Your search keyword '"Raitamaa, L. (Lauri)"' showing total 14 results

1. Human NREM Sleep Promotes Brain-Wide Vasomotor and Respiratory Pulsations

Author

Helakari, H. (Heta), Korhonen, V. (Vesa), Holst, S. C. (Sebastian C.), Piispala, J. (Johanna), Kallio, M. (Mika), Väyrynen, T. (Tommi), Huotari, N. (Niko), Raitamaa, L. (Lauri), Tuunanen, J. (Johanna), Kananen, J. (Janne), Järvelä, M. (Matti), Tuovinen, T. (Timo), Raatikainen, V. (Ville), Borchardt, V. (Viola), Kinnunen, H. (Hannu), Nedergaard, M. (Maiken), Kiviniemi, V. (Vesa), Helakari, H. (Heta), Korhonen, V. (Vesa), Holst, S. C. (Sebastian C.), Piispala, J. (Johanna), Kallio, M. (Mika), Väyrynen, T. (Tommi), Huotari, N. (Niko), Raitamaa, L. (Lauri), Tuunanen, J. (Johanna), Kananen, J. (Janne), Järvelä, M. (Matti), Tuovinen, T. (Timo), Raatikainen, V. (Ville), Borchardt, V. (Viola), Kinnunen, H. (Hannu), Nedergaard, M. (Maiken), and Kiviniemi, V. (Vesa)

Abstract

The physiological underpinnings of the necessity of sleep remain uncertain. Recent evidence suggests that sleep increases the convection of cerebrospinal fluid (CSF) and promotes the export of interstitial solutes, thus providing a framework to explain why all vertebrate species require sleep. Cardiovascular, respiratory and vasomotor brain pulsations have each been shown to drive CSF flow along perivascular spaces, yet it is unknown how such pulsations may change during sleep in humans. To investigate these pulsation phenomena in relation to sleep, we simultaneously recorded fast fMRI, magnetic resonance encephalography (MREG), and electroencephalography (EEG) signals in a group of healthy volunteers. We quantified sleep-related changes in the signal frequency distributions by spectral entropy analysis and calculated the strength of the physiological (vasomotor, respiratory, and cardiac) brain pulsations by power sum analysis in 15 subjects (age 26.5 ± 4.2 years, 6 females). Finally, we identified spatial similarities between EEG slow oscillation (0.2–2 Hz) power and MREG pulsations. Compared with wakefulness, nonrapid eye movement (NREM) sleep was characterized by reduced spectral entropy and increased brain pulsation intensity. These effects were most pronounced in posterior brain areas for very low-frequency (≤0.1 Hz) vasomotor pulsations but were also evident brain-wide for respiratory pulsations, and to a lesser extent for cardiac brain pulsations. There was increased EEG slow oscillation power in brain regions spatially overlapping with those showing sleep-related MREG pulsation changes. We suggest that reduced spectral entropy and enhanced pulsation intensity are characteristic of NREM sleep. With our findings of increased power of slow oscillation, the present results support the proposition that sleep promotes fluid transport in human brain.

Published

2022

2. Increased interictal synchronicity of respiratory related brain pulsations in epilepsy

Author

Kananen, J. (Janne), Järvelä, M. (Matti), Korhonen, V. (Vesa), Tuovinen, T. (Timo), Huotari, N. (Niko), Raitamaa, L. (Lauri), Helakari, H. (Heta), Väyrynen, T. (Tommi), Raatikainen, V. (Ville), Nedergaard, M. (Maiken), Ansakorpi, H. (Hanna), Jacobs, J. (Julia), LeVan, P. (Pierre), Kiviniemi, V. (Vesa), Kananen, J. (Janne), Järvelä, M. (Matti), Korhonen, V. (Vesa), Tuovinen, T. (Timo), Huotari, N. (Niko), Raitamaa, L. (Lauri), Helakari, H. (Heta), Väyrynen, T. (Tommi), Raatikainen, V. (Ville), Nedergaard, M. (Maiken), Ansakorpi, H. (Hanna), Jacobs, J. (Julia), LeVan, P. (Pierre), and Kiviniemi, V. (Vesa)

