Neural dynamics of visual awareness investigated by means of Fast Optical Imaging and EEG

The search for the Neural Correlate of Consciousness (NCC, Koch, 2004) is one of the unresolved problems of cognitive neuroscience. Although great efforts have been made to seek to answer this fundamental question, theories about the neural basis of consciousness provide different and competing answers. The heterogeneity of the NCCs interpretations could be due to a methodological gap since so far studies trying to unveil the neural correlates of visual awareness have employed techniques that can reach a high level of resolution only in one dimension (i.e., space or time) resulting to be inadequate to investigate the spatio-temporal dynamics related to conscious vision. The following studies aim to elucidate the controversial search for the neural correlates of visual awareness, by proposing innovative and cutting-edge approaches that allow to move beyond these issues. In the first study, availing of EEG and EROS (Event-Related Optical Signal) techniques we seek to unravel the spatio-temporal dynamics occurring when a visual stimulus enters consciousness. To do so, participants’ brain activity is recorded during the performance of a discrimination task by means of EEG and EROS in separate sessions. EEG allows to investigate the electrophysiological correlates of visual awareness and to identify their exact timing, while EROS permits to disentangle which brain regions and in what order of activation are involved when the stimulus is reported as consciously perceived. Results revealed that when the stimulus entered the consciousness, it elicited a sustained activation in LOC, suggesting that this brain region could represent a reliable neural correlate of consciousness. Interestingly, this sustained activation occurred within the temporal window of VAN (Visual Awareness Negativity), corroborating the idea that LOC could serve as the cortical generator of VAN, which is typically considered a reliable marker of conscious vision. In the second study, EEG signal was decomposed into maximally independent components by means of ICA (Independent Component Analysis) in order to unveil the cortical generators and the time-courses of independent neural sources that significantly contribute to the ERP correlates of visual awareness (i.e., Visual Awareness Negativity and Late Positivity). It emerged that the neural sources of VAN seem to be localized in posterior brain regions, including occipital and temporal cortex, while LP seems to reflect a combination of multiple sources spread over frontal, parietal and occipito-temporal cortex. Overall, the present results provide innovative insights into the search for the neural correlates of visual awareness

Multiple independent components contribute to event-related potential correlates of conscious vision

Research has revealed two major event-related potential (ERP) markers of visual awareness: the earlier Visual Awareness Negativity (VAN, around 150-250 ms after stimulus onset), and the following Late Positivity (LP, around 300-500 ms after stimulus onset). Understanding the neural sources that give rise to VAN and LP is important in order to understand what kind of neural processes underlie conscious visual perception. Although the ERPs afford high temporal resolution, their spatial resolution is limited because multiple separate neural sources sum up at the scalp level. In the present study, we sought to characterize the locations and time-courses of independent neural sources underlying the ERP correlates of visual awareness by means of Independent Component Analysis (ICA). ICA allows identifying and localizing the temporal dynamics of different neural sources that contribute to the ERP correlates of conscious perception. The present results show that the cortical sources of VAN are localized to posterior areas including occipital and temporal cortex, while LP reflects a combination of multiple sources distributed among frontal, parietal and occipito-temporal cortex. Our findings suggest that conscious vision correlates with dynamically changing neural sources, developing in part in "accumulative fashion": consciousness-related activity initially arises in few early sources and, subsequently, additional sources are engaged as a function of time. The results further suggest that even early latency neural sources that correlate with conscious perception may also associate with action-related processes

Effects of Cupral® on the formation and persistence of microbial biofilms in vitro

