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In 1911 Eugen Bleuler (Bleuler, 1911) postulated that schizophrenia was a disorder resulting from inability to properly integrate mental processes. Around the same time, Carl Wernicke (Wernicke, 1894) proposed that psychosis might result from disruption of white matter tracts. Both of these statements can be considered early cornerstones of modern connectivity hypotheses developed towards the end of the twentieth century by such researchers as Karl Friston (1998) and Nancy Andreansen (1998). In the current work, the hypothesis that schizophrenia, rather than being a disorder or either anatomical or functional connectivity, is a disorder where both of these processes interact and influence the clinical presentation of patients, is examined. This is achieved through a detailed examination of a sample of chronic schizophrenia patients using a combination of functional and anatomical Magnetic Resonance Imaging techniques. The relationship of these measures to clinical symptoms is also explored. In the first study, anatomical connectivity at the whole-brain level is examined using Diffusion Tensor Imaging. The results of the study contribute to the previous literature on auditory hallucinations in schizophrenia and provide the first direct correlation between increased anatomical connectivity and increased severity of psychotic symptoms. The second study provides a thorough examination of the interhemispheric connectivity. This is achieved through a detailed examination of the corpus callosum using a combination of diffusivity and volumetric values. This is the first study to date where several anatomical methods are used in one sample. The results illustrate the importance of using different techniques to accurately characterize anatomical abnormalities observed in schizophrenia. In addition, contrary to previous research reports, the results of the current study imply that only specific sub-sections of the corpus callosum are affected by anatomical abnormalities. The pattern of these changes may influence clinical presentation of patients. Finally, functional connectivity at the whole-brain level is examined during resting-state using Independent Component Analysis. Similarly to the results of the anatomical examinations, it provides further supporting evidence that the pattern of disturbances observed in the current sample of schizophrenia patients examined herein reflects a combination of hypo- and hyperconnectivity. Moreover, the study further validates resting-state functional Magnetic Resonance Imaging as a reliable tool for examining functional abnormalities in schizophrenia.
Visual information is processed hierarchically in the human visual system. Early during processing basic features are analysed separately while at later stages of processing, they are integrated into a unified percept. By investigating a basic visual feature and following its integration at different levels of processing one can identify specific patterns. In certain visual impairments, these patterns can function defectively and their detailed study can clarify the cause of the visual deficit. Here we investigate orientation as a basic feature and use a property of the visual system called adaptation. Adaptation occurs as a decrease in the level of neural activity during repetitive presentation of the same stimulus. Psychophysical studies have shown that adaptation transfers interocularly, meaning that if only one eye is adapted the other eye shows also adaptation effects. Our aim was to investigate interocular transfer by means of functional magnetic resonance imaging (fMRI). Even though adaptation was demonstrated in the fMRI environment, the interocular transfer was never investigated in such a setup. First, we developed a method to measure interocular transfer of adaptation to gratings with fMRI. We then went further to test it in various groups of subjects. In normally sighted humans interocular transfer was present both in early (striate) as well as later visual areas (extrastriate). In subjects with impaired stereovision (with or without normal visual acuity) interocular transfer was absent in the investigated regions. Detailed analysis of the recorded differences between subjects with and subjects without stereovision was performed. The results of this analysis are presented in detail in this book. These results suggest that the neuronal mechanisms involved in the interocular transfer of pattern adaptation share, at least in part, the neural circuitry underlying binocular functions and stereopsis. We conclude that fMRI adaptation can be used for the assessment of cortical binocularity in humans with normal and impaired stereopsis. Further investigations are needed to address more subtle aspects of the lack of interocular transfer. Towards this purpose, through a fourth experiment we propose further directions that might shed more light on the issue of stereovision and its clinical implications. We show that carefully tuned variations in our experimental procedure might reveal other aspects of binocularity in the human visual system. We believe that the method we developed, apart from the interesting results shown here, has a high potential to be further used for other research questions. Following the above summarized ideas, the thesis comprises of three parts (chapters). The first chapter provides the main theoretical backgrounds of the visual system and of the MRI imaging technique, chapter two describes the experimental procedures while the results and their detailed discussion are detailed in chapter three.