Abstract

Respiratory brain pulsations have recently been shown to drive electrophysiological brain activity in patients with epilepsy. Furthermore, functional neuroimaging indicates that respiratory brain pulsations have increased variability and amplitude in patients with epilepsy compared to healthy individuals. To determine whether the respiratory drive is altered in epilepsy, we compared respiratory brain pulsation synchronicity between healthy controls and patients. Whole brain fast functional magnetic resonance imaging was performed on 40 medicated patients with focal epilepsy, 20 drug-naïve patients and 102 healthy controls. Cerebrospinal fluid associated respiratory pulsations were used to generate individual whole brain respiratory synchronization maps, which were compared between groups. Finally, we analyzed the seizure frequency effect and diagnostic accuracy of the respiratory synchronization defect in epilepsy. Respiratory brain pulsations related to the verified fourth ventricle pulsations were significantly more synchronous in patients in frontal, periventricular and mid-temporal regions, while the seizure frequency correlated positively with synchronicity. The respiratory brain synchronicity had a good diagnostic accuracy (ROCAUC = 0.75) in discriminating controls from medicated patients. The elevated respiratory brain synchronicity in focal epilepsy suggests altered physiological effect of cerebrospinal fluid pulsations possibly linked to regional brain water dynamics involved with interictal brain physiology.

Published

2022

3. Physiological instability is linked to mortality in primary central nervous system lymphoma:a case–control fMRI study

Author

Poltojainen, V. (Valter), Kemppainen, J. (Janette), Keinänen, N. (Nina), Bode, M. (Michaela), Isokangas, J.-M. (Juha-Matti), Kuitunen, H. (Hanne), Nikkinen, J. (Juha), Sonkajärvi, E. (Eila), Korhonen, V. (Vesa), Tuovinen, T. (Timo), Järvelä, M. (Matti), Huotari, N. (Niko), Raitamaa, L. (Lauri), Kananen, J. (Janne), Korhonen, T. (Tommi), Tetri, S. (Sami), Kuittinen, O. (Outi), Kiviniemi, V. (Vesa), Poltojainen, V. (Valter), Kemppainen, J. (Janette), Keinänen, N. (Nina), Bode, M. (Michaela), Isokangas, J.-M. (Juha-Matti), Kuitunen, H. (Hanne), Nikkinen, J. (Juha), Sonkajärvi, E. (Eila), Korhonen, V. (Vesa), Tuovinen, T. (Timo), Järvelä, M. (Matti), Huotari, N. (Niko), Raitamaa, L. (Lauri), Kananen, J. (Janne), Korhonen, T. (Tommi), Tetri, S. (Sami), Kuittinen, O. (Outi), and Kiviniemi, V. (Vesa)

Abstract

Primary central nervous system lymphoma (PCNSL) is an aggressive brain disease where lymphocytes invade along perivascular spaces of arteries and veins. The invasion markedly changes (peri)vascular structures but its effect on physiological brain pulsations has not been previously studied. Using physiological magnetic resonance encephalography (MREGBOLD) scanning, this study aims to quantify the extent to which (peri)vascular PCNSL involvement alters the stability of physiological brain pulsations mediated by cerebral vasculature. Clinical implications and relevance were explored. In this study, 21 PCNSL patients (median 67y; 38% females) and 30 healthy age-matched controls (median 63y; 73% females) were scanned for MREGBOLD signal during 2018–2021. Motion effects were removed. Voxel-by-voxel Coefficient of Variation (CV) maps of MREGBOLD signal was calculated to examine the stability of physiological brain pulsations. Group-level differences in CV were examined using nonparametric covariate-adjusted tests. Subject-level CV alterations were examined against control population Z-score maps wherein clusters of increased CV values were detected. Spatial distributions of clusters and findings from routine clinical neuroimaging were compared [contrast-enhanced, diffusion-weighted, fluid-attenuated inversion recovery (FLAIR) data]. Whole-brain mean CV was linked to short-term mortality with 100% sensitivity and 100% specificity, as all deceased patients revealed higher values (n = 5, median 0.055) than surviving patients (n = 16, median 0.028) (p < .0001). After adjusting for medication, head motion, and age, patients revealed higher CV values (group median 0.035) than healthy controls (group median 0.024) around arterial territories (p ≤ .001). Abnormal clusters (median 1.10 × 10₅mm₃) extended spatially beyond FLAIR lesions (median 0.62 × 10₅mm₃) with differences in volumes (p = .0055).

