The objective of this work is to quantify age-related differences in the characteristics and coupling of cerebral arterial inflow and cerebrospinal fluid (CSF) dynamics. To this end, 3T phase-contrast magnetic resonance imaging blood and CSF flow data of eleven young ( years) and eleven elderly subjects ( years) with a comparable sex-ratio were acquired. Flow waveforms and their frequency composition, transfer functions from blood to CSF flows and cross-correlations were analyzed. The magnitudes of the frequency components of CSF flow in the aqueduct differ significantly between the two age groups, as do the frequency components of the cervical spinal CSF and the arterial flows. The males' aqueductal CSF stroke volumes and average flow rates are significantly higher than those of the females. Transfer functions and cross-correlations between arterial blood and CSF flow reveal significant age-dependence of phase-shift between these, as do the waveforms of arterial blood, as well as cervical-spinal and aqueductal CSF flows. These findings accentuate the need for age- and sex-matched control groups for the evaluation of cerebral pathologies such as hydrocephalus.
References
[1]
Barkhof F, Kouwenhoven M, Scheltens P, Sprenger M, Algra P, et al. (1994) Phase-contrast cine MR imaging of normal aqueductal CSF flow. effect of aging and relation to CSF void on modulus MR. Acta Radiol 35: 123–130.
[2]
Gideon P, Thomsen C, St?hlberg F, Henriksen O (1994) Cerebrospinal fluid production and dynamics in normal aging: a MRI phase-mapping study. Acta Neurol Scand 89: 362–366.
[3]
Uftring SJ, Chu D, Alperin N, Levin DN (2000) The mechanical state of intracranial tissues in elderly subjects studied by imaging CSF and brain pulsations. Magn Reson Imaging 18: 991–996.
[4]
Stoquart-ElSankari S, Balédent O, Gondry-Jouet C, Makki M, Godefroy O, et al. (2007) Aging effects on cerebral blood and cerebrospinal fluid flows. J Cereb Blood Flow Metab 27: 1563–1572.
[5]
Ford MD, Alperin N, Lee SH, Holdsworth DW, Steinman DA (2005) Characterization of volumetric flow rate waveforms in the normal internal carotid and vertebral arteries. Physiol Meas 26: 477–488.
[6]
Hoi Y, Wasserman BA, Xie YJ, Najjar SS, Ferruci L, et al. (2010) Characterization of volumetric flow rate waveforms at the carotid bifurcations of older adults. Physiol Meas 31: 291–302.
[7]
Miyati T, Mase M, Banno T, Kasuga T, Yamada K, et al. (2003) Frequency analyses of CSF flow on cine MRI in normal pressure hydrocephalus. Eur Radiol 13: 1019–1024.
[8]
Thomsen C, St?hlberg F, Stubgaard M, Nordell B (1990) Fourier analysis of cerebrospinal fluid flow velocities: MR imaging study. the scandinavian flow group. Radiology 177: 659–665.
[9]
Bateman GA, Levi CR, Schofield P, Wang Y, Lovett EC (2005) The pathophysiology of the aqueduct stroke volume in normal pressure hydrocephalus: can co-morbidity with other forms of dementia be excluded? Neuroradiology 47: 741–748.
[10]
Bradley W Jr, Scalzo D, Queralt J, Nitz WN, Atkinson DJ, et al. (1996) Normal-pressure hydrocephalus: evaluation with cerebrospinal fluid flow measurements at MR imaging. Radiology 198: 523–529.
[11]
Luetmer PH, Huston J, Friedman JA, Dixon GR, Petersen RC, et al. (2002) Measurement of cerebrospinal fluid flow at the cerebral aqueduct by use of phase-contrast magnetic resonance imaging: technique validation and utility in diagnosing idiopathic normal pressure hydrocephalus. Neurosurgery 50: 534–43; discussion 543–4.
[12]
Alperin N, Vikingstad EM, Gomez-Anson B, Levin DN (1996) Hemodynamically independent analysis of cerebrospinal fluid and brain motion observed with dynamic phase contrast MRI. Magn Reson Med 35: 741–754.
[13]
Tain RW, Alperin N (2009) Noninvasive intracranial compliance from MRI-based measurements of transcranial blood and CSF flows: indirect versus direct approach. IEEE Trans Biomed Eng 56: 544–551.
[14]
Balédent O, Gondry-Jouet C, Meyer ME, De Marco G, Le Gars D, et al. (2004) Relationship between cerebrospinal fluid and blood dynamics in healthy volunteers and patients with communicating hydrocephalus. Invest Radiol 39: 45–55.
[15]
de Marco G, Idy-Peretti I, Didon-Poncelet A, Balédent O, Onen F, et al. (2004) Intracranial fluid dynamics in normal and hydrocephalic states: systems analysis with phase-contrast magnetic resonance imaging. J Comput Assist Tomogr 28: 247–254.
[16]
Gideon P, St?hlberg F, Thomsen C, Gjerris F, Srensen PS, et al. (1994) Cerebrospinal fluid flow and production in patients with normal pressure hydrocephalus studied by MRI. Neuroradiology 36: 210–215.
[17]
Otsu N (1979) A threshold selection method from gray-level histograms. IEEE Trans Syst Man Cybern 9: 62–66.