Background and objectives: Constrictive pericarditis (CP) is the result of a spectrum of primary cardiac and non-cardiac conditions. Little data exists on the cause-specific survival after pericardiectomy in the modern era. The impact of pericardial calcification (CA) on survival is unclear. We sought to determine the association of etiology of CP, CA and other clinical variables with long-term survival after pericardiectomy. Methods: We analyzed the records of 163 patients who underwent pericardiectomy for CP over a 24-year period at a single center. The diagnosis of CP was established by surgical report. Vital status was obtained by the Social Security Death Index. The Kaplan Meier method was used to estimate overall survival and survival by etiology group. Cox proportional hazards regression analysis was performed to assess the effect of various causes for CP on longterm survival while adjusting for age. Results: The etiology of CP was idiopathic in 75 patients (46%), prior cardiac surgery in 60 (37%), radiation treatment in 15 (9%) and miscellaneous in 13 patients (8%). Vital status was obtained in 160 patients (98%). Median follow-up was 6.9 years (range: 0.8 to 24.5 years). Perioperative mortality for all patients was 6%. Idiopathic CP had the best prognosis (7 year survival: 88%, 95% confidence interval [CI] 76% to 94%) followed by postsurgical (66%, 95% CI 52% to 78%) and postradiation CP (27%, 95% CI 9% to 58%). In bootstrap-validated proportional hazards analyses, predictors of poor survival were prior radiation, worse renal function, higher pulmonary artery pressure (PAP), abnormal left ventricular (LV) systolic function, lower serum sodium level, and older age. Pericardial calcification had no impact on survival. Conclusion: Long-term survival after pericardiectomy for CP is determined by the underlying etiology of constriction, LV systolic function, renal function, serum sodium, and PAP. Patients with postsurgical as well as postradiation CP have a survival inferior to patients with idiopathic CP. Perioperative Mortality is low. The relatively good survival after pericardiectomy in patients with idiopathic CP emphasizes the safety of pericardiectomy in this group.
The µ-opioid receptor is the primary target structure of most opioid analgesics and thus responsible for the predominant part of their wanted and unwanted effects. Carriers of the frequent genetic µ-opioid receptor variant N40D (allelic frequency 8.2 - 17 %), coded by the single nucleotide polymorphism A>G at position 118 of the µ-opioid receptor coding gene OPRM1 (OPRM1 118A>G SNP), suffer from a decreased opioid potency and from a higher need of opioid analgesics to reach adequate analgesia. The aim of the present work was to identify the mechanism by which the OPRM1 118A>G SNP decreases the opioid potency and to quantify its effects on the analgesic potency and therapeutic range of opioid analgesics.
To elucidate the consequences of the OPRM1 118A>G SNP for the effects of opioid analgesics, brain regions of healthy homozygous carriers of the OPRM1 118A>G SNP were identified by means of functional magnetic resonace imaging (fMRI), where the variant alters the response to opioid analgesics after painful stimulation. Afterwards, the µ-opioid receptor function was analyzed on a molecular level in post mortem samples of these brain regions. Finally, the consequences of the OPRM1 118A>G SNP for the analgesic and respiratory depressive effects of opioids were quantified in healthy carriers and non-carriers of OPRM1 118A>G SNP by means of experimental pain- and respiratory depression-models.
To identify pain processing brain regions, where the variant alters the response to opioid analgesics after painful stimulation, we investigated the effects of different alfentanil concentration levels (0, 25, 50 and 75 ng/ml) on pain-related brain activation achieved by short pulses (300 msec) of gaseous CO2 (66% v/v) delivered to the nasal mucosa using a 3.0 T magnetic head scanner in 16 non-carriers and nine homozygous carriers of the µ-opioid receptor gene variant OPRM1 118A>G. In brain regions associated with the processing of the sensory dimension of pain (pain intensity), such as the primary and secondary somatosensory cortices and the posterior insular cortex, the activation decreased linearly in relation to alfentanil concentrations, which was significantly less pronounced in OPRM1 118G carriers. In contrast, in brain regions known to process the affective dimension of pain (emotional dimension), such as the parahippocampal gyrus, amygdala and anterior insula, the pain-related activation disappeared already at the lowest alfentanil dose, without genotype differences.