Introduction: endodontic biofilm is a microbial community, enclosed in a polymeric matrix of polysaccharide origin where are frequently found pathogenic microorganisms, such as Gram+, Gram- and opportunistic fungi, belonging to Candida spp, responsible for several endodontic pathologies. As clinical importance is the fact that biofilm is extremely resistant to common intra-canal irrigants, antimicrobial drugs and host immune defenses. The aim of this in vitro study was to evaluate the efficacy of Cupral® on planktonic forms of some pathogens, as well as to assess its ability to prevent and affect the formation/persistence of microbial biofilms. Materials and Methods: ATCC strains of S. aureus, P. aeruginosa and C. albicans were exposed to various concentrations of Cupral® (an antiseptic compound based on calcium and copper hydroxide, used in endodoncy) to investigate its antimicrobial efficacy. This activity has been evaluated in terms of microbial growth and cellular doubling time (optical density, colony forming units and doubling time assays), inhibition/persistence (crystal violet staining), viability of microbial cells embedded in the biofilms (live/dead stain) and pyoverdine production (fluorimetric assay). Finally, the morphology of Cupral®-treated biofilms was investigated by optical/confocal microscopy analysis. Results: the addition of Cupral® to microbial cultures, influences, in a significantly and dose-dependent manner, the doubling time and growth of microbial cultures. Cupral® antimicrobial activity was also assessed on biofilms formation and persistence with meaningful decreases of residual biomass (observed reductions of 47-94% for S. aureus, 28-95% for P. aeruginosa and 27-75 % for C. albicans). Cupral®-treated biofilms analyzed by optical and confocal microscopy revealed loss of typical sessile structure, with few scattered microbial cells and a reduced thickness. Finally, the addition of Cupral® reduced both the number of embedded alive cells in the biofilms and the levels of pyoverdine in the culture supernatants. Discussion and Conclusions: this pilot in vitro study provided the first evidences on Cupral® efficacy against microbial biofilms. The wide range of action (vs Gram+, Gram- and fungi) of Cupral® strongly suggests its use as compound in the prevention and treatment of main oral biofilm-associated infections

Beyond primary visual cortex: the leading role of lateral occipital complex in early conscious visual processing

The study of the neural substrates that serve conscious vision is one of the unsolved questions of cognitive neuroscience. So far, consciousness literature has endeavoured to disentangle which brain areas and in what order are involved in giving rise to visual awareness, but the problem of consciousness still remains unsolved. Availing of two different but complementary sources of data (i.e., Fast Optical Imaging and EEG), we sought to unravel the neural dynamics responsible for the emergence of a conscious visual experience. Our results revealed that conscious vision is characterized by a significant increase of activation in extra-striate visual areas, specifically in the Lateral Occipital Complex (LOC), and that, more interestingly, such activity occurred in the temporal window of the ERP component commonly thought to represent the electrophysiological signature of visual awareness, i.e., the Visual Awareness Negativity (VAN). Furthermore, Granger causality analysis, performed to further investigate the flow of activity occurring in the investigated areas, unveiled that neural processes relating to conscious perception mainly originated in LOC and subsequently spread towards visual and motor areas. In general, the results of the present study seem to advocate for an early contribution of LOC in conscious vision, thus suggesting that it could represent a reliable neural correlate of visual awareness. Conversely, striate visual areas, showing awareness-related activity only in later stages of stimulus processing, could be part of the cascade of neural events following awareness emergence

EDTA and Taurolidine affect Pseudomonas aeruginosa virulence in vitro: impairment of secretory profile and biofilm production onto peritoneal dialysis catheters

Introduction: peritoneal catheter-associated biofilm infection is reported to be the main cause of refractory peritonitis in peritoneal dialysis patients. The application of antimicrobial lock therapy, based on results on central venous catheters, may be a promising option also for treatment of biofilm-harboring peritoneal catheters. In this study, we investigated the effects of two lock solutions, EDTA and Taurolidine, on an “in-vitro” model of Pseudomonas aeruginosa biofilm-related peritoneal catheter infection. Materials and Methods: silicon peritoneal catheters were incubated for 24 h with a bioluminescent strain of P. aeruginosa. After washing, serial concentrations of Taurolidine (0.5, 0.25 and 0.125 %) and EDTA (2.5, 0.75 and 0.25 %), either alone or in combination, were applied for 24 h, once or twice, onto the contaminated catheters and then P. aeruginosa viability/persistence was evaluated in real time up to 120 h, by a Fluoroskan reader. Moreover, on selected supernatants from biofilm treated or not with EDTA and/or Taurolidine, High-Performance Liquid Chromatography-Mass (HPLC) analysis was performed to measure phenazine and pyocianine production. Results: Taurolidine alone or in combination with EDTA caused a significant decrease of bacterial load and biofilm persistence onto the contaminated catheters. The lock solution treatment did not lead to the sterilization of the devices; yet, it resulted in a substantial destructuration of the peritoneal catheter-associated P. aeruginosa biofilm. Moreover, HPLC analysis showed that the treatment of biofilm-harboring catheters with EDTA and Taurolidine deeply affected the secretion of some key virulence-related molecules by P. aeruginosa, such as phenazines and pyocianines. Discussion and conclusions: EDTA and Taurolidine affect the formation and persistence of P. aeruginosa biofilm onto peritoneal catheters; moreover, also the secretion of P. aeruginosa virulence factors is profoundly compromised. Future studies are needed to establish whether such lock solutions can be used to render peritoneal catheter-related infections more susceptible to antibiotic treatment, thus avoiding/reducing the onset of the antibiotic resistance phenomena

