Linear Increase In Activity Research Articles

(Digital Presentation) Fabrication and Electrochemical Characterization of Inkjet Printed IrO2 Electrodes for Water Electrolysis

Water electrolysis is believed to be one of the most promising technologies to produce green hydrogen. However, the current challenge in commercialising this technology is the high relative cost. According to a recent report on cost breakdown of Polymer Electrolyte Membrane (PEM) electrolyser [1], the cell stack contributes to 35% - 45% of the total cost. Catalyst materials on the electrodes are believed to be the primary areas for innovation and cost reduction in PEM electrolysers. Several approaches have been applied to reduce the stack cost, with a focus on reducing material usage while enhancing the performance of PEM electrolysers. This project aims to reduce catalyst loading on the anode of PEM water electrolyser while maintaining high performance, through developing an inkjet printing technique to create a thin, porous and active catalyst layer. Conventional catalyst fabrication techniques such as spray coating produce large amount of material waste and non-homogenous distribution on the surface [2]. Inkjet printing will provide controlled catalyst loading, ensuring well catalyst distribution, creating porous structure, and having the ability to create patterned electrodes [3].Due to its high activity, Iridium Oxide (IrO2) is selected as the catalyst. The ink was formulated to be compatible with the printing requirement, with 7.5 wt% of IrO2 powder, 7.9 wt% of Nafion, and 84.5 wt% of solvents mixture of Isopropanol and Propylene Glycol. Full coverage of the catalyst on the Titanium substrate was proven by Scanning Electron Microscopy (SEM) with Energy Dispersive X-Ray Analysis (EDX). The effect on varying the number of printed layers was analysed in terms of catalyst loading and activity to show a linear increase in activity with the number of layers. Moreover, electrochemical performance was inspected using cyclic voltammetry in a 3-electrodes cell. The printed electrodes showed comparable stability to conventional electrodes. Electrochemical surface area (ECSA) was higher for the 10-layered electrodes as compared to the 2-layered electrodes indicating higher catalyst utilisation. Printed electrodes showed activity of 300 mA/mg IrO2 with ECSA of 225 cm2 at reduced catalyst loading of 0.8 mg IrO2/cm2. These results outperform conventionally fabricated electrodes by spray and decal transfer coatings [4].

How has COVID-19 social distancing impacted physical activity patterns? Data from the PAMPA cohort, Brazil

ObjectiveThis study aimed to evaluate how social distancing measures affected physical activity (PA) patterns in adults from Rio Grande do Sul, Brazil. MethodsParticipants were recruited from social and local media campaigns, contacts with private and public universities, as well as research personal contacts across the state. PA was assessed before (retrospectively) and during social distancing. Frequency (days per week) and time (minutes per day) were asked to those participants who practiced PA. Two PA variables were built to each time-frame (before and during social distancing): 1) any PA (yes/no question), and 2) sufficient PA (based on the 150 min/week cut-off point). ResultsOverall, 2321 participants answered the questionnaire. Any and sufficient PA decreased from before to during social distancing (22.3% and 17.0%, respectively). A linear increase of activity during social distancing was observed in participants who practiced up to 400 min or less of PA per week before social distancing. Regarding associated factors, female, overweight/obese and diagnosed chronic disease participants were less likely to practice any or sufficient PA during social distancing when compared to the period before. ConclusionPA practice (both any and sufficient) decreased in Southern Brazil in the first months of social distancing. Women, overweight/obese and chronic diseased participants showed a higher decrease in PA compared to other groups. Finally, those participants who practiced PA before social distancing were more likely to continue practicing during COVID-19 pandemic.

Cerebellar and premotor activity during a non-fatiguing grip task reflects motor fatigue in relapsing-remitting multiple sclerosis.