Published

2022

4. Cardiovascular pulsatility increases in visual cortex before blood oxygen level dependent response during stimulus

Author

Huotari, N. (Niko), Tuunanen, J. (Johanna), Raitamaa, L. (Lauri), Raatikainen, V. (Ville), Kananen, J. (Janne), Helakari, H. (Heta), Tuovinen, T. (Timo), Järvelä, M. (Matti), Kiviniemi, V. (Vesa), Korhonen, V. (Vesa), Huotari, N. (Niko), Tuunanen, J. (Johanna), Raitamaa, L. (Lauri), Raatikainen, V. (Ville), Kananen, J. (Janne), Helakari, H. (Heta), Tuovinen, T. (Timo), Järvelä, M. (Matti), Kiviniemi, V. (Vesa), and Korhonen, V. (Vesa)

Abstract

The physiological pulsations that drive tissue fluid homeostasis are not well characterized during brain activation. Therefore, we used fast magnetic resonance encephalography (MREG) fMRI to measure full band (0–5 Hz) blood oxygen level-dependent (BOLDFB) signals during a dynamic visual task in 23 subjects. This revealed brain activity in the very low frequency (BOLDVLF) as well as in cardiac and respiratory bands. The cardiovascular hemodynamic envelope (CHe) signal correlated significantly with the visual BOLDVLF response, considered as an independent signal source in the V1-V2 visual cortices. The CHe preceded the canonical BOLDVLF response by an average of 1.3 (± 2.2) s. Physiologically, the observed CHe signal could mark increased regional cardiovascular pulsatility following vasodilation.

Published

2022

5. Spectral analysis of physiological brain pulsations affecting the BOLD signal

Author

Raitamaa, L. (Lauri), Huotari, N. (Niko), Korhonen, V. (Vesa), Helakari, H. (Heta), Koivula, A. (Anssi), Kananen, J. (Janne), and Kiviniemi, V. (Vesa)

Subjects

Quantitative Biology::Neurons and Cognition, fast fMRI, global signal, Astrophysics::High Energy Astrophysical Phenomena, Quantitative Biology::Tissues and Organs, Physics::Medical Physics, amplitude of low-frequency fluctuation, physiological brain pulsations, Astrophysics::Solar and Stellar Astrophysics, resting state, cardiorespiratory modulation

Abstract

Physiological pulsations have been shown to affect the global blood oxygen level dependent (BOLD) signal in human brain. While these pulsations have previously been regarded as noise, recent studies show their potential as biomarkers of brain pathology. We used the extended 5 Hz spectral range of magnetic resonance encephalography (MREG) data to investigate spatial and frequency distributions of physiological BOLD signal sources. Amplitude spectra of the global image signals revealed cardiorespiratory envelope modulation (CREM) peaks, in addition to the previously known very low frequency (VLF) and cardiorespiratory pulsations. We then proceeded to extend the amplitude of low frequency fluctuations (ALFF) method to each of these pulsations. The respiratory pulsations were spatially dominating over most brain structures. The VLF pulsations overcame the respiratory pulsations in frontal and parietal gray matter, whereas cardiac and CREM pulsations had this effect in central cerebrospinal fluid (CSF) spaces and major blood vessels. A quasi-periodic pattern (QPP) analysis showed that the CREM pulsations propagated as waves, with a spatiotemporal pattern differing from that of respiratory pulsations, indicating them to be distinct intracranial physiological phenomenon. In conclusion, the respiration has a dominant effect on the global BOLD signal and directly modulates cardiovascular brain pulsations.

Published

2021

6. Respiratory-related brain pulsations are increased in epilepsy:a two-centre functional MRI study

Author

Kananen, J. (Janne), Helakari, H. (Heta), Korhonen, V. (Vesa), Huotari, N. (Niko), Järvela, M. (Matti), Raitamaa, L. (Lauri), Raatikainen, V. (Ville), Rajna, Z. (Zalan), Tuovinen, T. (Timo), Nedergaard, M. (Maiken), Jacobs, J. (Julia), LeVan, P. (Pierre), Ansakorpi, H. (Hanna), and Kiviniemi, V. (Vesa)