Subsequently, we investigated the µ-opioid receptor-expression ([3H]-DAMGO saturation experiments, OPRM1 mRNA analysis by means of RT-PCR), the µ-opioid receptor affinity ([3H]-DAMGO saturation and competition experiments) and µ-opioid receptor signaling ([35S]- GTPγS binding experiments) in post mortem samples of the human SII-region, as a cortical projection region coding for pain intensity, and lateral thalamus, as an important region for nociceptive transmission. Samples of 22 non-carriers, 21 heterozygous and three homozygous carriers of OPRM1 118A>G SNP were included into the analysis. The receptor expression and receptor affinity of both brain regions did not differ between non-carriers and carriers of the variant N40D. In non-carriers, the µ-opioid receptors of the SII-region activated the receptor bound G-protein more efficiently than those of the thalamus (factor 1.55-2.27). This regional difference was missing in heterozygous (factor 0.78-1.66) and homozygous (factor 0.66-1.15) carriers of the N40D variant indicating a reduced receptor-G-protein-coupling in the SII-region.
Finally, the consequences of the alteration of µ-opioid receptor function in carriers and noncarriers of the genetic variant was investigated using pain- and respiratory depression-models. Therefore, 10 healthy non-carriers, four heterozygous and six homozygous carriers of the µ- opioid receptor variant N40D received an infusion of four different concentrations of alfentanil (0, 33.33, 66.66 and 100 ng/ml). At each concentration level, analgesia was assessed by means of electrically (5 Hz sinus 0 to 20 mA) and chemically (200 ms gaseous CO2 pulses applied to the nasal mucosa) induced pain, and respiratory depression was quantified by means of hypercapnic challenge according to Read and recording of the breathing frequency. The results showed that depending on the used pain model, both heterozygous and homozygous carriers of the variant N40D needed 2 – 4 times higher alfentanil concentrations to achieve the same analgesia as non-carriers. This increase seems to be at least for homozygous carriers unproblematic, because to reach a comparable respiratory depression as non-carriers, they needed 10-12 times higher alfentanil concentrations.
The results of this work demonstrate that the µ-opioid receptor variant N40D causes a regionally limited reduction of the signal transduction efficiency of µ-opioid receptors in brain regions involved in pain processing. Thus, the painful activation of sensory brain regions coding for pain intensity is not sufficiently suppressed by opioid analgesics in carriers of the variant N40D. Due to the insufficient suppression in hetero- and homozygous carriers of the variant N40D, the concentration of opioids has to be increased by a factor 2 - 4, in order to achieve the same analgesia as in non-carriers. At the same time, the respiratory depressive effects are decreased to a greater extent in homozygous carriers of the N40D variant as they need a 10 - 12 times higher opioid concentration to suffer from the same degree of respiratory depression as non-carriers. Due to the increased therapeutic range of opioid analgesics, an increase of the opioid dose seems to be harmless, at least for homozygous carriers of the N40D variant.
The physiology of our most complex organ, the brain, is still not comprehensively understood. The brain basically serves the processing, storing and binding of external and internal information, and thereby generates amazing phenomena like the understanding of oneself as an individual entitiy. How exactly information is encoded and represented, how individual neurons or networks of neurons actually interact, is a gigantic puzzle, whose pieces were collected since many decades. Subject of scientific discussions are the basic spatiotemporal structures of neuronal representations. Suggestions and observations reach hereby from simple rate coding of individual neurons to synchronous activity of larger ensembles. To approach answers to these questions, our working group has used a combination of different recording techniques that allowed for the comparison of neuronal interactions on different spatial scales. We focused on prefrontal neuronal interactions during visual short-term memory. Herefore two rhesus monkeys had been trained to perform a visual short-term memory task. We measured and recorded their neuronal activity by means of a microelectrode matrix that could be inserted into the cortex via a closable chamber, which had been previously implanted above prefrontal cortex. The acquired signal was separated into two components: a high-frequency component, that represents the spiking output activity of few neurons in the vicinity of each electrode tip (multi-unit activity), and a low-frequency component, that results from dendritic input activity of larger neuronal assemblies (local field potential). From one of the experimental animals we also recorded mass signals of even larger neuronal populations by means of small silverball electrodes, that had been implated into the skull above prefrontal cortex (skull EEG) in the context of a pilot project. In the first subproject, we analyzed the selectivity of output signals with respect to the memorized stimulus and task performance. We compared selectivities of local recording sites (multi-unit activity) with the selectivities of patterns created by the combined activity of all recording sites, thus representing the activity of large and distributed ensembles. Local neuronal activity correlated with the course of the visual short-term memory task, but was not highly discriminative with respect to different visual stimuli. We could show that the population activity was significantly more specific. Concerning task performance, we obtained the same result, albeit less pronounced. Further analyses revealed that the patterns of distributed ensemble activity were only partly based on realtime coordination of neuronal activity, and in addition, did not remain stable across the time course of the short-term memory task. In the second subproject, we focused on the oscillatory behavior of the local field potential. After a time-frequency analysis, we studied different frequency bands concerning stimulus selectivity and task performance of the monkey. We hereby found significant modulations of oscillations in the beta- and gamma-frequency range, that correlated with different periods of the task. Especially for oscillations in beta- and low-gamma-range, we observed phase-locking of oscillations between different recording sites, which could play an important role as internal clock to coordinate spatially separate activity. Local high-gamma oscillations themselves seemed to be important for the maintenance of information. These results could be partly confirmed by mass signals of EEG. In sum, our results support the hypothesis that information is represented in the brain by means of concerted activity of spatially distributed neuronal ensembles. This activity again appears to be coordinated by oscillatory activity in beta- and low-gamma-frequency ranges. A deeper understanding of central nervous information processing could contribute to better treatment of diseases like Parkinson’s, Alzheimer’s as well as epilepsy, and neuropsychiatric disorders like schizophrenia.
