The neural basis of the blood-oxygen-level-dependent functional magnetic resonance imaging signal

Magnetic resonance imaging (MRI) has rapidly become an important tool in clinical medicine and biological research. Its functional variant (functional magnetic resonance imaging; fMRI) is currently the most widely used method for brain mapping and studying the neural basis of human cognition. While the method is widespread, there is insufficient knowledge of the physiological basis of the fMRI signal to interpret the data confidently with respect to neural activity. This paper reviews the basic principles of MRI and fMRI, and subsequently discusses in some detail the relationship between the blood-oxygen-level-dependent (BOLD) fMRI signal and the neural activity elicited during sensory stimulation. To examine this relationship, we conducted the first simultaneous intracortical recordings of neural signals and BOLD responses. Depending on the temporal characteristics of the stimulus, a moderate to strong correlation was found between the neural activity measured with microelectrodes and the BOLD signal averaged over a small area around the microelectrode tips. However, the BOLD signal had significantly higher variability than the neural activity, indicating that human fMRI combined with traditional statistical methods underestimates the reliability of the neuronal activity. To understand the relative contribution of several types of neuronal signals to the haemodynamic response, we compared local field potentials (LFPs), single- and multi-unit activity (MUA) with high spatio-temporal fMRI responses recorded simultaneously in monkey visual cortex. At recording sites characterized by transient responses, only the LFP signal was significantly correlated with the haemodynamic response. Furthermore, the LFPs had the largest magnitude signal and linear systems analysis showed that the LFPs were better than the MUAs at predicting the fMRI responses. These findings, together with an analysis of the neural signals, indicate that the BOLD signal primarily measures the input and processing of neuronal information within a region and not the output signal transmitted to other brain regions.     

激动中枢组胺能受体对应激大鼠颈动脉窦压力感受性反射重调定的影响

应激1周的大鼠,麻醉后弧离双侧颈动脉窦区,将不同窦内压（ISP）与其对应的平均动脉压（MAP）值进行Logistic5个参数曲线拟合。根据所得ISP－MAP关系曲线及其特征参数,分别观察侧脑室(i.c.v.）注射和弧束核（NTS）内注射组胺受体拮抗剂对颈动脉窦压力感受性反射（CSR）的影响,并与相应的非应激CSR水平进行比较。结果如下：（1）应激导致ISP－MAP关系曲线显著全面上移,窦内压和增益（ISP-Gain）关系曲线中部明显下移,反射参数中阈压（TP）、饱和压（SP）、调定点（set point）和最大增益时的窦内压（ISPGmax）值增大,MAP反射变动范围（MAPrange）及反射最大增益（Gmax）减小;（2）I.c.v.H1或H2受体拮抗剂氯苯吡胺（CHL）15μg或西咪替丁（CIM）15μg,在20min内均可明显减弱应激对CSR的上述改变,CIM的这种减弱作用不如CHL的显著;（3）NTS内注射CHL（0.5μg）或CIM（1.5μg）,对应激所致CSR变化的影响与i.c.v.CHL或CIM后的相类似;（4）分别i.c.v.和NTS内注射CHL或CIM后,均不能使应激的CSR水平完全恢复到相应的非应激对照水平。以上结果提示,应激引起CSR重调定,反射敏感性下降;其部分机制可能是激活中枢组胺能系统,通过中枢组胺能受体（H1和H2受体）尤其是H1受体介导而发挥作用;下丘脑－NTS的组胺能通路可能是应激导致CSR重调定的下行通路之一。     

New nuclear magnetic resonance structures and structural methodology.

Progress in the field of protein nuclear magnetic resonance spectroscopy during the past year has included the elucidation of a number of new structures. In addition, several critical developments in the experimental methodology have opened up the potential for applying the nuclear magnetic resonance-based approach to structure determination in solution of recombinant proteins in excess of 15 kD.     

Functional imaging of plants by magnetic resonance experiments.

Microimaging based on magnetic resonance is an experimental technique that can provide a unique view of a variety of plant physiological processes. Particularly interesting applications include investigations of water movement and spatially resolved studies of the transport and accumulation of labelled molecules in intact plant tissue. Some of the fundamental principles of nuclear and electron magnetic resonance microimaging are explained here and the potential of these techniques is shown using several representative examples.     

Nuclear magnetic resonance signal chemical shifts and molecular simulations: a multidisciplinary approach to modeling copper protein structures

Nuclear magnetic resonance (NMR) chemical shifts are experimental observables that are available during the first stage of the protein structure determination process. Recently, some methodologies for building structural models of proteins using only these experimental data have been implemented. To assess the potential of these methods for modeling metalloproteins (generally considered a challenging benchmark), we determined the structures of the yeast copper chaperone Atx1 and the CuA domain of Thermus thermophilus cytochrome c oxidase starting from the available chemical shift data. The metal centers were modeled using molecular dynamics simulations with molecular mechanics potentials. The results obtained are evaluated and discussed.     

