries with 7‐T MRI. A two‐dimensional (2D), single‐slice quantitative flow (Qflow) sequence was used to measure blood flow velocities during the cardiac cycle in perforating arteries in the basal ganglia (BG) and semioval centre (CSO), from which a mean normalised pulsatility index (PI) per region was calculated (n = 6 human subjects, aged 23–29 years). The precision of the measurements was determined by repeated imaging and performance of a Bland–Altman analysis, and confounding effects of partial volume and noise on the measurements were simulated. The median number of arteries included was 14 in CSO and 19 in BG. In CSO, the average velocity per volunteer was in the range 0.5–1.0 cm/s and PI was 0.24–0.39. In BG, the average velocity was in the range 3.9–5.1 cm/s and PI was 0.51–0.62. Between repeated scans, the precision of the average, maximum and minimum velocity per vessel decreased with the size of the arteries, and was relatively low in CSO and BG compared with the M1 segment of the middle cerebral artery. The precision of PI per region was comparable with that of M1. The simulations proved that velocities can be measured in vessels with a diameter of more than 80 µm, but are underestimated as a result of partial volume effects, whilst pulsatility is overestimated. Blood flow velocity and pulsatility in cerebral perforating arteries have been measured directly in vivo for the first time, with moderate to good precision. This may be an interesting metric for the study of haemodynamic changes in aging and cerebral small vessel disease. © 2015 The Authors NMR in Biomedicine Published by John Wiley & Sons Ltd. A two‐dimensional, single‐slice, quantitative flow (Qflow) sequence on a 7‐T system yielded the first non‐invasive in vivo measurements of blood flow velocity and pulsatility in cerebral perforating arteries in the basal ganglia (BG) and semioval centre (CSO), with the middle cerebral artery as reference. The precision of the velocity measurements in individual vessels and the pulsatility index per anatomical region was determined using Bland–Altman analysis. This sequence allows the study of the haemodynamics of cerebral perforating arteries and their association with, for example, vascular lesions.
Thus far, blood flow velocity measurements with MRI have only been feasible in large cerebral blood vessels. High-field-strength MRI may now permit velocity measurements in much smaller arteries. The aim of this proof of principle study was to measure the blood flow velocity and pulsatility of cerebral perforating arteries with 7-T MRI. A two-dimensional (2D), single-slice quantitative flow (Qflow) sequence was used to measure blood flow velocities during the cardiac cycle in perforating arteries in the basal ganglia (BG) and semioval centre (CSO), from which a mean normalised pulsatility index (PI) per region was calculated (n = 6 human subjects, aged 23-29 years). The precision of the measurements was determined by repeated imaging and performance of a Bland-Altman analysis, and confounding effects of partial volume and noise on the measurements were simulated. The median number of arteries included was 14 in CSO and 19 in BG. In CSO, the average velocity per volunteer was in the range 0.5-1.0 cm/s and PI was 0.24-0.39. In BG, the average velocity was in the range 3.9-5.1 cm/s and PI was 0.51-0.62. Between repeated scans, the precision of the average, maximum and minimum velocity per vessel decreased with the size of the arteries, and was relatively low in CSO and BG compared with the M1 segment of the middle cerebral artery. The precision of PI per region was comparable with that of M1. The simulations proved that velocities can be measured in vessels with a diameter of more than 80 µm, but are underestimated as a result of partial volume effects, whilst pulsatility is overestimated. Blood flow velocity and pulsatility in cerebral perforating arteries have been measured directly in vivo for the first time, with moderate to good precision. This may be an interesting metric for the study of haemodynamic changes in aging and cerebral small vessel disease. © 2015 The Authors NMR in Biomedicine Published by John Wiley & Sons Ltd.Thus far, blood flow velocity measurements with MRI have only been feasible in large cerebral blood vessels. High-field-strength MRI may now permit velocity measurements in much smaller arteries. The aim of this proof of principle study was to measure the blood flow velocity and pulsatility of cerebral perforating arteries with 7-T MRI. A two-dimensional (2D), single-slice quantitative flow (Qflow) sequence was used to measure blood flow velocities during the cardiac cycle in perforating arteries in the basal ganglia (BG) and semioval centre (CSO), from which a mean normalised pulsatility index (PI) per region was calculated (n = 6 human subjects, aged 23-29 years). The precision of the measurements was determined by repeated imaging and performance of a Bland-Altman analysis, and confounding effects of partial volume and noise on the measurements were simulated. The median number of arteries included was 14 in CSO and 19 in BG. In CSO, the average velocity per volunteer was in the range 0.5-1.0 cm/s and PI was 0.24-0.39. In BG, the average velocity was in the range 3.9-5.1 cm/s and PI was 0.51-0.62. Between repeated scans, the precision of the average, maximum and minimum velocity per vessel decreased with the size of the arteries, and was relatively low in CSO and BG compared with the M1 segment of the middle cerebral artery. The precision of PI per region was comparable with that of M1. The simulations proved that velocities can be measured in vessels with a diameter of more than 80 µm, but are underestimated as a result of partial volume effects, whilst pulsatility is overestimated. Blood flow velocity and pulsatility in cerebral perforating arteries have been measured directly in vivo for the first time, with moderate to good precision. This may be an interesting metric for the study of haemodynamic changes in aging and cerebral small vessel disease. © 2015 The Authors NMR in Biomedicine Published by John Wiley & Sons Ltd.