Macrophages show a remarkable functional plasticity, which enables them to change their phenotype in response to environmental signals. They are key players during infection by initiating inflammation through the release of proinflammatory mediators. Furthermore, macrophages contribute to the resolution of inflammation by phagocytosis of apoptotic granulocytes. Phagocytosis of apoptotic cells (AC) induces an anti-inflammatory phenotype in macrophages and protects them against apoptosis. However, mechanistic details provoking these phenotype alterations are incompletely understood. Therefore, the aim of my Ph.D. thesis was to investigate the molecular basis of anti-inflammatory macrophage polarization. In the first part of my studies, I investigated the expression of heme oxygenase (HO)-1 in macrophages following treatment with supernatants from AC. HO-1 catalyzes the first and rate-limiting step of heme degradation and potentially bears anti-inflammatory as well as anti-apoptotic potential. I was able to show biphasic upregulation of HO-1 by AC supernatants. The first phase of HO-1 induction at 6 h required activation of p38 MAPK and was accomplished by the bioactive lipid sphingosine-1-phosphate (S1P) engaging S1P receptor 1 (S1P1). However, the second wave of HO-1 induction at 24 h was attributed to autocrine signaling of vascular endothelial growth factor (VEGF) A, whose expression was facilitated by S1P. The release of VEGFA from macrophages was STAT1-dependent, whereas VEGFA itself acted on the macrophage HO-1 promoter via STAT1/STAT3 heterodimer binding. Knockdown of HO-1 revealed its relevance in promoting enhanced expression of the anti-apoptotic proteins B cell leukemia/lymphoma-2 (Bcl-2) and B cell leukaemia/lymphoma-x long (Bcl-XL), as well as the anti-inflammatory adenosine receptor A2A. MHC II and indoleamine 2,3-dioxygenase expression were also affected by ACsupernanatants, but were not HO-1 dependent. Unexpectedly, S1P1 was also upregulated following treatment with AC supernatants. Thus, I considered whether S1P1 induction could specifically be mediated by alternative macrophage activating factors. The expression of S1P1 was enhanced in the presence of the alternative activation stimuli IL-4 as well as IL-10, whereas it was unchanged following incubations with LPS, interferon-g or S1P. My next aim was to investigate the expression of the different S1P receptor isoforms in macrophages following treatment with supernatants form AC. While the expressions of S1P1 as well as S1P3 were induced by exposure to supernatants from AC, S1P2 expression was unaffected. As S1P1/3 and S1P2 are conflictively involved in the regulation of cell migration, I asked for a correlation between increased S1P receptor expression and enhanced migration rate. Indeed, macrophages showed enhanced motility following treatment with supernatants form AC, which was inhibited in S1P1 knockout macrophages. In summary, my findings indicate that HO-1, which is induced by AC-derived S1P, is critically involved in macrophage polarization towards an alternatively activated macrophage phenotype. S1P1 seems to represent a central checkpoint during macrophage activation. On the one hand, S1P1 is induced by supernatants form AC and promotes migration of macrophages. On the other hand, it mediates the induction of HO-1, which is accompanied by antiinflammatory as well as anti-apoptotic signaling. Furthermore, my studies provide evidence that upregulation of HO-1 and S1P1 in macrophages may contribute to the resolution of inflammation by establishing an anti-inflammatory macrophage phenotype and provoking macrophage migration along the vascular S1P gradient out of an inflammatory environment into the lymph.