Functional magnetic resonance imaging during hypotension in the developing animal.

Hypotension in adult animals recruits brain sites extending from cerebellar cortex to the midbrain and forebrain, suggesting a range of motor and endocrine reactions to maintain perfusion. We hypothesized that comparable neural actions during development rely more extensively on localized medullary processes. We used functional MRI to assess neural responses during sodium nitroprusside challenges in 14 isoflurane-anesthetized kittens, aged 14-25 days, and seven adult cats. Baseline arterial pressure increased with age in kittens, and basal heart rates were higher. The magnitude of depressor responses increased with age, while baroreceptor reflex sensitivity initially increased over those of adults. In contrast to a decline in adult cats, functional MRI signal intensity increased significantly in dorsal and ventrolateral medullary regions and the midline raphe in the kittens during the hypotensive challenges. In addition, significant signal intensity differences emerged in cerebellar cortex and deep nuclei, dorsolateral pons, midbrain tectum, hippocampus, thalamus, and insular cortex. The altered neural responses in medullary baroreceptor reflex sites may have resulted from disinhibitory or facilitatory influences from cerebellar and more rostral structures as a result of inadequately developed myelination or other neural processes. A comparable immaturity of blood pressure control mechanisms in humans would have significant clinical implications.     

Facilitation of baroreceptor reflex response by endogenous somatostatin in the rat.

We evaluated the potential participation of endogenous brain somatostatin-14 (SOM) in central cardiovascular regulation, using adult male Sprague-Dawley rats anesthetized with pentobarbital sodium (40 mg/kg, i.p.). Intracerebroventricular (i.c.v.) application of SOM (2 or 4 nmol) promoted a significant elevation in baroreceptor reflex (BRR) response, induced by phenylephrine (5 micrograms kg, i.v.). Blocking the endogenous SOM activity with its specific receptor antagonist, cyclo-[7-aminoheptanoyl-Phe-D-Trp-Lys-Thr(Bzl)] (2 or 4 nmol, i.c.v.) or antiserum against SOM (1:20, i.c.v.), on the other hand, appreciably attenuated the same response. These modulatory effects on the BRR response were essentially duplicated upon bilateral microinjections of SOM (320 pmol), SOM antagonist (320 pmol) or anti-SOM (1:20) into the caudal portion of the nucleus of tractus solitarius (NTS), the terminal site for baroreceptor afferents. These results suggest that neurons that contain SOM may participate in cardiovascular control by tonically facilitating the BRR, possibly by exerting an influence on the neurons at the NTS.     

Substance P in the baroreceptor reflex: 25 years

Twenty-five years ago, very little was known about chemical communication in the afferent limb of the baroreceptor reflex arc. Subsequently, considerable anatomic and functional data exist to support a role for the tachykinin, substance P (SP), as a neuromodulator or neurotransmitter in baroreceptor afferent neurons. Substance P is synthesized and released from baroreceptor afferent neurons, and excitatory SP (NK1) receptors are activated by baroreceptive input to second-order neurons. SP appears to play a role in modulating the gain of the baroreceptor reflex. However, questions remain about the specific role and significance of SP in mediating baroreceptor information to the central nervous system (CNS), the nature of its interaction with glutaminergic transmission, the relevance of colocalized agents, and complex effects that may result from mediation of non-baroreceptive signals to the CNS.     

Functional magnetic resonance study of deliberate deception

The goal of the study was analysis of the cerebral mechanisms of deliberate deception. The eventrelated functional magnetic resonance (ER fMRI) imaging technique was used to assess the changes in the functional brain activity by means of recording the blood oxygen level-dependent (BOLD) signal. Twelve right-handed healthy volunteers aged 19–44 years participated in the study. The BOLD images were obtained during three experimental trials: deliberate deception, manipulative honest and control truthful trials (catch trials). The deliberate deception and manipulative honest actions were characterized by a BOLD signal increase in the anterior cingulate (Brodmann’s area (BA) 32), frontal (BAs 9/10, 6), and parietal (BA 40) cortices as compared with a truthful response. Comparison of the ER fMRI data with the results of earlier studies where event-related potentials (ERPs) were recorded under similar conditions indicates the involvement of the brain mechanism of error detection in deliberate deception.     