Thus far, blood flow velocity measurements with MRI have only been feasible in large cerebral blood vessels. High‐field‐strength MRI may now permit velocity measurements in much smaller arteries. The aim of this proof of principle study was to measure the blood flow velocity and pulsatility of cerebral perforating arteries with 7‐T MRI. A two‐dimensional (2D), single‐slice quantitative flow (Qflow) sequence was used to measure blood flow velocities during the cardiac cycle in perforating arteries in the basal ganglia (BG) and semioval centre (CSO), from which a mean normalised pulsatility index (PI) per region was calculated ( n = 6 human subjects, aged 23–29 years). The precision of the measurements was determined by repeated imaging and performance of a Bland–Altman analysis, and confounding effects of partial volume and noise on the measurements were simulated. The median number of arteries included was 14 in CSO and 19 in BG. In CSO, the average velocity per volunteer was in the range 0.5–1.0 cm/s and PI was 0.24–0.39. In BG, the average velocity was in the range 3.9–5.1 cm/s and PI was 0.51–0.62. Between repeated scans, the precision of the average, maximum and minimum velocity per vessel decreased with the size of the arteries, and was relatively low in CSO and BG compared with the M1 segment of the middle cerebral artery. The precision of PI per region was comparable with that of M1. The simulations proved that velocities can be measured in vessels with a diameter of more than 80 µm, but are underestimated as a result of partial volume effects, whilst pulsatility is overestimated. Blood flow velocity and pulsatility in cerebral perforating arteries have been measured directly in vivo for the first time, with moderate to good precision. This may be an interesting metric for the study of haemodynamic changes in aging and cerebral small vessel disease. © 2015 The Authors NMR in Biomedicine Published by John Wiley & Sons Ltd.
Thus far, blood flow velocity measurements with MRI have only been feasible in large cerebral blood vessels. High-field-strength MRI may now permit velocity measurements in much smaller arteries. The aim of this proof of principle study was to measure the blood flow velocity and pulsatility of cerebral perforating arteries with 7-T MRI. A two-dimensional (2D), single-slice quantitative flow (Qflow) sequence was used to measure blood flow velocities during the cardiac cycle in perforating arteries in the basal ganglia (BG) and semioval centre (CSO), from which a mean normalised pulsatility index (PI) per region was calculated (n = 6 human subjects, aged 23-29 years). The precision of the measurements was determined by repeated imaging and performance of a Bland-Altman analysis, and confounding effects of partial volume and noise on the measurements were simulated. The median number of arteries included was 14 in CSO and 19 in BG. In CSO, the average velocity per volunteer was in the range 0.5-1.0 cm/s and PI was 0.24-0.39. In BG, the average velocity was in the range 3.9-5.1 cm/s and PI was 0.51-0.62. Between repeated scans, the precision of the average, maximum and minimum velocity per vessel decreased with the size of the arteries, and was relatively low in CSO and BG compared with the M1 segment of the middle cerebral artery. The precision of PI per region was comparable with that of M1. The simulations proved that velocities can be measured in vessels with a diameter of more than 80 µm, but are underestimated as a result of partial volume effects, whilst pulsatility is overestimated. Blood flow velocity and pulsatility in cerebral perforating arteries have been measured directly in vivo for the first time, with moderate to good precision. This may be an interesting metric for the study of haemodynamic changes in aging and cerebral small vessel disease. © 2015 The Authors NMR in Biomedicine Published by John Wiley & Sons Ltd.
Author Zwanenburg, J. J. M.
Kappelle, L. J.
Biessels, G. J.
Geurts, L. J.
Kuijf, H. J.
Bouvy, W. H.
Luijten, P. R.
