[1] M. Campos-Benitez, A.M. Kaufmann, Neurovascular compression findings in
hemifacial spasm, J. Neurosurg. 109 (3) (2008) 416–420.
[2] T. Yamazaki, T. Yamamoto, T. Hatayama, A. Zaboronok, E. Ishikawa, H. Akutsu,
M. Matsuda, N. Kato, A. Matsumura, Abducent nerve palsy treated by microvascular
decompression: a case report and review of the literature, Acta Neurochir. 157 (10)
(2015) 1801–1805.
[3] Y. Kuroi, S. Tani, H. Ohbuchi, H. Kasuya, Microvascular decompression for hypoglossal nerve palsy secondary to vertebral artery compression: a case report and
review of the literature, Surg. Neurol. Int. 8 (2017) 74.
[4] D.M. Jacobson, J.J. Warner, S.K. Broste, Optic nerve contact and compression by
the carotid artery in asymptomatic patients, Am J. Ophthalmol. 123 (5) (1997)
677–683.
[5] C. Oesman, J.J. Mooij, Long-term follow-up of microvascular decompression for
trigeminal neuralgia, Skull Base 21 (5) (2011) 313–322.
[6] M. Sindou, P. Mercier, Microvascular decompression for hemifacial spasm: outcome
on spasm and complications. A review, Neuro-Chirurgie 64 (2) (2018) 106–116.
[7] P.J. Jannetta, R. Segal, S.K. Wolfson Jr., Neurogenic hypertension: etiology and
surgical treatment. I. Observations in 53 patients, Ann. Surg. 201 (3) (1985)
391–398.
[8] E.I. Levy, B. Clyde, M.R. McLaughlin, P.J. Jannetta, Microvascular decompression
of the left lateral medulla oblongata for severe refractory neurogenic hypertension,
Neurosurgery 43 (1) (1998) 1–6 (discussion 6-9).
[9] P. Legrady, E. Voros, D. Bajcsi, I. Fejes, P. Barzo, G. Abraham, Observations of
changes of blood pressure before and after neurosurgical decompression in hypertensive patients with different types of neurovascular compression of brain stem,
Kidney Blood Press. Res. 37 (4–5) (2013) 451–457.
[10] M. Sindou, M. Mahmoudi, A. Brinzeu, Hypertension of neurogenic origin: effect of
microvascular decompression of the CN IX-X root entry/exit zone and ventrolateral
medulla on blood pressure in a prospective series of 48 patients with hemifacial
spasm associated with essential hypertension, J. Neurosurg. 123 (6) (2015)
1405–1413.
[11] H. Geiger, R. Naraghi, H.P. Schobel, H. Frank, R.B. Sterzel, R. Fahlbusch, Decrease
of blood pressure by ventrolateral medullary decompression in essential hypertension, Lancet 352 (9126) (1998) 446–449.
[12] S. Morimoto, S. Sasaki, K. Takeda, S. Furuya, S. Naruse, K. Matsumoto, T. Higuchi,
M. Saito, M. Nakagawa, Decreases in blood pressure and sympathetic nerve activity
by microvascular decompression of the rostral ventrolateral medulla in essential
hypertension, Stroke 30 (8) (1999) 1707–1710.
[13] M.M. Sendeski, F.M. Consolim-Colombo, E.M. Krieger, C. Leite Cda, The spectrum
of magnetic resonance imaging findings in hypertension-related neurovascular
compression, Neuroradiology 48 (1) (2006) 21–25.
[14] D. Caldwell, ANSI/NCSL Z540.3:2006, Requirements for the calibration of measuring and test equipment, NCSLI Measure 1 (4) (2006) 26–30.
[15] S. Aoki, T. Ohtsuki, N. Hosomi, Y. Sueda, T. Kono, T. Yamawaki, M. Matsumoto,
Blood pressure variability and prognosis in acute ischemic stroke with vascular
compression on the rostral ventrolateral medulla (RVLM), Hypertens. Res. 34 (5)
(2011) 617–622.
[16] C.J. McGinnity, A. Hammers, D.A. Riano Barros, S.K. Luthra, P.A. Jones, W. Trigg,
C. Micallef, M.R. Symms, D.J. Brooks, M.J. Koepp, J.S. Duncan, Initial evaluation of
18F-GE-179, a putative PET tracer for activated N-methyl D-aspartate receptors, J.
Nucl. Med. 55 (3) (2014) 423–430.
[17] W. Osler, The principles and practice of medicine, Appleton, The Principles and
Practice of Medicine, 3rd Edition. Appleton, 3rd ed., 1898.
[18] M.H. Chowdhury, A. Nagai, H. Bokura, E. Nakamura, S. Kobayashi, S. Yamaguchi,
Age-related changes in white matter lesions, hippocampal atrophy, and cerebral
microbleeds in healthy subjects without major cerebrovascular risk factors, J.
Stroke Cerebrovasc. Dis. 20 (4) (2011) 302–309.
[19] Y. Li, W.J. Choi, W. Wei, S. Song, Q. Zhang, J. Liu, R.K. Wang, Aging-associated
changes in cerebral vasculature and blood flow as determined by quantitative optical coherence tomography angiography, Neurobiol. Aging 70 (2018) 148–159.
[20] O. Mirea, I. Donoiu, I.E. Plesea, Arterial aging: a brief review, Romanian J.
Downloaded for Anonymous User (n/a) at Kure Medical Center from ClinicalKey.jp by Elsevier on June 23, 2020.
For personal use only. No other uses without permission. Copyright ©2020. Elsevier Inc. All rights reserved.
-RXUQDORIWKH1HXURORJLFDO6FLHQFHV
Y. Dodo, et al.
tonometry measured pulse wave velocity, BMC Cardiovasc. Disord. 17 (1) (2017)
118.
[24] M. Nishikata, Y. Hirashima, T. Tomita, R. Futatsuya, Y. Horie, S. Endo,
Measurement of basilar artery bending and elongation by magnetic resonance
cerebral angiography: relationship to age, sex and vertebral artery dominance,
Arch. Gerontol. Geriatr. 38 (3) (2004) 251–259.
[25] J. Sugawara, K. Hayashi, T. Yokoi, H. Tanaka, Age-associated elongation of the
ascending aorta in adults, J. Am. Coll. Cardiol. Img. 1 (6) (2008) 739–748.
[26] https://www.e-stat.go.jp/dbview?sid=0003147022 (in Japanese).
Morphol. Embryol. 53 (3) (2012) 473–477.
[21] M. Lin, S.L. Lin, K.L. Wang, H.W. Kuo, T. Tak, Effect of aging on human circulatory
system in normotensive healthy subjects, Int. J. Angiol. 23 (4) (2014) 233–242.
[22] R. Dittrich, I. Nassenstein, S. Harms, D. Maintz, W. Heindel, G. Kuhlenbaumer,
E.B. Ringelstein, Arterial elongation (“redundancy”) is not a feature of spontaneous
cervical artery dissection, J. Neurol. 258 (2) (2011) 250–254.
[23] J.R. Weir-McCall, F. Khan, D.B. Cassidy, A. Thakur, J. Summersgill, S.Z. Matthew,
F. Adams, F. Dove, S.J. Gandy, H.M. Colhoun, J.J. Belch, J.G. Houston, Effects of
inaccuracies in arterial path length measurement on differences in MRI and
Downloaded for Anonymous User (n/a) at Kure Medical Center from ClinicalKey.jp by Elsevier on June 23, 2020.
For personal use only. No other uses without permission. Copyright ©2020. Elsevier Inc. All rights reserved.
...