Fatigue is a common and highly disabling symptom of multiple sclerosis. Patients experience an effort-independent general subjective feeling of fatigue as well as excessive fatigability when engaging in physical or mental activity. Previous research using functional magnetic resonance imaging (fMRI) has revealed heterogeneous findings, but some evidence implicates the motor system. To identify brain correlates of fatigue, 44 mildly impaired patients with relapsing-remitting multiple sclerosis and 25 age- and gender-matched healthy controls underwent functional magnetic resonance imaging at 3 Tesla, while they performed alternating blocks of rest and a non-fatiguing precision grip task. We investigated neural correlates of fatigue using the motor subscore of Fatigue Scale for Motor and Cognitive Functions (FSMCMOTOR) using the bilateral motor cerebellum, putamen, and dorsal premotor cortex as regions of interest. Patients and healthy controls performed the grip force task equally well without being fatigued. In patients, task-related activity in lobule VI of right motor cerebellum changed in proportion with individual FSMCMOTOR scores. In right dorsal premotor cortex, linear increases in activity across consecutive task blocks scaled with individual FSMCMOTOR scores in healthy controls, but not in patients. In premotor and dorsomedial prefrontal areas, patients were impaired at upscaling task-related activity the more they were affected by motor fatigue. The results support the notion that increased sensorimotor processing in the cerebellum contributes to the experience of motor fatigue and fatigability in multiple sclerosis. Additionally, downscaling of motivational input or sensorimotor processing in prefrontal and premotor areas may constitute an additional pathophysiological factor.

Tunability of the Adsorbate Binding on Bimetallic Alloy Nanoparticles for the Optimization of Catalytic Hydrogenation.

In this paper, we show that PtAu and PdAu random alloy dendrimer-encapsulated nanoparticles with an average size of ∼1.6 nm have different catalytic activity trends for allyl alcohol hydrogenation. Specifically, PtAu nanoparticles exhibit a linear increase in activity with increasing Pt content, whereas PdAu dendrimer-encapsulated nanoparticles show a maximum activity at a Pd content of ∼60%. Both experimental and theoretical results suggest that this contrasting behavior is caused by differences in the strength of H binding on the PtAu and PdAu alloy surfaces. The results have significant implications for predicting the catalytic performance of bimetallic nanoparticles on the basis of density functional theory calculations.

The effect of motor familiarity during simple finger opposition tasks.

Humans are more familiar with performing (and observing) index-thumb than with any other finger to thumb grasping and the effect of familiarity has not been tested specifically with simple and intransitive actions. The study of simple and intransitive motor actions (i.e. simple actions without need of object interaction) provides the opportunity to investigate specifically the brain motor regions reducing the effect of non-motor aspects that are related with more complex and/or transitive motor actions. The aim of this study is to evaluate brain activity patterns during the execution of simple and intransitive finger movements with different degrees of familiarity. With this in mind, a functional Magnetic Resonance Imaging (fMRI) study was performed in which participants were asked to execute finger to thumb opposition tasks with all the different fingers (index, middle, ring and little) with a fixed frequency (1 Hz) determined by a visual cue. This movement is considered as the pantomime of a precision grasping action. Significant activity was identified in the Sensory Motor Cortex (SMC), posterior parietal and premotor regions for all simple conditions (index-finger>control, middle-finger>control, ring-finger>control and little-finger>control). However, a linear trend contrast (index<middle<ring<little) demonstrated that there was a linear increase of activity in the SMC (mainly in the Precentral Gyrus) while the finger used to perform the action was further from the thumb. Therefore, the execution of less familiar simple intransitive movements seems to lead to a stronger activation of the SMC than familiar ones. Posterior parietal and premotor regions did not show the aforementioned stronger activation. The most important implication of this study is the identification of differences in brain activity during the execution of simple intransitive movements with different degrees of familiarity.

Re-Imagining the Future: Repetition Decreases Hippocampal Involvement in Future Simulation

Imagining or simulating future events has been shown to activate the anterior right hippocampus (RHC) more than remembering past events does. One fundamental difference between simulation and memory is that imagining future scenarios requires a more extensive constructive process than remembering past experiences does. Indeed, studies in which this constructive element is reduced or eliminated by “pre-imagining” events in a prior session do not report differential RHC activity during simulation. In this fMRI study, we examined the effects of repeatedly simulating an event on neural activity. During scanning, participants imagined 60 future events; each event was simulated three times. Activation in the RHC showed a significant linear decrease across repetitions, as did other neural regions typically associated with simulation. Importantly, such decreases in activation could not be explained by non-specific linear time-dependent effects, with no reductions in activity evident for the control task across similar time intervals. Moreover, the anterior RHC exhibited significant functional connectivity with the whole-brain network during the first, but not second and third simulations of future events. There was also evidence of a linear increase in activity across repetitions in right ventral precuneus, right posterior cingulate and left anterior prefrontal cortex, which may reflect source recognition and retrieval of internally generated contextual details. Overall, our findings demonstrate that repeatedly imagining future events has a decremental effect on activation of the hippocampus and many other regions engaged by the initial construction of the simulation, possibly reflecting the decreasing novelty of simulations across repetitions, and therefore is an important consideration in the design of future studies examining simulation.