Subjects

fast fMRI, epilepsy, brain physiology, respiration, brain pulsations

Abstract

Resting-state functional MRI has shown potential for detecting changes in cerebral blood oxygen level-dependent signal in patients with epilepsy, even in the absence of epileptiform activity. Furthermore, it has been suggested that coefficient of variation mapping of fast functional MRI signal may provide a powerful tool for the identification of intrinsic brain pulsations in neurological diseases such as dementia, stroke and epilepsy. In this study, we used fast functional MRI sequence (magnetic resonance encephalography) to acquire ten whole-brain images per second. We used the functional MRI data to compare physiological brain pulsations between healthy controls (n = 102) and patients with epilepsy (n = 33) and furthermore to drug-naive seizure patients (n = 9). Analyses were performed by calculating coefficient of variation and spectral power in full band and filtered sub-bands. Brain pulsations in the respiratory-related frequency sub-band (0.11–0.51 Hz) were significantly (P

Published

2020

7. Dynamic lag analysis reveals atypical brain information flow in autism spectrum disorder

Author

Raatikainen, V. (Ville), Korhonen, V. (Vesa), Borchardt, V. (Viola), Huotari, N. (Niko), Helakari, H. (Heta), Kananen, J. (Janne), Raitamaa, L. (Lauri), Joskitt, L. (Leena), Loukusa, S. (Soile), Hurtig, T. (Tuula), Ebeling, H. (Hanna), Uddin, L. Q. (Lucina Q.), and Kiviniemi, V. (Vesa)

Subjects

lag pattern, MREG, resting state fMRI, dynamic lag analysis, ASD, human brain

Abstract

This study investigated whole‐brain dynamic lag pattern variations between neurotypical (NT) individuals and individuals with autism spectrum disorder (ASD) by applying a novel technique called dynamic lag analysis (DLA). The use of 3D magnetic resonance encephalography data with repetition time = 100 msec enables highly accurate analysis of the spread of activity between brain networks. Sixteen resting‐state networks (RSNs) with the highest spatial correlation between NT individuals (n = 20) and individuals with ASD (n = 20) were analyzed. The dynamic lag pattern variation between each RSN pair was investigated using DLA, which measures time lag variation between each RSN pair combination and statistically defines how these lag patterns are altered between ASD and NT groups. DLA analyses indicated that 10.8% of the 120 RSN pairs had statistically significant (P‐value

Published

2020

8. The variability of functional MRI brain signal increases in Alzheimer’s disease at cardiorespiratory frequencies

Author

Tuovinen, T. (Timo), Kananen, J. (Janne), Rajna, Z. (Zalan), Lieslehto, J. (Johannes), Korhonen, V. (Vesa), Rytty, R. (Riikka), Mattila, H. (Heli), Huotari, N. (Niko), Raitamaa, L. (Lauri), Helakari, H. (Heta), Elseoud, A. A. (Ahmed Abou), Krüger, J. (Johanna), LeVan, P. (Pierre), Tervonen, O. (Osmo), Hennig, J. (Juergen), Remes, A. M. (Anne M.), Nedergaard, M. (Maiken), Kiviniemi, V. (Vesa), Tuovinen, T. (Timo), Kananen, J. (Janne), Rajna, Z. (Zalan), Lieslehto, J. (Johannes), Korhonen, V. (Vesa), Rytty, R. (Riikka), Mattila, H. (Heli), Huotari, N. (Niko), Raitamaa, L. (Lauri), Helakari, H. (Heta), Elseoud, A. A. (Ahmed Abou), Krüger, J. (Johanna), LeVan, P. (Pierre), Tervonen, O. (Osmo), Hennig, J. (Juergen), Remes, A. M. (Anne M.), Nedergaard, M. (Maiken), and Kiviniemi, V. (Vesa)

Abstract

Biomarkers sensitive to prodromal or early pathophysiological changes in Alzheimer’s disease (AD) symptoms could improve disease detection and enable timely interventions. Changes in brain hemodynamics may be associated with the main clinical AD symptoms. To test this possibility, we measured the variability of blood oxygen level-dependent (BOLD) signal in individuals from three independent datasets (totaling 80 AD patients and 90 controls). We detected a replicable increase in brain BOLD signal variability in the AD populations, which constituted a robust biomarker for clearly differentiating AD cases from controls. Fast BOLD scans showed that the elevated BOLD signal variability in AD arises mainly from cardiovascular brain pulsations. Manifesting in abnormal cerebral perfusion and cerebrospinal fluid convection, present observation presents a mechanism explaining earlier observations of impaired glymphatic clearance associated with AD in humans.

