DOI DataCite: https://doi.org/10.5281/zenodo.439033
DOI CrossRef: http://doi.org/10.1038/jcbfm.2010.189
Functional white laser imaging to study brain oxygen uncoupling/re-coupling in songbirds
Stéphane Mottin1, Bruno Montcel2, Hugues Guillet de Chatellus3 and Stéphane Ramstein1
1CNRS; Université de Lyon; Université de St-Etienne, UMR5516, Saint-Etienne, France; 2 Université de Lyon; CREATIS-LRMN; CNRS UMR5220; INSERM U630; Université Lyon1; INSA Lyon, France; 3CNRS; Université de Grenoble; UMR5588, St Martin d’Hères, France.
Correspondence: B. Montcel bruno.montcel@univ-lyon1.fr;
S. Mottin: mottin@univ-st-etienne.fr
Mottin, S. identifier: http://orcid.org/0000-0002-7088-4353
These experiments were supported by the Program “Emergence” of the Région Rhône-Alpes and the Agence Nationale de la Recherche.
Reference BibTeX
@article{2011_mottin_33,
TITLE = {Functional white laser imaging to study brain oxygen uncoupling/re-coupling in songbirds},
AUTHOR = { Mottin, Stéphane and Montcel, Bruno and Guillet De Chatellus, Hugues and Ramstein, Stéphane },
JOURNAL = {Journal of Cerebral Blood Flow & Metabolism},
VOLUME = { 31},
NUMBER = {2},
PAGES = {393-400},
YEAR = {2011},
DOI = {10.1038/jcbfm.2010.189},
KEYWORDS = {brain activation;cerebral hemodynamics;near-infrared spectroscopy;neurovascular coupling;optical imaging;songbirds},
}
Abstract
Contrary to the intense debate about brain oxygen dynamics and its uncoupling in mammals, very little is known in birds. In zebra finches, picosecond optical tomography (POT) with a white laser and a streak camera can measure in vivo oxy-hemoglobin (HbO2) and deoxy-hemoglobin (Hb) concentration changes following physiological stimulation (familiar calls and songs). POT demonstrated sufficient sub-micromolar sensitivity to resolve the fast changes in hippocampus and auditory forebrain areas with 250 µm resolution. The time-course is composed of (i) an early 2s-long event with a significant decrease in Hb and HbO2, respectively -0.7 µMoles/L and -0.9 µMoles/L (ii) a subsequent increase in blood oxygen availability with a plateau of HbO2 (+0.3µMoles/L) and (iii) pronounced vasodilatation events immediately following the end of the stimulus. One of the findings of our work is the direct link between the blood oxygen level-dependent (BOLD) signals previously published in birds and our results. Furthermore, the early vasoconstriction event and post-stimulus ringing seem to be more pronounced in birds than in mammals. These results in bird, a tachymetabolic vertebrate with a long lifespan, can potentially yield new insights for example in brain aging.
Keywords
Brain activation; near-infrared spectroscopy; neurovascular coupling; optical imaging; oxygen metabolism; songbirds; cerebral hemodynamics.
Introduction
Unlike other organs, the brain of mammals and birds is a constant energy sink, consuming energy irrespective of whether it is at rest or active, but on the other side of the coin is its low tolerance to a long list of “perturbations” i.e. hypoglycemia, hypoxia, hypercapnia, hyperthermia and mitochondrial diseases (Siesjö, 1978; Mottin et al, 2003). The coupling between transport and metabolism allows the balance between the storage and the production of ATP, despite the very high rate of combustion of glucose with ~5.5 dioxygen molecules per glucose molecule (Siesjö, 1978; Sokoloff, 2001). This steady state is an oscillatory regime that is poorly understood and low frequencies have been observed in various cerebral parameters reversibly suppressed by hypercapnia (Steinmeier et al, 1996; Biswal et al, 1997; Fox and Raichle, 2007). When activation occurs, step responses are complex (Kasischke et al, 2004; Niven and Laughlin, 2008; Petzold et al, 2008; Vanzetta and Grinvald, 2008) and induce changes in blood flow and in oxygen transport (Ress et al, 2009). The coupling of perfusion and oxidative metabolism in the resting brain has been shown to be disrupted in the first minute after the onset of a sudden functional challenge (Kasischke et al, 2004; Niven and Laughlin, 2008; Petzold et al, 2008; Vanzetta and Grinvald, 2008). This uncoupling has also been a major problem for the interpretation of brain imaging (Vanzetta and Grinvald, 2008). To better understand the link between tachymetabolism and this uncoupling, we developed a method for measuring the full time-course of oxygen transport in the higher-order auditory region of the telencephalon in the zebra finch, Taeniopygia guttata. The need for an improved understanding of the mechanisms underlying brain activation, especially in songbirds, has become obvious (Voss et al, 2007; Boumans et al, 2007). Following the growing evidence of mammalian-like cognitive abilities in songbirds (Vignal et al, 2004), of the neocortex-like functions of the avian pallium (Jarvis et al, 2005; Reiner, 2005) and of some peculiarities of the avian metabolism (Barja and Herrero, 1998; Turner et al, 2005;Moe et al, 2009), birds have become an important focus of interest for comparative neuroscience (Vignal et al, 2004; Clayton, 2007).