A neural set point for the long-term control of arterial pressure: beyond the arterial baroreceptor reflex

Arterial baroreceptor reflex control of renal sympathetic nerve activity (RSNA) has been proposed to play a role in long-term control of arterial pressure. The hypothesis that the "set point" of the acute RSNA baroreflex curve determines the long-term level of arterial pressure is presented and challenged. Contrary to the hypothesis, studies on the long-term effects of sinoaortic denervation (SAD) on arterial pressure and RSNA, as well as more recent studies of chronic baroreceptor "unloading" on arterial pressure, suggest that the basal levels of sympathetic nerve activity and arterial pressure are regulated independent of arterial baroreceptor input to the brainstem. Studies of the effect of SAD on the long-term salt sensitivity of arterial pressure are consistent with a short-term role, rather than a long-term role for the arterial baroreceptor reflex in regulation of arterial pressure during changes in dietary salt intake. Renal denervation studies suggest that renal nerves contribute to maintenance of the basal levels of arterial pressure. However, evidence that baroreflex control of the kidney plays a role in the maintenance of arterial pressure during changes in dietary salt intake is lacking. It is proposed that a "baroreflex-independent" sympathetic control system must exist for the long-term regulation of sympathetic nerve activity and arterial pressure. The concept of a central nervous system "set point" for long-term control of mean arterial pressure (CNS-MAP set point), and its involvement in the pathogenesis of hypertension, is discussed.     

Functional magnetic resonance imaging: imaging techniques and contrast mechanisms.

Functional magnetic resonance imaging (fMRI) is a widely used technique for generating images or maps of human brain activity. The applications of the technique are widespread in cognitive neuroscience and it is hoped they will eventually extend into clinical practice. The activation signal measured with fMRI is predicated on indirectly measuring changes in the concentration of deoxyhaemoglobin which arise from an increase in blood oxygenation in the vicinity of neuronal firing. The exact mechanisms of this blood oxygenation level dependent (BOLD) contrast are highly complex. The signal measured is dependent on both the underlying physiological events and the imaging physics. BOLD contrast, although sensitive, is not a quantifiable measure of neuronal activity. A number of different imaging techniques and parameters can be used for fMRI, the choice of which depends on the particular requirements of each functional imaging experiment. The high-speed MRI technique, echo-planar imaging provides the basis for most fMRI experiments. The problems inherent to this method and the ways in which these may be overcome are particularly important in the move towards performing functional studies on higher field MRI systems. Future developments in techniques and hardware are also likely to enhance the measurement of brain activity using MRI.     

Functional brain mapping by blood oxygenation level-dependent contrast magnetic resonance imaging. A comparison of signal characteristics with a biophysical model.

It recently has been demonstrated that magnetic resonance imaging can be used to map changes in brain hemodynamics produced by human mental operations. One method under development relies on blood oxygenation level-dependent (BOLD) contrast: a change in the signal strength of brain water protons produced by the paramagnetic effects of venous blood deoxyhemoglobin. Here we discuss the basic quantitative features of the observed BOLD-based signal changes, including the signal amplitude and its magnetic field dependence and dynamic effects such as a pronounced oscillatory pattern that is induced in the signal from primary visual cortex during photic stimulation experiments. The observed features are compared with the results of Monte Carlo simulations of water proton intravoxel phase dispersion produced by local field gradients generated by paramagnetic deoxyhemoglobin in nearby venous blood vessels. The simulations suggest that the effect of water molecule diffusion is strong for the case of blood capillaries, but, for larger venous blood vessels, water diffusion is not an important determinant of deoxyhemoglobin-induced signal dephasing. We provide an expression for the apparent in-plane relaxation rate constant (R2*) in terms of the main magnetic field strength, the degree of the oxygenation of the venous blood, the venous blood volume fraction in the tissue, and the size of the blood vessel.     

Lymphocyte activation and phospholipid pathways. 31P magnetic resonance studies

31P NMR spectra of perfused lymphocytes, embedded in alginate capsules and activated by interleukin-2, were remarkably different from those of control lymphocytes. The main differences were the appearance and gradual increase in phosphodiester signals, glycerophosphocholine and glycerophosphoethanolamine. These metabolic changes also occurred following perfusion with phorbol ester and after incubation with phytohemagglutinin (PHA) and were not dependent on a special growth medium. Nifedipine, a calcium channel blocking drug, inhibited the effects of phytohemagglutinin, but not of interleukin-2. There were no NMR spectral differences between peripheral lymphocytes, stimulated for 3 weeks, and tumor-infiltrating lymphocytes. Thus, sustained accelerated turnover of phosphatidylcholine and phosphatidylethanolamine is an inherent feature of the activation process. 31P NMR spectra of lymphocytes are characterized by a low signal of phosphocholine. Perfusion studies with high concentrations of choline and the use of dapsone, an inhibitor of cytidylyltransferase, indicated that choline kinase plays a key role in regulating phosphaditylcholine synthesis in human lymphocytes.     

Biology and therapy of fibromyalgia. Functional magnetic resonance imaging findings in fibromyalgia

Techniques in neuroimaging such as functional magnetic resonance imaging (fMRI) have helped to provide insights into the role of supraspinal mechanisms in pain perception. This review focuses on studies that have applied fMRI in an attempt to gain a better understanding of the mechanisms involved in the processing of pain associated with fibromyalgia. This article provides an overview of the nociceptive system as it functions normally, reviews functional brain imaging methods, and integrates the existing literature utilizing fMRI to study central pain mechanisms in fibromyalgia.