Brain Cells in the Avian ‘Prefrontal Cortex’ Code for Features of Slot-Machine-Like Gambling

Slot machines are the most common and addictive form of gambling. In the current study, we recorded from single neurons in the ‘prefrontal cortex’ of pigeons while they played a slot-machine-like task. We identified four categories of neurons that coded for different aspects of our slot-machine-like task. Reward-Proximity neurons showed a linear increase in activity as the opportunity for a reward drew near. I-Won neurons fired only when the fourth stimulus of a winning (four-of-a-kind) combination was displayed. I-Lost neurons changed their firing rate at the presentation of the first nonidentical stimulus, that is, when it was apparent that no reward was forthcoming. Finally, Near-Miss neurons also changed their activity the moment it was recognized that a reward was no longer available, but more importantly, the activity level was related to whether the trial contained one, two, or three identical stimuli prior to the display of the nonidentical stimulus. These findings not only add to recent neurophysiological research employing simulated gambling paradigms, but also add to research addressing the functional correspondence between the avian NCL and primate PFC.

Do you like me? Neural correlates of social evaluation and developmental trajectories

Social acceptance is of key importance for healthy functioning. We used functional magnetic resonance imaging (fMRI) to examine age-related changes in the neural correlates of social acceptance and rejection processing. Participants from four age groups participated in the study: pre-pubertal children (8–10 years), early adolescents (12–14 years), older adolescents (16–17 years) and young adults (19–25 years). During the experiment, participants were presented with unfamiliar faces of peers and were asked to predict whether they expected to be liked or disliked by the other person, followed by feedback indicating acceptance or rejection. Results showed that activation in the ventral mPFC and striatum to social feedback was context-dependent; there was increased activation when participants had positive expectations about social evaluation, and increased activation following social acceptance feedback. Age-related comparisons revealed a linear increase in activity with age in these brain regions for positive expectations of social evaluation. Similarly, a linear increase with age was found for activation in the striatum, ventral mPFC, OFC, and lateral PFC for rejection feedback. No age-related differences in neural activation were shown for social acceptance feedback. Together, these results provide important insights in the developmental trajectories of brain regions implicated in social and affective behavior.

Exposure–response analysis of tigecycline in pharmacodynamic simulations using different size inocula of target bacteria

This study explored tigecycline exposure–bacterial responses in pharmacodynamic simulations (in vitro kinetic model) using different inocula. One meticillin-resistant vancomycin-heteroresistant Staphylococcus aureus, one Enterococcus faecium and one extended-spectrum β-lactamase-producing Escherichia coli with equal tigecycline minimum inhibitory concentrations/minimum bactericidal concentrations (MICs/MBCs) (0.12/0.25 μg/mL) were used. A computerised pharmacodynamic bicompartmental model simulated three tigecycline twice-daily dosing regimens over 48 h: 50 mg (100 mg loading dose); 100 mg; and 150 mg. Areas under bacterial growth curves were calculated, and differences between the growth curve used as control and the killing curve of bacteria exposed to tigecycline (ABBC) were determined. With standard inocula [ca. 1 × 10 6 colony-forming units (CFU)/mL], linear increases in area under the concentration–time curve (AUC)/MIC (25.6 for 50 mg, 53.76 for 100 mg and 79.52 for 150 mg) produced linear increases in activity against Gram-positive organisms (mean ABBCs of 120.60, 143.20 and 195.80 log CFU × h/mL for S. aureus and of 95.75, 172.55 and 216.90 log CFU × h/mL for E. faecium, respectively), with the activity of the 150 mg regimen being significantly higher ( P < 0.01) than that of the other two regimens. ABBCs obtained with the 100 mg regimen using standard inocula were similar to those obtained with the 150 mg regimen when using high inocula (ca. 1 × 10 7 CFU/mL). Against E. coli, the highest dosing regimen was required to obtain significant antibacterial activity compared with control (mean ABBCs of 145.75 log CFU × h/mL with standard inocula and 63.33 log CFU × h/mL with high inocula). An increase in tigecycline dosing appears to be an interesting therapeutic option to maximise antibacterial activity owing to its linear pharmacokinetics and pharmacodynamics, especially when severe infections with high bacterial load are suspected.