The reliability of optical measurements of changes in the concentration of hemoglobin in tissues has been a challenge for years (Vanzetta and Grinvald, 2008; Calderon-Arnulphi et al, 2009). Because of its non-invasive nature, transcranial optical cerebral oximetry (near infrared spectroscopy, diffuse optical tomography, etc…) has become a source of quantitative or semi-quantitative information about brain oxygenation, cerebral blood flow and volume. However, continuing technical controversies about signal derivation, accuracy, precision, and quantitative ability have limited the application of transcranial optical cerebral oximetry. Clearly transcranial optical cerebral oximetry still needs developments. Recent ultrafast technological advancements have opened up a new promising avenue in neuroscience (Gibson et al, 2006; Vignal et al, 2008; Montcel et al, 2005; Montcel et al, 2006; Pifferi et al, 2008; Liebert et al, 2004; Selb et al, 2006).
As part of our broader effort to develop a non-invasive neuro-method and to improve quantitative measurement of absorbing chromophores into scattering brain tissues, we worked on a time-domain based device. Using a white light super-continuum or “white laser” (Chin et al, 1999), we combined POT with near-infrared spectroscopy (spectral-POT) (Vignal et al, 2008) and a new POT with contact free spatial imaging (spatial-POT). In the near-infrared spectral window 650 to 850 nm, the non-monotonic behavior of the absorption spectrum of Hb provides reliable “molecular fingerprints” (Vignal et al, 2008). Furthermore the optical signals are integrated into a selected picosecond time-of-flight window specifically defined so as to probe only the targeted deep brain structures (Vignal et al, 2008). This system allows us to monitor in vivo and quantify an evoked brain hemodynamic response with sub-micromolar sensitivity and sub-millimeter spatial resolution. The spatial-POT is different from the classic strategy of several discrete detectors (Gibson et al, 2006). This configuration is without contact between skin and detectors. The position of this imaged segment on the head of the bird can be controlled by eye by shining the intermediate slit with a He-Ne laser and checking and adjusting the position of its image on the skin. In the case of such small animal this imaging system allows the analysis of the resolution limits of POT.
Having developed a spectral-POT, we have previously been able to measure HbO2 and Hb changes following hypercapnia (Vignal et al, 2008). We now address the task of mapping the acoustic field with the best possible spatial resolution to show that POT is able to reproduce classic neuroscience results and to measure for the first time the full time-course of coupling/uncoupling in small songbirds.
Materials and Methods Animals and stimulation protocols
Adult male zebra finches (Taeniopygia guttata) served as subjects for the experiments. Bred in the aviary of the University of St-Etienne with a 12L/12D photoperiod, 4 birds and 5 birds were used respectively for spectral-POT and spatial-POT. Birds were anesthetized with 2% isoflurane under spontaneous breathing conditions (Vignal et al, 2008).
The animal preparation and the spectral-POT setup have been described previously (Vignal et al, 2008). Anaesthetized zebra finches with the head previously plucked (three days before experiments) were fixed in a stereotaxic frame (Stoelting Co., USA, adaptations for birds). The body temperature was kept within a narrow range (39-40°C) by a feedback controlled heating pad. The optical fibers were fixed into stereotaxic manipulators (Stoelting Co., USA) and placed directly on the skin. Positions of the input optical fiber F1 providing illumination and the optical fiber F2 collecting transmitted light were chosen in order to probe the auditory regions of the telencephalon (field L, the caudo-medial Nidopallium NCM and the caudo-medial Mesopallium CMM). The head of the bird is turned until the beak (rostral extremity) is perpendicular to the body plane. This position allowed us to define a stereotaxic origin point (0,0,0) defined by the intersection of the vertical plane passing through the interaural line and the sagittal suture (the vena cerebralis dorsocaudalis). The stereotaxic axes are chosen according to this origin point. F1 was placed more rostrally on the right hemisphere than F2. The distance between F1 and F2 was 5 mm (Figure 1). The chosen coordinates in millimeters were: F1 (2.0, 5.4, -2.7) and F2 (2.0, 0.4, -0.3).