Published

2020

9. Breath hold effect on cardiovascular brain pulsations:a multimodal magnetic resonance encephalography study

Author

Raitamaa, L. (Lauri), Korhonen, V. (Vesa), Huotari, N. (Niko), Raatikainen, V. (Ville), Hautaniemi, T. (Taneli), Kananen, J. (Janne), Rasila, A. (Aleksi), Helakari, H. (Heta), Zienkiewicz, A. (Aleksandra), Myllylä, T. (Teemu), Borchardt, V. (Viola), and Kiviniemi, V. (Vesa)

Subjects

cardiovascular pulsations, magnetic resonance encephalography, Breath hold, respiratory centers, cerebrovascular reactivity

Abstract

Ultra-fast functional magnetic resonance encephalography (MREG) enables separate assessment of cardiovascular, respiratory, and vasomotor waves from brain pulsations without temporal aliasing. We examined effects of breath hold- (BH) related changes on cardiovascular brain pulsations using MREG to study the physiological nature of cerebrovascular reactivity. We used alternating 32 s BH and 88 s resting normoventilation (NV) to change brain pulsations during MREG combined with simultaneously measured respiration, continuous non-invasive blood pressure, and cortical near-infrared spectroscopy (NIRS) in healthy volunteers. Changes in classical resting-state network BOLD-like signal and cortical blood oxygenation were reproduced based on MREG and NIRS signals. Cardiovascular pulsation amplitudes of MREG signal from anterior cerebral artery, oxygenated hemoglobin concentration in frontal cortex, and blood pressure decreased after BH. MREG cardiovascular pulse amplitudes in cortical areas and sagittal sinus increased, while cerebrospinal fluid and white matter remained unchanged. Respiratory centers in the brainstem — hypothalamus — thalamus — amygdala network showed strongest increases in cardiovascular pulsation amplitude. The spatial propagation of averaged cardiovascular impulses altered as a function of successive BH runs. The spread of cardiovascular pulse cycles exhibited a decreasing spatial similarity over time. MREG portrayed spatiotemporally accurate respiratory network activity and cardiovascular pulsation dynamics related to BH challenges at an unpreceded high temporal resolution.

Published

2019

10. Sampling rate effects on resting state fMRI metrics

Author

Huotari, N. (Niko), Raitamaa, L. (Lauri), Helakari, H. (Heta), Kananen, J. (Janne), Raatikainen, V. (Ville), Rasila, A. (Aleksi), Tuovinen, T. (Timo), Kantola, J. (Jussi), Borchardt, V. (Viola), Kiviniemi, V. J. (Vesa J.), Korhonen, V. O. (Vesa O.), Huotari, N. (Niko), Raitamaa, L. (Lauri), Helakari, H. (Heta), Kananen, J. (Janne), Raatikainen, V. (Ville), Rasila, A. (Aleksi), Tuovinen, T. (Timo), Kantola, J. (Jussi), Borchardt, V. (Viola), Kiviniemi, V. J. (Vesa J.), and Korhonen, V. O. (Vesa O.)

Abstract

Low image sampling rates used in resting state functional magnetic resonance imaging (rs-fMRI) may cause aliasing of the cardiorespiratory pulsations over the very low frequency (VLF) BOLD signal fluctuations which reflects to functional connectivity (FC). In this study, we examine the effect of sampling rate on currently used rs-fMRI FC metrics. Ultra-fast fMRI magnetic resonance encephalography (MREG) data, sampled with TR 0.1 s, was downsampled to different subsampled repetition times (sTR, range 0.3–3 s) for comparisons. Echo planar k-space sampling (TR 2.15 s) and interleaved slice collection schemes were also compared against the 3D single shot trajectory at 2.2 s sTR. The quantified connectivity metrics included stationary spatial, time, and frequency domains, as well as dynamic analyses. Time domain methods included analyses of seed-based functional connectivity, regional homogeneity (ReHo), coefficient of variation, and spatial domain group level probabilistic independent component analysis (ICA). In frequency domain analyses, we examined fractional and amplitude of low frequency fluctuations. Aliasing effects were spatially and spectrally analyzed by comparing VLF (0.01–0.1 Hz), respiratory (0.12–0.35 Hz) and cardiac power (0.9–1.3 Hz) FFT maps at different sTRs. Quasi-periodic pattern (QPP) of VLF events were analyzed for effects on dynamic FC methods. The results in conventional time and spatial domain analyses remained virtually unchanged by the different sampling rates. In frequency domain, the aliasing occurred mainly in higher sTR (1–2 s) where cardiac power aliases over respiratory power. The VLF power maps suffered minimally from increasing sTRs. Interleaved data reconstruction induced lower ReHo compared to 3D sampling (p < 0.001). Gradient recalled echo-planar imaging (EPI BOLD) data produced both better and worse metrics. In QPP analyses, the repeatability of the VLF pulse detection becomes linearly reduced with increasing sTR. In co

