Neural correlates of perceptual switching while listening to bistable auditory streaming stimuli.

Understanding the neural underpinning of conscious perception remains one of the primary challenges of cognitive neuroscience. Theories based mostly on studies of the visual system differ according to whether the neural activity giving rise to conscious perception occurs in modality-specific sensory cortex or in associative areas, such as the frontal and parietal cortices. Here, we search for modality-specific conscious processing in the auditory cortex using a bistable stream segregation paradigm that presents a constant stimulus without the confounding influence of physical changes to sound properties. ABA_ triplets (i.e., alternating low, A, and high, B, tones, and _ gap) with a 700 ms silent response period after every third triplet were presented repeatedly, and human participants reported nearly equivalent proportions of 1- and 2-stream percepts. The pattern of behavioral responses was consistent with previous studies of visual and auditory bistable perception. The intermittent response paradigm has the benefit of evoking spontaneous perceptual switches that can be attributed to a well-defined stimulus event, enabling precise identification of the timing of perception-related neural events with event-related potentials (ERPs). Significantly more negative ERPs were observed for 2-streams compared to 1-stream, and for switches compared to non-switches during the sustained potential (500-1000 ms post-stimulus onset). Further analyses revealed that the negativity associated with switching was independent of switch direction, suggesting that spontaneous changes in perception have a unique neural signature separate from the observation that 2-stream percepts evoke more negative ERPs than 1-stream. Source analysis of the sustained potential showed activity associated with these differences originating in anterior superior temporal gyrus, indicating involvement of the ventral auditory pathway that is important for processing auditory objects.

Coping Styles, Pain Expressiveness, and Implicit Theories of Chronic Pain.

Whereas some individuals use active coping strategies and are able to adaptively cope with their pain, others use passive strategies and catastrophic appraisals, which are often associated with increased displays of pain behavior and negative pain-related outcomes. To investigate attribution-based implicit theories as a potential underlying mechanism that might affect coping success, we hypothesized that pain patients with an incremental implicit theory of pain (i.e., view pain as malleable) would have more active coping strategies, lower levels of pain expressiveness, and better pain-related outcomes than those with an entity implicit theory of pain (i.e., view pain as nonmalleable). Patients with chronic back pain undergoing a functional assessment completed a variety of self-report measures and participated in a pain-inducing physiotherapy procedure. The results revealed those with an incremental theory of pain used more active coping strategies, displayed less pain behavior, and reported better pain-related outcomes (e.g., lower levels of depression) than individuals with an entity theory of pain. The findings suggest implicit theories of pain may represent an underlying social-cognitive mechanism linked to important coping, emotional, and expressive reactions to chronic pain. Identifying such a mechanism may provide valuable information for the assessment and treatment of chronic pain.

Spectral processing deficits in belt auditory cortex following early postnatal lesions of somatosensory cortex.

Induced or genetically based cortical laminar malformations in somatosensory cortex have been associated with perceptual and acoustic processing deficits in mammals. Perinatal freeze-lesions of developing rat primary somatosensory (S1) cortex induce malformations resembling human microgyria. Induced microgyria located in parietal somatosensory cortex have been linked to reduced behavioral detection of rapid sound transitions and altered spectral processing in primary auditory cortex (A1). Here we asked whether belt auditory cortex function would be similarly altered in rats with S1 microgyria (MG+). Pure-tone acoustic response properties were assessed in A1 and ventral auditory (VAF) cortical fields with Fourier optical imaging and multi-unit recordings. Three changes in spectral response properties were observed in both A1 and VAF in MG+ rats: 1) multi-unit response magnitudes were reduced 2) optical and multi-unit frequency responses were more variable; 3) at high sound levels units responded to a broader range of pure-tone frequencies. Optical and multi-unit pure-tone response magnitudes were both reduced for low sound levels in VAF but not A1. Sound level "tuning" was reduced in VAF but not in A1. Finally, in VAF frequency tuning and spike rates near best frequency were both altered for mid- but not high-frequency recording sites. These data suggest that VAF belt auditory cortex is more vulnerable than A1 to early postnatal induction of microgyria in neighboring somatosensory cortex.