AuthorAffiliation 2 Image Sciences Institute University Medical Center Utrecht the Netherlands
1 Brain Centre Rudolf Magnus Department of Neurology, University Medical Center the Netherlands
3 Department of Radiology University Medical Center Utrecht the Netherlands
AuthorAffiliation_xml – name: 1 Brain Centre Rudolf Magnus Department of Neurology, University Medical Center the Netherlands
– name: 2 Image Sciences Institute University Medical Center Utrecht the Netherlands
– name: 3 Department of Radiology University Medical Center Utrecht the Netherlands
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  surname: Bouvy
  fullname: Bouvy, W. H.
  email: Correspondence to: W. H. Bouvy, Brain Centre Rudolf Magnus, Department of Neurology, University Medical Center Utrecht, 3684CX, Heidelberglaan 100, the Netherlands. , wbouvy@umcutrecht.nl
  organization: Brain Centre Rudolf Magnus, Department of Neurology, University Medical Center, the Netherlands
– sequence: 2
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  surname: Geurts
  fullname: Geurts, L. J.
  organization: Image Sciences Institute, University Medical Center, Utrecht, the Netherlands
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  organization: Image Sciences Institute, University Medical Center, Utrecht, the Netherlands
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  surname: Biessels
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  organization: Brain Centre Rudolf Magnus, Department of Neurology, University Medical Center, the Netherlands
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  givenname: J. J. M.
  surname: Zwanenburg
  fullname: Zwanenburg, J. J. M.
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BackLink https://www.ncbi.nlm.nih.gov/pubmed/25916399$$D View this record in MEDLINE/PubMed
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ContentType Journal Article
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2015 The Authors. NMR in Biomedicine Published by John Wiley & Sons Ltd.
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DocumentTitleAlternate Blood Flow Velocity And Pulsatility In Cerebral Perforating Arteries
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Issue 9
Keywords pulsatility
Qflow
velocity
brain
MRI
blood
Language English
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2015 The Authors. NMR in Biomedicine Published by John Wiley & Sons Ltd.
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These authors contributed equally to this work.
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Koutsiaris AG, Tachmitzi SV, Papavasileiou P, Batis N, Kotoula MG, Giannoukas AD, Tsironi E. Blood velocity pulse quantification in the human conjunctival pre-capillary arterioles. Microvasc. Res. 2010; 80(2): 202-208.
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Bude RO, Rubin JM. Relationship between the resistive index and vascular compliance and resistance. Radiology 1999; 211(2): 411-417.
Young S, Bystrov D, Netsch T, Bergmans R, van Muiswinkel A, Visser F, Sprigorum R, Gieseke J. Automated planning of MRI neuro scans. Proc. SPIE 2006; 61441M.
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Kang C-K, Park C-W, Han J-Y, Kim S-H, Park C-A, Kim K-N, Hong S-M, Kim Y-B, Lee KH, Cho Z-H. Imaging and analysis of lenticulostriate arteries using 7.0-Tesla magnetic resonance angiography. Magn. Reson. Med. 2009; 61(1): 136-144.
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Nagaoka T, Yoshida A. Noninvasive evaluation of wall shear stress on retinal microcirculation in humans. Invest. Ophthalmol. Vis. Sci. 2006; 47(3): 1113-1119.
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Hendrikse J, Zwanenburg JJM, Visser F, Takahara T, Luijten P. Noninvasive depiction of the lenticulostriate arteries with time-of-flight MR angiography at 7.0 T. Cerebrovasc. Dis. 2008; 26(6): 624-629.
Mitchell GF. Physiology of the aging vasculature. Effects of central arterial aging on the structure and function of the peripheral vasculature: implications for end-organ damage. J. Appl. Physiol. 2008; 105(5): 1652-1660.
Henskens LHG, Kroon AA, van Oostenbrugge RJ, Gronenschild EHBM, Fuss-Lejeune MMJJ, Hofman PAM, Lodder J, de Leeuw P. Increased aortic pulse wave velocity is associated with silent cerebral small-vessel disease in hypertensive patients. Hypertension 2008; 52(6): 1120-1126.
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Snippet Thus far, blood flow velocity measurements with MRI have only been feasible in large cerebral blood vessels. High‐field‐strength MRI may now permit velocity...
Thus far, blood flow velocity measurements with MRI have only been feasible in large cerebral blood vessels. High-field-strength MRI may now permit velocity...
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StartPage 1295
SubjectTerms Adult
blood
Blood Flow Velocity - physiology
brain
Cerebral Angiography - methods
Cerebral Arteries - anatomy & histology
Cerebral Arteries - physiology
Cerebrovascular Circulation - physiology
Female
Humans
Image Enhancement - methods
Image Interpretation, Computer-Assisted - methods
Magnetic Fields
Magnetic Resonance Angiography - methods
Male
MRI
Pulsatile Flow - physiology
pulsatility
Qflow
Radiation Dosage
Reproducibility of Results
Sensitivity and Specificity
Special Issue
Special Issue s
velocity
Title Assessment of blood flow velocity and pulsatility in cerebral perforating arteries with 7-T quantitative flow MRI
URI https://api.istex.fr/ark:/67375/WNG-8H8ZC258-X/fulltext.pdf
https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fnbm.3306
https://www.ncbi.nlm.nih.gov/pubmed/25916399
https://www.proquest.com/docview/1812451467
https://www.proquest.com/docview/1812886873
https://www.proquest.com/docview/1815698466
https://pubmed.ncbi.nlm.nih.gov/PMC5008170
Volume 29
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