Published

2019

11. 3D multi-resolution optical flow analysis of cardiovascular pulse propagation in human brain

Author

Rajna, Z. (Zalán), Raitamaa, L. (Lauri), Tuovinen, T. (Timo), Heikkilä, J. (Janne), Kiviniemi, V. (Vesa), Seppänen, T. (Tapio), Rajna, Z. (Zalán), Raitamaa, L. (Lauri), Tuovinen, T. (Timo), Heikkilä, J. (Janne), Kiviniemi, V. (Vesa), and Seppänen, T. (Tapio)

Abstract

The brain is cleaned from waste by glymphatic clearance serving a similar purpose as the lymphatic system in the rest of the body. Impairment of the glymphatic brain clearance precedes protein accumulation and reduced cognitive function in Alzheimer’s disease (AD). Cardiovascular pulsations are a primary driving force of the glymphatic brain clearance. We developed a method to quantify cardiovascular pulse propagation in the human brain with magnetic resonance encephalography (MREG). We extended a standard optical flow estimation method to three spatial dimensions, with a multi-resolution processing scheme. We added application-specific criteria for discarding inaccurate results. With the proposed method, it is now possible to estimate the propagation of cardiovascular pulse wavefronts from the whole brain MREG data sampled at 10 Hz. The results show that on average the cardiovascular pulse propagates from major arteries via cerebral spinal fluid spaces into all tissue compartments in the brain. We present an example, that cardiovascular pulsations are significantly altered in AD: coefficient of variation and sample entropy of the pulse propagation speed in the lateral ventricles change in AD. These changes are in line with the theory of glymphatic clearance impairment in AD. The proposed non-invasive method can assess a performance indicator related to the glymphatic clearance in the human brain.

Published

2019

12. Altered physiological brain variation in drug‐resistant epilepsy

Author

Kananen, J. (Janne), Tuovinen, T. (Timo), Ansakorpi, H. (Hanna), Rytky, S. (Seppo), Helakari, H. (Heta), Huotari, N. (Niko), Raitamaa, L. (Lauri), Raatikainen, V. (Ville), Rasila, A. (Aleksi), Borchardt, V. (Viola), Korhonen, V. (Vesa), LeVan, P. (Pierre), Nedergaard, M. (Maiken), and Kiviniemi, V. (Vesa)

Subjects

coefficient of variation, MREG, fMRI, epilepsy, multimodal imaging, brain physiology

Abstract

Introduction: Functional magnetic resonance imaging (fMRI) combined with simultaneous electroencephalography (EEG‐fMRI) has become a major tool in mapping epilepsy sources. In the absence of detectable epileptiform activity, the resting state fMRI may still detect changes in the blood oxygen level‐dependent signal, suggesting intrinsic alterations in the underlying brain physiology. Methods: In this study, we used coefficient of variation (CV) of critically sampled 10 Hz ultra‐fast fMRI (magnetoencephalography, MREG) signal to compare physiological variance between healthy controls (n = 10) and patients (n = 10) with drug‐resistant epilepsy (DRE). Results: We showed highly significant voxel‐level (p < 0.01, TFCE‐corrected) increase in the physiological variance in DRE patients. At individual level, the elevations range over three standard deviations (σ) above the control mean (μ) CVMREG values solely in DRE patients, enabling patient‐specific mapping of elevated physiological variance. The most apparent differences in group‐level analysis are found on white matter, brainstem, and cerebellum. Respiratory (0.12–0.4 Hz) and very‐low‐frequency (VLF = 0.009–0.1 Hz) signal variances were most affected. Conclusions: The CVMREG increase was not explained by head motion or physiological cardiorespiratory activity, that is, it seems to be linked to intrinsic physiological pulsations. We suggest that intrinsic brain pulsations play a role in DRE and that critically sampled fMRI may provide a powerful tool for their identification.

