BACKGROUND: Small vessel diseases have been studied noninvasively with magnetic resonance imaging. Direct observation or visualization of the connected microvessel to the infarct, however, was not possible due to the limited resolution. Hence, one could not determine whether vessel occlusion or abnormal narrowing is the cause of an infarct. METHODS: In this report, we demonstrate that the small vessel related to the infarct can be detected using ultra-high-field (7 T) magnetic resonance imaging and a three dimensional image analysis and modeling technique for microvessels, which thereby enables us to quantify the vessel morphology directly, that is, visualize the vessel that is related to the infarct. We compared vessels of selected stroke patients, who had recovered from stroke, with vessels from typical stroke patients, who had after effects like motor weakness, and age-matched healthy subjects to demonstrate the potential of the technique. RESULTS: The experimental results show that typical stroke patients had overall degradation or loss of small vessels, compared with the selected patients as well as healthy subjects. The selected patients, however, had only minimal loss of vessels, except for one vessel located close to the infarct area. CONCLUSIONS: These preliminary results demonstrated that 7 T magnetic resonance imaging together with a three dimensional image analysis and modeling technique could provide information for detection of the vessel related to the infarct. In addition, three dimensional image analysis and modeling of vessels could further provide quantitative information on the microvessel structures comprising diameter, length and tortuosity.
BACKGROUND: Small vessel diseases have been studied noninvasively with magnetic resonance imaging. Direct observation or visualization of the connected microvessel to the infarct, however, was not possible due to the limited resolution. Hence, one could not determine whether vessel occlusion or abnormal narrowing is the cause of an infarct. METHODS: In this report, we demonstrate that the small vessel related to the infarct can be detected using ultra-high-field (7 T) magnetic resonance imaging and a three dimensional image analysis and modeling technique for microvessels, which thereby enables us to quantify the vessel morphology directly, that is, visualize the vessel that is related to the infarct. We compared vessels of selected strokepatients, who had recovered from stroke, with vessels from typical strokepatients, who had after effects like motor weakness, and age-matched healthy subjects to demonstrate the potential of the technique. RESULTS: The experimental results show that typical strokepatients had overall degradation or loss of small vessels, compared with the selected patients as well as healthy subjects. The selected patients, however, had only minimal loss of vessels, except for one vessel located close to the infarct area. CONCLUSIONS: These preliminary results demonstrated that 7 T magnetic resonance imaging together with a three dimensional image analysis and modeling technique could provide information for detection of the vessel related to the infarct. In addition, three dimensional image analysis and modeling of vessels could further provide quantitative information on the microvessel structures comprising diameter, length and tortuosity.
Authors: Ido R van den Wijngaard; Ghislaine Holswilder; Marianne A A van Walderveen; Ale Algra; Marieke J H Wermer; Osama O Zaidat; Jelis Boiten Journal: Brain Behav Date: 2016-08-31 Impact factor: 2.708
Authors: Derek Groen; Robin A Richardson; Rachel Coy; Ulf D Schiller; Hoskote Chandrashekar; Fergus Robertson; Peter V Coveney Journal: Front Physiol Date: 2018-06-19 Impact factor: 4.566
Authors: Giuseppe Barisano; Farshid Sepehrband; Samantha Ma; Kay Jann; Ryan Cabeen; Danny J Wang; Arthur W Toga; Meng Law Journal: Br J Radiol Date: 2018-11-01 Impact factor: 3.629