Dissociation within the Frontoparietal Network in Verbal Working Memory: A Parametric Functional Magnetic Resonance Imaging Study

Concomitant increase in activity within the mid-dorsolateral prefrontal cortex (MDLFC) and the posterior parietal cortex (PPC) is observed in most functional neuroimaging studies of working memory (Collette et al., 1999; Gerton et al., 2004; Sun et al., 2005; Postle et al., 2006; Champod and Petrides, 2007; Emery et al., 2008). Despite broad consensus on the importance of these two brain regions in working memory, their unique contribution, especially that of the PPC, remains a matter of heated debate (Paulesu et al., 1993; Smith and Jonides, 1998; Postle et al., 1999; Berryhill and Olson, 2008). The main objective of the present parametric event-related functional magnetic resonance imaging study was to examine the hypothesis that the cortex in the intraparietal sulcus region in the PPC is involved in the manipulation (i.e., rearrangement) of verbal information in working memory and to dissociate the involvement of this brain region from that of the MDLFC in working memory processes. The results demonstrated a linear increase in activity within the MDLFC during the manipulation and monitoring of a linearly increasing number of words in working memory. In sharp contrast, there was a linear increase in activity within the PPC during the manipulation but not the monitoring of a linearly increasing number of words. This study provides the first parametric dissociation of activation in these two cortical regions indicating a crucial role of the PPC in the manipulation of information in working memory, with the MDLFC playing a major role in monitoring this information.

Rotated alphanumeric characters do not automatically activate frontoparietal areas subserving mental rotation

Functional neuroimaging studies have identified a set of areas in the intraparietal sulcus and dorsal precentral cortex which show a linear increase in activity with the angle of rotation across a variety of mental rotation tasks. This linear increase in activity with angular disparity suggests that these frontoparietal regions compute rotational transformations. An open question is whether rotated target stimuli automatically activate these frontoparietal regions, even if the task does not require rotational transformations. To address this question, we performed functional MRI while healthy male volunteers made two-choice reaction-time judgements on canonical or mirror images of two-dimensional alphanumeric characters presented at various angles of rotation. Participants had either to decide whether characters were normal or mirror-reversed (i.e., mental rotation) or judge whether the stimulus was a letter or a number (i.e., stimulus categorization). Reaction times and error rates linearly increased with the angle of rotation for mirror-reversed judgements but not for number–letter judgements, showing that only the mental rotation task required rotational transformations of the characters. The mental rotation task was associated with a linear increase in neuronal activity with angular disparity in a bilateral set of frontoparietal areas, comprising the rostral dorsal premotor cortex, frontal eye field, ventral and medial intraparietal sulcus. Neuronal activity in these regions was neither increased nor modulated by angular disparity during the stimulus categorization task. These results suggest that at least for alphanumerical characters, areas implicated in mental rotation will only be called into action if the task requires a rotational transformation.

Compositional Effects in Ru, Pd, Pt, and Rh-Doped Mesoporous Tantalum Oxide Catalysts for Ammonia Synthesis