Antibacterial Effects of MicroRepair®BIOMA-Based Toothpaste and Chewing Gum on Orthodontic Elastics Contaminated In Vitro with Saliva from Healthy Donors: A Pilot Study

Several new products with innovative formulations are being proposed to facilitate oral care. Here, we evaluated the effects of a commercially available product, a toothpaste and chewing gum named Biorepair Peribioma, on oral microorganisms of healthy subjects. Saliva from six volunteers was collected during 20 min of mastication of a traditional gum (gum A) and the Biorepair Peribioma gum (gum P). Orthodontic elastics (OE) were in vitro contaminated with salivary samples, both A and P, and subsequently exposed or not to a Biorepair Peribioma toothpaste-conditioned supernatant (Tp-SUP). The salivary samples were tested for initial microbial load; hence, the contaminated OE were assessed for microbial growth, adhesion, biofilm formation and persistence; moreover, species identification was assessed. We found that the salivary samples A and P had similar microbial load; upon contamination, microbial adhesion onto the OE was detected to a lower extent when using saliva P with respect to saliva A. Microbial growth and biofilm formation, assessed at 24 h, remained at lower levels in OE exposed to saliva P, compared to saliva A. This difference between salivary samples A and P was confirmed when measuring biofilm persistence (48 h), while it was lost in terms of microbial re-growth (48 h). The Tp-SUP treatment drastically affected microbial load at 24 h and strongly impaired biofilm formation/persistence, in OE exposed to both salivary samples A and P. Finally, such treatment resulted in consistent overgrowth of Lactobacilli, bacterial species originally present both in the Biorepair Peribioma toothpaste and gum. In conclusion, by an in vitro pilot study, we show that the Biorepair Peribioma toothpaste and gum deeply affect oral microorganisms’ behavior, drastically impairing their ability to contaminate and produce plaque onto orthodontic devices

Spatiotemporal dynamics of attentional orienting and reorienting revealed by fast optical imaging in occipital and parietal cortices

The mechanisms of visuospatial attention are mediated by two distinct fronto-parietal networks: a bilateral dorsal network (DAN), involved in the voluntary orientation of visuospatial attention, and a ventral network (VAN), lateralized to the right hemisphere, involved in the reorienting of attention to unexpected, but relevant, stimuli. The present study consisted of two aims: 1) characterize the spatio-temporal dynamics of attention and 2) examine the predictive interactions between and within the two attention systems along with visual areas, by using fast optical imaging combined with Granger causality. Data were collected from young healthy participants performing a discrimination task in a Posner-like paradigm. Functional analyses revealed bilateral dorsal parietal (i.e. dorsal regions included in the DAN) and visual recruitment during orienting, highlighting a recursive predictive interplay between specific dorsal parietal regions and visual cortex. Moreover, we found that both attention networks are active during reorienting, together with visual cortex, highlighting a mutual interaction among dorsal and visual areas, which, in turn, predicts subsequent ventral activity. For attentional reorienting our findings indicate that dorsal and visual areas encode disengagement of attention from the attended location and trigger reorientation to the unexpected location. Ventral network activity could instead reflect post-perceptual maintenance of the internal model to generate and keep updated task-related expectations

Impact of Candida albicans hyphal wall protein 1 (HWP1) genotype on biofilm production and fungal susceptibility to microglial cells

The hyphal wall protein 1 (HWP1) gene of Candida albicans encodes for a fungal cell wall protein, required for hyphal development and yeast adhesion to epithelial cells; yet, its role in pathogenesis remains largely unknown. In the present study, we analyzed two C. albicans laboratory strains, the DAY286 (HWP1/HWP1) and the null mutant FJS24 (hwp1/hwp1) and six clinical isolates [3 harbouring the homozygous HWP1 gene (HWP1/HWP1) and 3 the heterologous gene (HWP1/hwp1)]. Biofilm production, fungal HWP1 mRNA levels and ultrastructural morphology were investigated; also, the susceptibility of these strains to microglial cells was evaluated, in terms of fungal damage and immune cell-mediated secretory response. When comparing the two laboratory strains, biofilm was produced to a similar extent independently on the genetic background, while the susceptibility to microglial cell-mediated damage was higher in the hwp1/hwp1 mutant than in the HWP1/HWP1 counterpart. Also, transmission electron microscopy revealed differences between the two in terms of abundance in surface adhesin-like structures, fungal cell wall shape and intracellular granules. When comparing the clinical isolates grouped according to their HWP1 genotype, reduced biofilm production and increased susceptibility to microglial cell-mediated damage occurred in the HWP1/hwp1 isolates with respect to the HWP1/HWP1 counterparts; furthermore, upon exposure to microglial cells, the HWP1/HWP1 isolates, but not the HWP1/hwp1 counterpart, showed enhanced HWP1 mRNA levels. Finally, both laboratory and clinical isolates exhibited reduced ability to stimulate TNFα and nitric oxide production by microglial cells in the case of heterozygous or null mutant HWP1 genotype. Overall, these data indicate that C. albicans HWP1 genotype influences pathogen morphological structure as well as its interaction with microglial cells, while fungal biofilm production results unaffected, thus arguing on its role as virulence factor that directly affects host mediated defences