[18]
Schibli M, Wyss M, Boesiger P, Guzzella L (2009) Investigation of ventricular cerebrospinal fluid flow phase differences between the foramina of monro and the aqueduct of sylvius. Biomed Tech (Berl) 54: 161–169.
[19]
Lotz J, Meier C, Leppert A, Galanski M (2002) Cardiovascular flow measurement with phasecontrast MR imaging: basic facts and implementation. Radiographics 22: 651–671.
[20]
Bombardini T, Gemignani V, Bianchini E, Venneri L, Petersen C, et al. (2008) Diastolic time - frequency relation in the stress echo lab: filling timing and flow at different heart rates. Cardiovasc Ultrasound 6: 15.
[21]
Oppenheim AV, Schafer RW (1999) Discrete-time signal processing 2nd ed. Upper Saddle River, NJ: Prentice Hall.
[22]
Fritsch FN, Carlson RE (1980) Monotone piecewise cubic interpolation. SIAM Journal on Numerical Analysis 17: 238–246.
[23]
Orfanidis S (1996) Introduction to signal processing. Englewood Cliffs, NJ: Prentice Hall.
[24]
Ljung L (1999) System identification: theory for the user, 2nd ed. Upper Saddle River, NJ: Prentice.
[25]
Grichisch Y, ?avu?o?lu M, Preissl H, Uluda? K, Hallschmid M, et al. (2012) Differential effects of intranasal insulin and caffeine on cerebral blood flow. Hum Brain Mapp 33: 280–287.
[26]
Chen Y, Parrish TB (2009) Caffeine's effects on cerebrovascular reactivity and coupling between cerebral blood flow and oxygen metabolism. Neuroimage 44: 647–652.
[27]
Han ME, Kim HJ, Lee YS, Kim DH, Choi JT, et al. (2009) Regulation of cerebrospinal fluid production by caffeine consumption. BMC Neurosci 10: 110.
[28]
Doepp F, Schreiber SJ, von Münster T, Rademacher J, Klingebiel R, et al. (2004) How does the blood leave the brain? A systematic ultrasound analysis of cerebral venous drainage patterns. Neuroradiology 46: 565–570.
[29]
Gisolf J, van Lieshout JJ, van Heusden K, Pott F, Stok WJ, et al. (2004) Human cerebral venous outflow pathway depends on posture and central venous pressure. J Physiol 560: 317–327.
[30]
Stoquart-Elsankari S, Lehmann P, Villette A, Czosnyka M, Meyer ME, et al. (2009) A phasecontrast MRI study of physiologic cerebral venous flow. J Cereb Blood Flow Metab 29: 1208–1215.
[31]
O'Rourke MF, Hashimoto J (2007) Mechanical factors in arterial aging: a clinical perspective. J Am Coll Cardiol 50: 1–13.
[32]
Gupta S, Soellinger M, Boesiger P, Poulikakos D, Kurtcuoglu V (2009) Three-dimensional computational modeling of subject-specific cerebrospinal fluid flow in the subarachnoid space. J Biomech Eng 131: 021010.
[33]
Hirata K, Yaginuma T, O'Rourke MF, Kawakami M (2006) Age-related changes in carotid artery flow and pressure pulses: possible implications for cerebral microvascular disease. Stroke 37: 2552–2556.
[34]
Sack I, Beierbach B, Wuerfel J, Klatt D, Hamhaber U, et al. (2009) The impact of aging and gender on brain viscoelasticity. Neuroimage 46: 652–657.
[35]
Rekate HL (2009) A contemporary definition and classification of hydrocephalus. Semin Pediatr Neurol 16: 9–15.
[36]
Czosnyka M, Czosnyka ZH, Whitfield PC, Donovan T, Pickard JD (2001) Age dependence of cerebrospinal pressure-volume compensation in patients with hydrocephalus. J Neurosurg 94: 482–486.
[37]
Enzinger C, Fazekas F, Matthews PM, Ropele S, Schmidt H, et al. (2005) Risk factors for progression of brain atrophy in aging: six-year follow-up of normal subjects. Neurology 64: 1704–1711.
[38]
Ropele S, Enzinger C, S?llinger M, Langkammer C, Wallner-Blazek M, et al. (2010) The impact of sex and vascular risk factors on brain tissue changes with aging: magnetization transfer imaging results of the austrian stroke prevention study. AJNR Am J Neuroradiol 31: 1297–1301.
[39]
Rudick RA, Fisher E, Lee JC, Simon J, Jacobs L (1999) Use of the brain parenchymal fraction to measure whole brain atrophy in relapsing-remitting MS. Multiple sclerosis collaborative research group. Neurology 53: 1698–1704.
[40]
Cosgrove KP, Mazure CM, Staley JK (2007) Evolving knowledge of sex differences in brain structure, function, and chemistry. Biol Psychiatry 62: 847–855.
[41]
Dolan RJ, Calloway SP, Mann AH (1985) Cerebral ventricular size in depressed subjects. Psychol Med 15: 873–878.
[42]
Xu J, Kobayashi S, Yamaguchi S, Iijima K, Okada K, et al. (2000) Gender effects on age-related changes in brain structure. AJNR Am J Neuroradiol 21: 112–118.