It has been shown that stem and progenitor cells are therapeutically effective after i.v application. Yet, many aspects regarding intracellular signaling pathways which are involved in the homing and local action of these cells still have to be elucidated. In this work, it was aimed to investigate the role of the small GTPase Rap1 in adhesion activation in Hematopoietic Stem and Progenitor Cells (HSC/HPC) and in Mesenchymal Stem Cells (MSC). The potential role of Rap1 was assessed in, mice which were homozygote negative for the expression of the Rap1a gene. Peripheral blood lymphocyte counts as well as numbers of HPCs in the blood were decreased in Rap1a-/- mice compared to wild-type controls. Additionally the adhesion capability of HPCs from Rap1a-/- to the endothelial ligand, Vascular Cell Adhesion Molecule – 1 under shear stress was decreased. The hematopoietic repopulation potential of Rap1a-/- HPC was however not decreased in a competitive bone marrow transplantation model, indicating that deficiency of Rap1a in HSC/HPC does not negatively affect their ability to interact with the bone marrow microenvironment. In contrast, the isolation of MSC was not possible from Rap1a-/- bone marrow, indicating an altered situation in the bone marrow niche through changed stromal cell behaviour. Instead, Rap1a+/- MSC could be isolated and showed an adhesion deficit under shear stress. In contrast, no differences were noted in their differentiation potential. In a mouse homing model, the overall ability of the Rap1a+/- MSC to home to different tissues was found preserved. Finally, in a murine subcutaneous carcinoma model, cells with an HPC phenotype were observed to be present in the tumor microenvironment, and it was shown that they home directly to tumors. Since HPC isolated from bone marrow were able to differentiate into cells with a pro-angiogenic phenotype in vitro, HPC may be of relevance for neovascularization, as tumor-infiltrating progenitor cells. The results of the study should contribute to the understanding of the regulation of progenitor cell homing behaviour in situations simulating cell therapy approaches in preclinical situations.
Dendritic cells are the sentinels between the innate and the adaptive immunity. They are professionals that capture invading pathogens, recognize specific microbial structures and induce naïve T lymphocytes to polarize into a specific T cell subset. To initiate the T cell polarization DCs secrete cytokines which are induced upon Toll-like receptor activation by microbial structures. The recognition of these structures and the discrimination between non-self and self structures by TLRs is fine tuned, but under defined circumstances deregulation of immune responses appears. Consequently, this can result in immune disorders such as autoimmunity, chronic inflammatory diseases or cancer. In this thesis the investigations are focused on the regulation of the IL-12 family members IL-12p70 and IL-23 in DCs. The objective was to investigate three different endogenous and exogenous factors that regulate IL-12p70 or IL-23. In the first part Selenium, an essential trace element and important factor in several metabolic pathways including the cellular redox status and reactive oxygen species (ROS) dependent signaling was applied as supplement in immature Langerhans cell culture. Because Selenium also plays a role in the immune system the TLR-induced IL-23 production of the DCs upon Selenium treatment was analyzed. In the immature Langerhans cell line XS-52 the strongest inducer of IL-23 was TLR4 ligand LPS. Furthermore increased levels of TLR4-induced IL-23 in cells treated with Selenium were detected in a concentration dependent manner. Whereas the IL-23 subunit p40 was upregulated upon Selenium treatment the second subunit p19 was completely unaffected. This effect was detected on mRNA and protein level. In addition, as expected, IFN-gamma inhibited the TLR4-induced IL-23 secretion of both, Selenium treated and untreated cells. In the second part of this thesis p47phox, an organizing protein of the NADPH oxidase was analyzed regarding its potential to regulate IL-12p70 and/or IL-23 secreted by different DC subtypes. Since it was demonstrated that p47phox deficiency is associated with enhanced autoimmunity and chronic inflammation we wanted to prove whether it has a function in addition to that within the NADPH oxidase. We found some hints that p47phox may be interact with proteins of the TLR signaling pathway and thus we hypothesized that p47phox may have a function for the regulation of TLR-mediated cytokine production in DCs. In several experiments with DCs from the spleen of different p47phox deficient mice we detected an increased