Real-time monitoring of Pseudomonas aeruginosa biofilm formation on endotracheal tubes in vitro

BACKGROUND: Pseudomonas aeruginosa is an opportunistic bacterial pathogen responsible for both acute and chronic infections in humans. In particular, its ability to form biofilm, on biotic and abiotic surfaces, makes it particularly resistant to host's immune defenses and current antibiotic therapies as well. Innovative antimicrobial materials, like hydrogel, silver salts or nanoparticles have been used to cover new generation catheters with promising results. Nevertheless, biofilm remains a major health problem. For instance, biofilm produced onto endotracheal tubes (ETT) of ventilated patients plays a relevant role in the onset of ventilation-associated pneumonia. Most of our knowledge on Pseudomonas aeruginosa biofilm derives from in vitro studies carried out on abiotic surfaces, such as polystyrene microplates or plastic materials used for ETT manufacturing. However, these approaches often provide underestimated results since other parameters, in addition to bacterial features (i.e. shape and material composition of ETT) might strongly influence biofilm formation. RESULTS: We used an already established biofilm development assay on medically-relevant foreign devices (CVC catheters) by a stably transformed bioluminescent (BLI)-Pseudomonas aeruginosa strain, in order to follow up biofilm formation on ETT by bioluminescence detection. Our results demonstrated that it is possible: i) to monitor BLI-Pseudomonas aeruginosa biofilm development on ETT pieces in real-time, ii) to evaluate the three-dimensional structure of biofilm directly on ETT, iii) to assess metabolic behavior and the production of microbial virulence traits of bacteria embedded on ETT-biofilm. CONCLUSIONS: Overall, we were able to standardize a rapid and easy-to-perform in vitro model for real-time monitoring Pseudomonas aeruginosa biofilm formation directly onto ETT pieces, taking into account not only microbial factors, but also ETT shape and material. Our study provides a rapid method for future screening and validation of novel antimicrobial drugs as well as for the evaluation of novel biomaterials employed in the production of new classes of ETT

The β-lactamase Inhibitor Boronic Acid SM23 as a new anti-Pseudomonas aeruginosa Biofilm Compound

BACKGROUND: Pseudomonas aeruginosa is a Gram-negative nosocomial pathogen, often causative agent of severe device-related infections, given its great ability to produce biofilm. P. aeruginosa finely regulates the expression of numerous virulence factors, including biofilm production, by Quorum Sensing (QS), an intercellular communication mechanism used by many bacteria. Biofilm formation can enhance bacterial resistance to antimicrobial agents due to a decreased penetration of the antibiotic and a reduced rate of bacterial cells in biofilm. Selective inhibition of biofilm formation may thus represent a novel promising strategy to overcome the well-known and widespread drug-resistance of P. aeruginosa. METHODS: In this study, we investigated the effects of SM23, a boronic acid derivate specifically designed as β-lactamase inhibitor, on biofilm formation and production of virulence factors, using the P. aeruginosa bioluminescent strain P1242. RESULTS: Our results indicated that SM23: a) inhibited the development of biofilm and the production of the virulence factors pyoverdine, elastase and pyocyanin, without affecting bacterial growth; b) decreased the levels of P. aeruginosa QS-related Autoinducers molecules 3-oxo-C12-HSL and C4-HSL by dampened lasR/lasI system gene expression in the biofilm; c) failed to bind to bacterial cells that had been preincubated with P. aeruginosa-conditioned medium; d) reduced both biofilm formation and pyoverdine production by P. aeruginosa onto endotracheal tubes, as assessed by a new in vitro model, closely mimicking the clinical settings. CONCLUSION: Taken together, our results indicate that, besides inhibiting β-lactamase, SM23 can also act as potent inhibitor of P. aeruginosa biofilm, suggesting that it may have a potential application in the prevention and treatment of biofilm-associated P. aeruginosa infections