Early cortical damage in rat somatosensory cortex alters acoustic feature representation in primary auditory cortex.

Early postnatal freeze-lesions to the cortical plate result in malformations resembling human microgyria. Microgyria in primary somatosensory cortex (S1) of rats are associated with a reduced behavioral detection of rapid auditory transitions and the loss of large cells in the thalamic nucleus projecting to primary auditory cortex (A1). Detection of slow transitions in sound is intact in animals with S1 microgyria, suggesting dissociation between responding to slow versus rapid transitions and a possible dissociation between levels of auditory processing affected. We hypothesized that neuronal responses in primary auditory cortex (A1) would be differentially reduced for rapid sound repetitions but not for slow sound sequences in animals with S1 microgyria. We assessed layer IV cortical responses in primary auditory cortex (A1) to single pure-tones and periodic noise bursts (PNB) in rats with and without S1 microgyria. We found that responses to both types of acoustic stimuli were reduced in magnitude in animals with microgyria. Furthermore, spectral resolution was degraded in animals with microgyria. The cortical selectivity and temporal precision were then measured with conventional methods for PNB and tone-stimuli, but no significant changes were observed between microgyric and control animals. Surprisingly, the observed spike rate reduction was similar for rapid and slow temporal modulations of PNB stimuli. These results suggest that acoustic processing in A1 is indeed altered with early perturbations of neighboring cortex. However, the type of deficit does not affect the temporal dynamics of the cortical output. Instead, acoustic processing is altered via a systematic reduction in the driven spike rate output and spectral integration resolution in A1. This study suggests a novel form of plasticity, whereas early postnatal lesions of one sensory cortex can have a functional impact on processing in neighboring sensory cortex.

Attributional style predicts causes of negative life events on the Attributional Style Questionnaire.

The causes cited by 218 participants for the hypothetical positive and negative life events on the Attributional Style Questionnaire (ASQ) and the dimensional ratings of the causes were examined to determine the match between the dimensional and categorical definitions of attributional style. Optimists (n = 105) and pessimists (n = 113) used different types of causes to explain the negative ASQ events, but not the positive events. However, optimists' and pessimists' causal explanations shared a number of features. The findings suggest that attributional styles depend, in part, on the event being explained and demonstrate that the ASQ events elicit specific types of causes.

Expression and function of the beta-adrenergic receptor coupled-adenylyl cyclase system on human airway epithelial cells.

Beta-adrenergic agonist-mediated activation of the beta receptor coupled-adenylyl cyclase (beta AR-AC) system expressed by human airway epithelial cells alters airway function. However, little is known about the magnitude of expression, subtype, and function of the beta receptor-adenylyl cyclase (beta AR-AC) system in human airway epithelial cells from healthy, nonsmoking subjects. Therefore, we characterized beta AR number and subtype and the cAMP response to isoproterenol (iso) in acutely dissociated human tracheocytes harvested from 22 healthy, nonsmoking adults during fibroptic bronchoscopy. Moreover, because the regulation of beta AR-AC system function in response to beta-agonists or inflammatory mediators released into the airway in asthma is poorly understood, we examined the cAMP response to iso after 30 min exposure of cells to iso or the protein kinase C activator, sn-1,2-dioctanoyl glycerol (diC8). The beta AR-AC system was highly expressed and functional in human airway epithelial cells. Group mean beta AR density (i.e., Bmax), equilibrium dissociation constant (Kd), and the percentage of beta 2AR subtypes assessed by radioligand binding were approximately 8,900 receptors/cell, 45 pM, and approximately 80%, respectively. Mean maximum cAMP production was approximately 42 pmol/10(5) cells, and the mean EC50 of the response to iso was 131 nM. However, Bmax and cAMP responses to iso varied considerably across subjects. For example, Bmax varied ninefold, and the EC50 of the cAMP response varied 39-fold interindividually. The EC50 was inversely related to beta AR density (r = -0.81, p < 0.05), suggesting that sensitivity of the cAMP response to iso was in part dependent on beta AR density. In all experiments, cAMP responses to iso stimulation were markedly desensitized in dose-dependent fashion by 30 min pretreatment with iso or diC8. For example, pretreatment with iso 10 microM or diC8 100 microM reduced maximum cAMP production to 22 and 63% of control values, respectively. These data indicate that: (1) the beta AR-AC system is highly expressed on acutely dissociated airway epithelial cells from normal adult, but beta AR expression and its functional coupling to adenylyl cyclase vary considerably interindividually; and (2) the beta AR-AC system of normal human airway epithelial cells is rapidly desensitized by exposure to beta-adrenergic agonists or activators of PKC.