production of TLR9-induced IL-12p70 compared to wild type cells. In contrast TLR4 stimulation with LPS displayed no significant differences between p47phox deficient and wild type cells. In spleen cells IL-23 was not detected. Confirming the results of this new negative feedback by p47phox on IL-12p70 rats, with a single nucleotide polymorphism in the p47phox gene, were investigated. Interestingly this polymorphism is located in the phosphorylation site of IRAK4, an important kinase in the TLR pathway. In rats with a methionine residue at this position in the p47phox protein enhanced IL-12p70 level were found, compared to the rats with threonine, which can be phosphorylated by IRAK4. All analyzed mice and rats have defects in the NADPH oxidase function due to a non functional p47phox protein which results in a defective ROS production. To determine whether the observed negative feedback mechanism is connected to the lack of ROS production experiments with gp91phox deficient mice, which also have a defective NADPH oxidase function, were performed. In several experiments the enhanced IL-12p70 production in cells from p47phox deficient mice could be confirmed, but no differences between gp91phox deficient and wild type mice have been observed. In further studies was found that the inhibition of the NADPH oxidase function did not alter the negative feedback on TLR9-induced IL-12p70 secretion by p47phox. Interestingly upon treatment with the inhibitor a feedback mechanism in wild type cells also after TLR4 stimulation was observed. Hence, blocking a ROS-dependent TLR4 pathway by the inhibitor uncovered the LPS induced ROS-independent pathway of the TLR4 signaling. These findings strongly approve a NADPH oxidase/ROS-independent function of p47phox in DCs. Because splenic DCs do not secrete IL-23, in vitro differentiated DCs from the bone marrow were investigated regarding the negative feedback mechanism. In DCs from p47phox deficient mice, differentiated with GM-CSF, the upregulation of IL-12p70 was confirmed, whereas Flt3-L cultured DCs did not display the negative feedback. In contrast to IL-12p70 no difference for the IL-23 production between wild type and p47phox deficient cells has been detected. Thus, we concluded that IL-23 production is not regulated by p47phox. IL-12p70 is the major cytokine in the Th1 polarization whereas IL-23 is important for the maintenance and survival of Th17 cells. To prove whether the regulation of IL-12p70 influences the T cell response immunization experiments closely resembling the classical DTH-like protocols were performed. Groups of p47phox deficient and wild type mice received either PBS, OVA alone or mixed with TLR9 ligand CpG2216 in IFA s.c. to activate and polarize naïve T cells towards Th1 or Th17 cells. After ten days isolated lymph node cells were incubated in an ELISA spot assay with or without OVA and the frequency of IFN-gamma and IL-17 producing T cells was quantified. In vitro recall of OVA immunization of wild type and p47phox deficient mice resulted in an increased IFN-gamma and IL-17 frequency in the p47phox deficient cells. The combination with CpG2216 as adjuvant and inducer of the 3rd signal enhanced the frequency of IFN-gamma and IL-17 producing T cells in wild type mice significantly. However, in p47phox deficient cells the IFN-gamma and IL-17 response, being already detectable without in vitro OVA re-stimulation, was strongly augmented upon OVA restimulation. These findings confirmed our in vitro data for IL-12p70. Hence, the data supports our hypothesis that the p47phox dependent regulation of IL-12p70 and the consequences for the T cell response is an important mechanism to prevent uncontrolled immune responses. In the last part of this thesis the immunomodulatory property of vitamin D3 on the IL-12p70 production of DCs was examined. Since it was shown that VD3 influences the differentiation and maturation of monocytes and DCs, splenic DCs from C57BL/6 and BALB/c mice were investigated regarding their IL-12p70 production after VD3 treatment. Spleen cells, stimulated with LPS or CpG2216, exhibited a decreased IL-12p70 production when treated with VD3 before stimulation phase. In contrast treatment with VD3 only during TLR stimulation had no influence on the IL-12p70 production. Since it was demonstrated that VD3 stimulates the expression of p47phox mRNA cells from p47phox deficient mice were also treated with VD3. In initial experiments only a slight inhibition of IL-12p70 has been detected in p47phox deficient cells compared to the wild type. In summary the thesis displays three different possibilities to influence the TLR-induced cytokine secretion of DCs, although with different intensities and specificities.