Published

2018

13. Continuous blood pressure recordings simultaneously with functional brain imaging:studies of the glymphatic system

Author

Zienkiewicz, A. (Aleksandra), Huotari, N. (Niko), Raitamaa, L. (Lauri), Raatikainen, V. (Ville), Ferdinando, H. (Hany), Vihriälä, E. (Erkki), Korhonen, V. (Vesa), Myllylä, T. (Teemu), and Kiviniemi, V. (Vesa)

Abstract

The lymph system is responsible for cleaning the tissues of metabolic waste products, soluble proteins and other harmful fluids etc. Lymph flow in the body is driven by body movements and muscle contractions. Moreover, it is indirectly dependent on the cardiovascular system, where the heart beat and blood pressure maintain force of pressure in lymphatic channels. Over the last few years, studies revealed that the brain contains the so-called glymphatic system, which is the counterpart of the systemic lymphatic system in the brain. Similarly, the flow in the glymphatic system is assumed to be mostly driven by physiological pulsations such as cardiovascular pulses. Thus, continuous measurement of blood pressure and heart function simultaneously with functional brain imaging is of great interest, particularly in studies of the glymphatic system. We present our MRI compatible optics based sensing system for continuous blood pressure measurement and show our current results on the effects of blood pressure variations on cerebral brain dynamics, with a focus on the glymphatic system. Blood pressure was measured simultaneously with near-infrared spectroscopy (NIRS) combined with an ultrafast functional brain imaging (fMRI) sequence magnetic resonance encephalography (MREG, 3D brain 10 Hz sampling rate).

Published

2017

14. Combined spatiotemporal ICA (stICA) for continuous and dynamic lag structure analysis of MREG data

Author

Raatikainen, V. (Ville), Huotari, N. (Niko), Korhonen, V. (Vesa), Rasila, A. (Aleksi), Kananen, J. (Janne), Raitamaa, L. (Lauri), Keinänen, T. (Tuija), Kantola, J. (Jussi), Tervonen, O. (Osmo), Kiviniemi, V. (Vesa), Raatikainen, V. (Ville), Huotari, N. (Niko), Korhonen, V. (Vesa), Rasila, A. (Aleksi), Kananen, J. (Janne), Raitamaa, L. (Lauri), Keinänen, T. (Tuija), Kantola, J. (Jussi), Tervonen, O. (Osmo), and Kiviniemi, V. (Vesa)

Abstract

This study investigated lag structure in the resting-state fMRI by applying a novel independent component (ICA) method to magnetic resonance encephalography (MREG) data. Briefly, the spatial ICA (sICA) was used for defining the frontal and back nodes of the default mode network (DMN), and the temporal ICA (tICA), which is enabled by the high temporal resolution of MREG (TR=100ms), was used to separate both neuronal and physiological components of these two spatial map regions. Subsequently, lag structure was investigated between the frontal (DMNvmpf) and posterior (DMNpcc) DMN nodes using both conventional method with all-time points and a sliding-window approach. A rigorous noise exclusion criterion was applied for tICs to remove physiological pulsations, motion and system artefacts. All the de-noised tICs were used to calculate the null-distributions both for expected lag variability over time and over subjects. Lag analysis was done for the three highest correlating denoised tICA pairs. Mean time lag of 0.6 s (± 0.5 std) and mean absolute correlation of 0.69 (± 0.08) between the highest correlating tICA pairs of DMN nodes was observed throughout the whole analyzed period. In dynamic 2 min window analysis, there was large variability over subjects as ranging between 1–10 sec. Directionality varied between these highly correlating sources an average 28.8% of the possible number of direction changes. The null models show highly consistent correlation and lag structure between DMN nodes both in continuous and dynamic analysis. The mean time lag of a null-model over time between all denoised DMN nodes was 0.0 s and, thus the probability of having either DMNpcc or DMNvmpf as a preceding component is near equal. All the lag values of highest correlating tICA pairs over subjects lie within the standard deviation range of a null-model in whole time window analysis, supporting the earlier findings that there is a consistent temporal lag structure across groups of

Published

2017