The animals were kept in a custom-made sound-attenuated box (48x53x70 cm) equipped with 2 fixed high-fidelity speakers (triangle Comete 202). After a 1mn baseline period, each bird was subject to a 20s stimulus, followed by 1mn for recovery of baseline. The original auditory signal was a random sequence of songs and calls recorded in the zebra finch aviary, normalized to the same intensity. Among the 20s of stimulus recorded, 94% represented songs and calls, while 6% represented silence. For each animal, 15 stimuli were used, with 9 random white-noise stimuli. After experiments, all animals were kept in the recording room for 24 h for physiological and behavioral verifications. All experimental procedures were approved by the University’s animal care committee. Statistical methods have been previously described (Vignal et al, 2008) (multiple comparison procedure, one-way ANOVAs for repeated measures, Tukey-Kramer test, Statistics toolbox, Matlab, The Mathworks, Massachusetts). The variation of the time-resolved transmittance spectrum was also fitted to the spectra of HbO2 and Hb known in mammals by classic linear least-squares procedure. The same procedure was applied to calculate the variations in concentration of HbO2 and Hb. These concentration variations can be expressed using an absolute scale (μMol) because our time-resolved detection system can measure the mean optical path through the bird’s head thanks to the mean arrival time of photons (Vignal et al, 2008).
Experimental setup of the spatial-POT
We used the same setup and the same laser fiber position as previously described (Vignal et al, 2008), with the omission of the polychromator and with an imaging system between the head of the animal and the streak camera (Hamamatsu Streakscope C4334). The imaging setup based on two lenses (L4, L1) (100 mm focal length) conjugates optically the surface of the skull with the plane of the entrance slit of the streak camera (Figure 1). An afocal system made of two lenses (L2, L3) (100 mm focal) is placed between the two imaging lenses, and a slit (F) is put at the focal point of the afocal system. This slit is optically conjugated with the entrance slit of the streak camera resulting in a great simplification of the alignment procedure and in the possibility of controlling the intensity of the light by narrowing the slit as well. The magnification of the setup is 1. Intrinsic filtering properties of the imaging setup enable to collect only the photons emerging from a 5 mm-long segment located 5 mm apart from the fiber (Figure 1). We put a narrow bandwidth filter (IF) (10 nm FWHM) centered at 700 nm, where the difference of absorption between the two hemoglobin species is maximal. The position of the imaged segment on the head of the bird can be controlled by eye by shining the intermediate slit with a He-Ne laser and checking and adjusting the position of its image on the surface of the head (mirror M). The spatial resolution along the slit was determined by imaging a white sheet of paper half covered with black ink. The image consists in the response of the system to a Heaviside step and characterizes the spatial resolution of the setup. Its resolution along the slit is near of 250 µm.
The single shot streak camera measures the propagation time of the photons through tissues. All measurements are carefully corrected from the shading effects. Each measurement consists in a frame integrating 33 laser pulses due to the 33 ms CCD integration time of the streak camera. The 5 mm-long segment (and 150 µm thickness) was imaged onto the slit of the streak camera and at the end, transformed to 640 pixels. The 2.1 ns deflection time was converted to 480 pixels. The temporal resolution of the system was set by the temporal width of the trace on the CCD camera of a femtosecond pulse. The instrument response function was obtained by sending directly a leaking of a femtosecond laser pulse. Due to the jitter (with 33 laser pulses), the resolution was 25 ps (6 pixels).
An advantage of this setup comes from the possibility of contact-free measurements. The versatility of the optical design we implemented has another interesting advantage in terms of imaging. In a near future, by simply tilting the M mirror we will sweep the imaging segment. This possibility is way more flexible than fiber bundles and leads to a narrower spatial resolution, not limited by the diameter of the optical fibers, but only by the numerical aperture and the properties of the optical setup.