Functional behavior of the beta-adrenergic receptor-adenylyl cyclase system in rabbit airway epithelium.

Stimulation of adenylyl cyclase mediates the effects of beta-adrenergic agonists and prostaglandin E2 (PGE2) on tracheobronchial epithelial cell function by increasing intracellular cyclic adenosine monophosphate (cAMP). In turn, increases in cAMP affect airway function by modulating ciliary beating, chloride and water transport, mucus secretion, and release of bronchoactive substances. This study examined the function and regulation of the beta-adrenergic receptor-adenylyl cyclase system (beta AR-AC) in tracheal epithelial cells isolated from the rabbit, a frequently used animal model of airway reactivity, inflammation, and electrolyte transport. beta AR number, assessed by ligand binding using the non-subtype-specific beta-antagonist [125I]iodopindolol, averaged approximately 10,700 beta AR/cell (400 fmol/mg membrane protein). Greater than 85% of the receptors were of the beta 2 subtype as determined by competitive antagonist displacement of iodopindolol by selective beta 1- (betaxolol) and beta 2- (ICI 118,551) antagonists. cAMP synthesis was stimulated with isoproterenol, PGE2, and forskolin in a time- and concentration-dependent fashion. Preincubation of epithelial cells for 30 min with either isoproterenol (10 microM) or the peptide inflammatory mediator, bradykinin (100 microM), markedly depressed subsequent isoproterenol-stimulated cAMP synthesis. Isoproterenol-induced beta AR-AC desensitization appeared to be homologous since cAMP responses to PGE2 and forskolin, a direct activator of adenylyl cyclase, were not reduced. The effect of bradykinin on isoproterenol-stimulated cAMP response was mimicked by preincubation with either dioctanoyl glyceride or phorbol myristate acetate, activators of protein kinase C.(ABSTRACT TRUNCATED AT 250 WORDS)

A technique to harvest viable tracheobronchial epithelial cells from living human donors.

The ability to obtain airway epithelial cells from the lower respiratory tract in living human donors will facilitate study of the biologic properties of these cells. We report our experience harvesting tracheobronchial epithelial cells from living human donors by brushing the mucosal surface of the trachea and mainstem bronchi. Cells were obtained on 21 occasions from 18 healthy adult subjects under direct vision with a brush-tipped catheter during fiberoptic bronchoscopy. The average number of cells harvested per subject was 14 +/- 2 x 10(6), and cell viability determined by trypan blue exclusion averaged 36 +/- 4%. Of note, cell viability was significantly enhanced when lidocaine was confined to the nares. Lidocaine was also observed to diminish cell viability in vitro in a dose-dependent fashion. Morphologic and staining properties were used to classify harvested cells into the three major cell types present in the mucosa (i.e., ciliated, secretory, and basal cells). All three subtypes were obtained. The percentage of ciliated, secretory, and basal-like cells was 24 +/- 2%, 11 +/- 1%, 29 +/- 1%, respectively, while the remaining 36% were difficult to type. In one subject in whom brushing was performed on three occasions over a 7-wk period, the percentage of each of the three subtypes was similar across procedures. Harvested cells could be successfully placed in primary culture with a plating efficiency of 50 to 60% and could be subcultured for up to seven passages. Acutely dissociated cells could be used to study the beta-adrenergic receptor adenylyl cyclase system since they produced cAMP in response to isoproterenol.(ABSTRACT TRUNCATED AT 250 WORDS)