A series of early metal-promoted Ru-, Pd-, Pt-, and Rh-doped mesoporous tantalum oxide catalysts were synthesized using a variety of dopant ratios and dopant precursors, and the effects of these parameters on the catalytic activity of NH3 synthesis from H2 and N2 were explored. Previous studies on this system supported an unprecedented mechanism in which N-N cleavage occurred at the Ta sites rather than on Ru. The results of the present study showed, for all systems, that Ba is a better promoter than Cs or La and that the nitrate is a superior precursor for Ba than the isopropoxide or the hydroxide. 15N-labeling studies showed that residual nitrate functions as the major ammonia source in the first hour but that it does not account for the ammonia produced after the nitrate is completely consumed. Ru3(CO)12 proved to be a better Ru precursor than RuCl(3).3H2O, and an almost linear increase in activity with increasing Ru loading level was observed at 350 degrees C (623 K). However, at 175 degrees C (448 K), the increase in Ru had no effect on the reaction rate. Pd functioned with comparable rates to Ru, while Pt and Rh functioned far less efficiently. The surprising activities for the Pd-doped catalysts, coupled with XPS evidence for low-valent Ta in this catalyst system, support a mechanism in which cleavage of the N-N triple bond occurs on Ta rather than the precious metal because the Ea value for N-N cleavage on Pd is 2.5 times greater than that for Ru, and the 9.3 kJ mol-1 Ea value measured previously for the Ru system suggests that N-N cleavage cannot occur at the Ru surface.

EFFECTIVE DOSE SCALING FACTORS FOR USE WITH CASCADE IMPACTOR SAMPLING DATA IN TENORM INHALATION EXPOSURES

When assessing the effective dose to workers following radio-aerosol inhalation exposures, significant reductions in dose uncertainty can be achieved through direct measurement of the particle-size distribution. The University of Washington Mark III cascade impactor is one such air sampling device that permits the user to determine aerosol mass and radioactivity concentrations as a function of particle size within eight different size intervals (each corresponding to a different impactor stage or end filter). Traditionally, dose assessments made using the LUDEP code or other internal dosimetry software utilize this air sampling information by assigning the radioactivity measured at each stage as concentrated at a single representative size central to the size interval. In this study, we explore more realistic assumptions that the measured radioactivity distributes uniformly, linearly increases, or linearly decreases across the particle size interval for each impactor stage. The concept of an effective dose scaling factor, SF(E), is thus introduced whereby (1) the former approach can be used (which requires less computational effort using the LUDEP code), and (2) the resulting values of effective dose per stage can then be rescaled to values appropriate to a linear radioactivity distribution per stage. For a majority of (238)U-series radionuclides, particle size ranges, and absorption classes, differences in these two approaches are less than 10%, and thus no corrections in effective dose per particle stage are needed. Significant corrections, however, were noted in select cases. For uniform or linearly decreasing radioactivity distributions, end-filter particles (0.03 to 0.35 microm) of type F, M, or S radionuclides were assigned values of SF(E) ranging from 1.15 to 1.44, while 3(rd) stage particles (4.5 to 12 microm) of type M and S radionuclides were assigned values of SF(E) ranging from 1.11 to 1.53. When the cascade impactor measurements indicate a linear increase of activity across a given impactor-stage size range, values of SF(E) range from a high of 1.11 (6(th) stage particles of type F radionuclides) to lows of 0.85 to 0.91 (4(th) stage and end-filter particles of type M and S radionuclides). In these cases, the inhalation dose coefficient varies non-linearly across the particle size range, and the assumption of a mono-size distribution per impactor stage either underestimates (SF(E) > 1) or overestimates (SF(E) < 1) that stage's contribution to the worker effective dose.

Circulating cortisone levels are associated with biochemical markers of bone formation and lumbar spine BMD: the Hertfordshire Cohort Study

Cortisone is an endogenous corticosteroid that has negligible intrinsic glucocorticoid activity but can be converted to the active corticosteroid cortisol by the enzyme 11beta-hydroxysteroid dehydrogenase type 1 (11beta-HSD1). 11beta-HSD1 is expressed in osteoblasts and may play a role in determining susceptibility to glucocorticoid-induced osteoporosis. In intact osteoblasts enzyme activity, and thus cortisol generation, is dependent on substrate concentration with an almost linear increase in activity across the physiological range. We have therefore attempted to measure the impact of 11beta-HSD1 activity on bone in vivo by examining the association of circulating cortisone with bone markers, bone mineral density (BMD) and bone loss in a cohort of women and men. Baseline cross-sectional association study involving 135 women and 171 men aged 61-73 years from the Hertfordshire Cohort Study and a 4 year follow-up study examining changes in BMD. Serum cortisone, cortisol and osteocalcin, and urinary type I collagen cross-linked N-telopeptide (NTX) were measured at baseline. BMD at spine and hip was measured at baseline and 4 years later. In men serum cortisone levels were negatively correlated with serum osteocalcin (r = -0.20, P = 0.01); a similar relationship was seen in women (r = -0.16, P = 0.06). No correlation was seen between serum cortisone and urinary NTX (r = 0.03, P = 0.74 for women; r = -0.03, P = 0.72 for men). A negative correlation was observed between serum cortisone and spine BMD in women (r = -0.18, P = 0.04); a similar relationship was also seen in men (r =-0.14, P = 0.07). However, cortisone did not correlate with BMD at the femoral neck or total hip or changes in BMD at any site over time. In analyses adjusted for adiposity, osteoarthritis grade and a range of life-style variables, these relationships did not change substantially. All these relationships were independent of cortisol concentrations. The most plausible explanation for the association of circulating cortisone levels with osteocalcin is the presence of 11beta-HSD1 activity within osteoblasts. The measurement of serum cortisone may independently give insights into the action of glucocorticoids on bone.