Results
Figure 2 shows the full time-courses of picosecond time-resolved transmittance measured by spectral-POT (Figure 2a) and by spatial-POT (Figure 2b). The shape of the time-courses and the level of variation of transmittance were equivalent for spatial-POT and spectral-POT. The maximum change in transmittance induced by the auditory stimulus was 1.03. To establish a calibrated functional technique, the acoustic response experiments were carried out under the same conditions as the 7% normoxic hypercapnic experiments (Vignal et al, 2008). The functional signal under these conditions was found to be equivalent to 10% of the hypercapnic changes (Vignal et al, 2008). Our results showed that these physiologic changes needed a less 2s time resolution (Figures 2 and 3). Significant Hb and HbO2 changes were obtained by linear un-mixing (Vignal et al, 2008) and were analyzed with a 0.667 s time resolution. During the 2-seconds following the onset of acoustic stimuli, Hb and HbO2 levels significantly decreased to -0.7 µMoles/L and -0.9 µMoles/L respectively (Figure 3). The HbO2 level then increased significantly (during 12.4s, 100 concentration measurements) to reach a plateau of 0.3 µMoles/L (p=0.015 when compared to the 100 concentrations preceding the stimulus). Immediately after the end of the stimulus, Hb and HbO2 pulses reached +0.7 µMoles/L.
Changes were significantly localized (Figures 2b and 4a) above the auditory forebrain areas (NCM, Field L, CMM). A small contribution could have derived from the hippocampus (dorsal and posterior areas) (Vignal et al, 2008). Furthermore there was a significant bilateral increase in transmittance (Figure 4a) when compared to more lateral positions [2.75 and 3 mm]. During the post-stimulus period (Figure 4b) all areas showed significant decreases in transmittance when compared to the rest period. These results show that re-coupling was less localized than uncoupling. Compared to more lateral positions and within the stimulation period, a significant bilateral increase was observed. In contrast, a significant bilateral decrease was observed within the post-stimulus period. Furthermore the number of Hb and HbO2 pulses was less high for the auditory-hippocampal areas [0.25 to 1.25mm and -0.25 to -1.25mm] than for more lateral positions, showing that re-coupling was faster in these areas (Figures 2b and 5).
Discussion
Our study demonstrates for the first time the changes of blood oxygen in a small songbird during stimulation in vivo. The most intense responses to similar stimuli have been observed in NCM and Field L, using other methods (Clayton, 2007; Voss et al, 2007; Poirier et al, 2009). In addition to bilateral responses in these areas, lateralized activation has been suggested to take place (Voss et al, 2007; Poirier et al, 2009). With our less specific stimulation paradigm, we obtained a bilateral response without lateralization (Figures 2b and 4). Unlike electrophysiology and immediate early gene expression, fMRI and POT measure blood dynamics in relation to the activity of large clusters of cells. In birds, the links between BOLD, hemodynamics and neuronal activation was not previously known (Boumans et al, 2007; Voss et al, 2007; Vignal et al, 2008). By choosing anesthetic conditions, sequences of stimuli and spatiotemporal parameters similar to other published BOLD experiments (Table 1), we sought to establish a robust correlation between the BOLD signal and changes in Hb and HbO2 concentrations.
The diffuse optical method has the potential to differentiate hemoglobin dynamics; however, they have a limited spatial resolution. On the other hand, BOLD fMRI has achieved high spatial resolution but is more susceptible to limited ability to monitor the hemoglobin dynamics. BOLD time-courses exhibits a sharp rise and an overshoot at the beginning of the stimulus and an undershoot during the post-stimulus period. The BOLD undershoot reveals two oscillations that have not been discussed previously, and these post-stimulus BOLD pulses are more pronounced in Field L than in NCM (Voss et al, 2007; Boumans et al, 2007). As known in mammals, we showed (Figure 6) that in birds there was a direct link between the BOLD signal and minus Hb (-Hb). However, -Hb exhibited a faster response to changes in stimulus (Figure 6) suggesting that the BOLD signal is a more “convoluted response” to hemodynamic than -Hb.