Patterns of neuronal activation in the rat brain and spinal cord in response to increasing durations of restraint stress

By most accounts the psychological stressor restraint produces a distinct pattern of neuronal activation in the brain. However, some evidence is incongruous with this pattern, leading us to propose that the restraint-induced pattern in the central nervous system might depend on the duration of restraint used. We therefore determined the pattern of neuronal activation (as indicated by the presence of Fos protein) seen in the paraventricular nucleus (PVN), bed nucleus of the stria terminalis, amygdala, locus coeruleus, nucleus tractus solitarius (NTS), ventrolateral medulla (VLM) and thoracic spinal cord of the rat in response to 0, 15, 30 or 60 min periods of restraint. We found that although a number of cell groups displayed a linear increase in activity with increasing durations of restraint (e.g. hypothalamic corticotrophin-releasing factor (CRF) cells, medial amygdala neurons and sympathetic preganglionic neurons of the thoracic spinal cord), a number of cell groups did not. For example, in the central amygdala restraint produced both a decrease in CRF cell activity and an increase in non-CRF cell activity. In the locus coeruleus, noradrenergic neurons did not display Fos in response to 15 min of restraint, but were significantly activated by 30 or 60 min restraint. After 30 or 60 min restraint a greater degree of activation of more rostral A1 noradrenergic neurons was observed compared with the pattern of A1 noradrenergic neurons in response to 15 min restraint. The results of this study demonstrate that restraint stress duration determines the amount and the pattern of neuronal activation seen in response to this psychological stressor.

Neuron-specific aminopeptidase and puromycin-sensitive aminopeptidase in rat brain development.

Neuron-specific aminopeptidase (NAP) and the ubiquitous puromycin-sensitive aminopeptidase (PSA) were compared in the rat hippocampus during early development. Hippocampus contains the highest amount of NAP determined by a fast-protein liquid chromatography-aminopeptidase analyzer using Leu beta-naphthylamide as substrate. Both enzymes were found in the hippocampus in all ages. NAP was lower in immature rat; the 19th embryonic-day fetus contained the least. It increased steeply during the prenatal through the early postnatal period, 9-fold by the first month. The rate of increase diminished subsequently, increasing 20% in the second month and 13% in the third. The age-dependent increase in NAP activity was parallel to its protein expression as determined by Western blot. The specific molecular activity (hydrolytic activity/ NAP antigenicity) in newborn, 15-day-old, and 30-day-old rats were 1.00, 0.88, and 1.00, respectively. The PSA developmental profile without linear increase in activity was distinct from NAP. PSA activity was higher than NAP in decreasing order, 100-4 times, during the same development span. Similarly, different growth profiles for NAP and PSA were also found in the primary culture of developing cerebellar granule cells. Puromycin (1-5 microM) blocked neurite outgrowth and caused apoptosis by nonantibiotic effects. Our data suggest that the synaptosome-enriched NAP plays a role in neuron growth, differentiation, and information programming.

Browning, polyphenol oxidase activity and headspace gas composition during storage of minimally processed pears using modified atmosphere packaging

AbstractModified atmosphere packaging was used to prevent browning of minimally processed Conference pears, thus extending their shelf‐life. Colour changes as well as PPO activity were strongly influenced by the package headspace gas composition, which was determined by the packaging conditions. The initial colour of minimally processed pears was preserved for several weeks under cold storage in plastic pouches of very low O2 permeability and an initial atmosphere of 100% N2. A fractional conversion kinetic model fitted the experimental browning data with high accuracy. Colour degradation (ΔE*) of minimally processed pears occurred exponentially (kΔE = 0.019–0.077 day−1) owing to changes in lightness (kL = 0.021–0.07 day−1). In contrast, PPO exhibited a linear increase in activity which could be related to the availability of O2 in the package headspace.© 2002 Society of Chemical Industry

Relations between the neural bases of dynamic auditory processing and phonological processing: evidence from fMRI.

Functional magnetic resonance imaging (fMRI) was used to examine how the brain responds to temporal compression of speech and to determine whether the same regions are also involved in phonological processes associated with reading. Recorded speech was temporally compressed to varying degrees and presented in a sentence verification task. Regions involved in phonological processing were identified in a separate scan using a rhyming judgment task with pseudowords compared to a lettercase judgment task. The left inferior frontal and left superior temporal regions (Broca's and Wernicke's areas), along with the right inferior frontal cortex, demonstrated a convex response to speech compression; their activity increased as compression increased, but then decreased when speech became incomprehensible. Other regions exhibited linear increases in activity as compression increased, including the middle frontal gyri bilaterally. The auditory cortices exhibited compression-related decreases bilaterally, primarily reflecting a decrease in activity when speech became incomprehensible. Rhyme judgments engaged two left inferior frontal gyrus regions (pars triangularis and pars opercularis), of which only the pars triangularis region exhibited significant compression-related activity. These results directly demonstrate that a subset of the left inferior frontal regions involved in phonological processing is also sensitive to transient acoustic features within the range of comprehensible speech.

Measuring object recognition

The role of object recognition in our everyday interaction with the environment is, quite obviously, very important. It is hardly surprising, then, that numerous functional neuroimaging studies have explored the various brain areas that might be involved in this skill. But so far, many of these studies have used relatively long and unmasked presentations of the stimuli. Thus, it is difficult to differentiate which areas of the brain are involved in actually recognizing the object, and which mediate other processes, such as the activation of semantic knowledge or memory consolidation.Recently, Barr and colleagues1xCortical mechanisms specific to explicit visual object recognition. Barr, M. et al. Neuron. 2001; 29: 529–535Abstract | Full Text | Full Text PDF | PubMed | Scopus (295)See all References1 carried out an event-related fMRI study in which they presented subjects with a series of objects, with a range of presentation durations with visual masks, in four stages from easy (i.e. aware of target object) to very difficult (i.e. hardly aware). This experimental design revealed a linear increase in activity in the ventrotemporal region of the cortex, a neural system that has previously been implicated in object recognition. The results showed in addition that the focus of functional activity shifted anteriorly along this area of the cortex when subjects indicated easier recognition of the object.As well as being an excellent example of a tightly controlled experimental design, this study is one of the first to reveal an associated increase in brain activity with a subjective measure of object recognition. Although not directly assessed, the anterior shift of the focus of functional activity coupled with the behavioral indication of an improvement in recognition suggests greater semantic processing of the object the more it is recognized. Taken together, these results contribute to a greater understanding of the processes involved, and the corresponding neural substrates, in the recognition of objects.

Motor response suppression and the prepotent tendency to respond: a parametric fMRI study

In the present study we utilised functional magnetic resonance imaging (fMRI) to examine cerebral activation during performance of a classic motor task in which response suppression load was parametrically varied. Linear increases in activity were observed in a distributed network of regions across both cerebral hemispheres, although with more extensive involvement of the right prefrontal cortex. Activated regions included prefrontal, parietal and occipitotemporal cortices. Decreasing activation was similarly observed in a distributed network of regions. These response forms are discussed in terms of an increasing requirement for visual cue discrimination and suppression/selection of motor responses, and a decreasing probability of the occurrence of non-target stimuli and attenuation of a prepotent tendency to respond. The results support recent proposals for a dominant role for the right-hemisphere in performance of motor response suppression tasks that emphasise the importance of the right prefrontal cortex.