Birds and mammals have well-pronounced pial arterial ramifications (Mc Hedlishvili and Kuridze, 1984). Birds have (i) bigger red blood cells (RBC) by a factor of 3, and a far larger capillary diameter, (ii) less RBC per volume of blood by a factor of 1/3 and, (iii) a hemoglobin concentration in RBC comparable to that of small rodents (Altman and Dittmer, 1971). The pial angioarchitecture and hematological features of tachymetabolic vertebrates appear to have converged to an equivalent oxygen supply. In mammals, the coupling of blood transport and cerebral metabolic rates in physiologically active brain states has been the subject of debate, and different theoretical models for it have been proposed (Banaji et al, 2008; Ress et al, 2009). In humans, contrary to the “canonical hemodynamic response function” (used by software packages i.e. SPM), BOLD responses reveal several disparities (Aguirre et al,1998). and some authors (Vanzetta and Grinvald, 2008; Ress et al, 2009) suggest that the differences between BOLD responses are related to differences in the properties of blood vessel networks between mammals. Despite these differences, the BOLD overshoot is always observed in the sensory systems of tachymetabolic vertebrates. Nevertheless, in the zebra finch, transient events seem to be more pronounced than in comparable small rodents, perhaps due to differences in blood vessels networks.
The biphasic changes in HbO2 (early decrease and increase) measured by POT reveal a temporal pattern similar to the biphasic response of tissue oxygen (decrease and increase) in the auditory cortex (Masamoto et al, 2003) and to the biphasic response (initial constriction followed by dilation) of isolated penetrating cerebral arterioles following an elevation of K+ or ATP (Dietrich et al, 2009). For the post-stimulus period, re-coupling seems to be more complex than expected because (i) the HbO2 and Hb pulses were less localized than during activation (Figure 2b), (ii) the re-coupling of the activated auditory regions was faster than for other regions (Figure 5), and (iii) the early HbO2 pulse arrived before the Hb pulse (Figure 3). Therefore BOLD and POT re-coupling pulses in birds seem to be more spatiotemporally structured than nonlinear “passive elastic sloshing”, as expected (Ress et al, 2009).
We imaged the sinus sagittalis superior (position 0 mm in Figure 2b) and no significant changes were observed during the activation period. However this result should be considered carefully because distinguishing arterial, capillary and venous compartments is not straightforward in optical neuro-imaging (Hillman et al, 2007).
Systems with a low ratio of energy storage to energy consumption, end-products and heat generation have to respond “instantaneously” to activation. The understanding of the time-course of uncoupling/re-coupling and spontaneous oscillations (Steinmeier et al, 1996; Biswal et al, 1997; Fox and Raichle, 2007; Ress et al, 2009) emphasize the role of non-isochoric processes in this response. Despite the constraints of an instantaneous response, the sensory systems of all tachymetabolic animals seem to be robust when faced with the ordinary perturbations they were designed to handle, but fragile when faced with unexpected or strong perturbations (Niven and Laughlin, 2008. Our approach demonstrates the occurrence of strong reactivity in the cerebral vessels of the bird, an animal with a long lifespan (Barja and Herrero, 1998; Moe et al, 2009). Several studies (Mitschelen et al, 2009) indicate that age-related changes in vascular reactivity are important contributing factors to mild cognitive impairment in aging mammals. Contrary to accepted dogma, the role of oxidative stress as a determinant of longevity is still open to question (Mitschelen et al, 2009; Moe et al, 2009). Our results could thus shed light on this crucial question i.e. the link between brain aging and vascular reactivity.
Disclosure/Conflict of interest
The authors don’t have any conflict of interest to declare.
Acknowledgements
We thank Clementine Vignal and Nicolas Mathevon for their technical participation and bioacoustic data. We thank Colette Bouchut, Sabine Palle and Pierre Laporte for their help.
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Figure 1
Figure 1. The imaging set-up based on two lenses (L4, L1) conjugates the surface of the skull with the plane of the slit of the streak camera. An afocal system made of two lenses (L2, L3) is placed between the two imaging lenses. The slit (F) is placed at the focal point of the afocal system. The position of the 5 mm-long segment on the head of the bird can be controlled by eye, by shining a He-Ne laser through the intermediate slit and adjusting the position of its image on the skull (with mirror M). A narrow bandwidth filter (IF) is placed just before the streak camera. The 5 mm-long segment is located 5 mm away from the white-laser input optical fibre (F1).
Figure 2
Figure 2. The full time-course of the picosecond time-resolved transmittance spectra was measured by spectral-POT (a). The near-infrared spectral window is 668-844.4nm, with 20 spectral windows of 8.83 nm. The time-course of the picosecond time-resolved transmittance for 20 spatial regions of 0.25 mm was imaged by spatial-POT (b). The 695-705 nm spectral window was used for spatial-POT. Each point of measurement corresponds to 33ms. For illustration purposes, these results were filtered to get rid of high frequency noise, using a Chebyshev window only along the time axis, 1s for spectral-POT and 2s for spatial-POT respectively. The 0 mm position corresponds to the sagittal midline.
Figure 3
Figure 3. Hb (a) and HbO2 (b) concentration changes obtained by linear unmixing of the picosecond time-resolved transmittance spectra. Each point is an average of five concentrations, allowing a time resolution of 0.667s. Bars corresponds to p=0.05 for multiple comparisons (one-way ANOVAs for repeated measures) between periods. The limits of significance of Hb and HbO2 are 0.42 µMoles/L and 0.75 µMoles/L respectively. The asterisk indicates significant difference (p<0.05) from the detection limit.
Figure 4
Figure 4. Spatial-POT averaged 20s-long transmittance changes for the stimulus (20-40 s) period (a) and for the post-stimulus (40-60 s) period (b). The transmittance of the rest period (on 0-20 s) is normalized to 1 in all regions. Bars corresponds to p=0.01 for multiple comparisons (one-way ANOVAs for repeated measures) between the rest period and the two respective periods. Points without the ns (non-significant) symbol indicate areas with significant changes when compared to the rest period (p<0.01). The symbols for stimulus period and for the post-stimulus period are, respectively, § and # (p<0.01) for the left hemisphere and right hemisphere, compared with more lateral positions [2.75 to 3 mm]. The position 0 mm corresponds to the sagittal midline and positions [0.25 to 1.25mm and -0.25 to -1.25mm] to the auditory-hippocampal areas.
Figure 5
Figure 5. Time-course of transmittance measured by spatial-POT at four positions (a: left hemisphere, position -1.25 mm; b: sagittal midline, position 0 mm; c: right hemisphere, position +1.25mm; d: right hemisphere position +1.75mm). Each bar (p=0.01) allows multiple comparisons (one-way ANOVAs for repeated measures) between the pre-stimulus period and the two others periods (the symbol * indicates p<0.01).
Figure 6
Figure 6. Typical time-course of BOLD signal (dashed line) in zebra finches is compared with the time-course of HbO2 (curve with the symbol “o”) and Hb concentration changes measured by POT in caudal-medial areas. Minus Hb (-Hb) concentration is shown for better comparison with the BOLD signal.
Table 1
Table 1: Comparisons between BOLD spatiotemporal parameters and POT parameters.
Footnotes: BOLD spatiotemporal parameters in male zebra finches (Voss et al, 2007; Boumans et al, 2007) and male starlings (Van Meir et al, 2005). For POT parameters (∆Tr transmittance changes; ∆C concentration changes of hemoglobin) the thickness of the "diffuse slice" is measured at the surface of the scalp.
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Male zebra finch1
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Male zebra
finch2
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Male starling3
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Male zebra finch (POT)
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Time resolution
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4 s
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between 3 s
and 6 s
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5 s
|
0.033 s for ∆Tr
0.666 s for ∆C
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Time stimulus paradigm
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32sON-32sOFF
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40sON-40sOFF
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30sON-30sOFF & 60sON-60sOFF
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20sON-60sOFF
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thickness of slice
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1 mm
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0.5 mm
|
0.7-0.8 mm
|
0.25 mm
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Number of slices
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8 sagittal slices
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1 tilted coronal slice
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2 sagittal slices
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20 sagittal slices
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Table 1bis: Comparisons between BOLD spatiotemporal parameters in male zebra finches1,2 and male starlings3 and our POT parameters (∆Tr transmittance changes; ∆C concentration changes of haemoglobins). For POT, the thickness of the "diffuse slice" is measured at the surface of the scalp.
1. Voss, H. U. et al. Functional MRI of the zebra finch brain during song stimulation suggests a lateralized response topography. Proceedings of the National Academy of Sciences of the United States of America 104, 10667-10672 (2007).
2. Boumans, T., Theunissen, F. E., Poirier, C. & Van Der Linden, A. Neural representation of spectral and temporal features of song in the auditory forebrain. Eur J Neurosci 26, 2613-2626 (2007)
3. Van Meir, V. et al. Spatiotemporal properties of the BOLD response in the songbirds' auditory circuit during a variety of listening tasks. Neuroimage 25, 1242-1255 (2005).
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