The peroxisome proliferator activated receptor gamma (PPARgamma) plays an eminent role during alternative activation of macrophages and resolution of inflammation. As an antiinflammatory signaling molecule, it seems likely that it is tightly regulated dependent on the state of the immune response. There is growing evidence that PPARgamma expression is reduced during inflammation, whereas molecular mechanisms are illdefined. Even though, its role in immunosuppression is getting more definite. Apoptotic cells (AC) provoke an active repression of pro-inflammatory responses inter alia by the inhibition of pro-inflammatory cytokine expression or attenuated generation of reactive oxygen species (ROS). The reduced formation of ROS was attributed to PPARgamma activation, while mechanisms behind the reduced cytokine expression remained unclear. Therefore, my Ph.D. thesis addressed the role of PPARgamma during inhibited cytokine synthesis in response to AC and the regulation of PPARgamma expression during an inflammatory response, which was initiated by lipopolysaccharide (LPS) exposure. In the first part of the thesis, I investigated the role of PPARgamma in coordinating the attenuation of pro-inflammatory cytokine expression in response to AC. Exposing murine RAW264.7 macrophages to AC prior to LPS-stimulation, reduced NFKB transactivation and lowered target gene expression of e.g. TNFalpha and IL-6 compared to controls. In macrophages over-expressing a dominant negative (d/n) mutant of PPARgamma, NFKB transactivation in response to LPS was restored, while using macrophages from myeloid lineage-specific conditional PPARgamma knock-out mice proved that PPARgamma transmitted the anti-inflammatory response delivered by AC. Domain analysis revealed that amino acids 32-250 are essential for inhibition of NFKB. Mutation of a SUMOylation (SUMO: small-ubiquitin related modifier) site in this region (K77R) and interfering SUMOylation by silencing the SUMO E3 ligase PIAS1 (protein inhibitor of activated Stat1) eliminated AC-provoked NFKB inhibition and concomitant TNFalpha expression. Chromatin-immunoprecipitation assays demonstrated that AC prevented the LPS-induced removal of nuclear receptor co-repressor (NCoR) from the KB response element within the TNFalpha promoter. I concluded that AC induce PPARgamma SUMOylation to attenuate the removal of NCoR, thereby blocking transactivation of NFKB. This contributes to an anti-inflammatory phenotype shift in macrophages in response to AC, by lowering pro-inflammatory cytokine production. The second part addressed molecular mechanisms responsible for reduced PPARgamma expression upon LPS exposure. PPARgamma gained considerable interest as a therapeutic target during chronic inflammatory diseases. Remarkably, the pathogenesis of diseases such as multiple sclerosis or Alzheimer’s disease is associated with impaired PPARgamma expression. Initiation of an inflammatory response by exposing primary human macrophages to LPS revealed a rapid decline of PPARgamma1 expression. PPARgamma1 mRNA decrease was prevented by inhibition of NFKB and also after pre-treatment with the PPARgamma agonist rosiglitazone, suggesting a NFKB-dependent pathway, because activated PPARgamma is known to inhibit NFKB transactivation. Since promoter activities were not affected by LPS, I focused on mRNA stability and noticed a decreased PPARgamma1 mRNA half-life. RNA stability is often regulated via 3’ untranslated regions (UTRs). Therefore, I analyzed the impact of the PPARgamma-3’UTR by luciferase assays. LPS significantly reduced luciferase activity of pGL3-PPARgamma-3’UTR, suggesting that PPARgamma1 mRNA is destabilized. Deletion of a potential miR-27a/b binding site within the 3’UTR completely restored luciferase activity. Moreover, inhibition of miR-27b, which was induced upon LPS-exposure, partially reversed PPARgamma1 mRNA decay, whereas the mature miR-27 mimicked the effect of LPS. MiR-27b was at least partially induced by NFKB, thus correlating with NFKB-dependent PPARgamma1 mRNA decrease. Since deletion of the miR-27 site also containing an AU-rich element (ARE) completely abrogated LPS-induced reduction but inhibition of miR-27b only partially restored PPARgamma1 mRNA expression, I suggested an additional implication of an ARE-binding protein. I provide evidence that LPS induces miR-27b, which in turn destabilizes PPARgamma1 mRNA. Understanding the molecular mechanism of PPARgamma mRNA destabilization, might help to rationalize inflammatory diseases associated with impaired PPARgamma expression. Even though, further experiments are needed to clarify the potential involvement of ARE-binding proteins.
Sepsis is caused by infection and often followed by an overwhelming inflammatory response. This can lead to shock, organ failure and even death. Each year approximately 60,000 people die in Germany due to sepsis. There is good evidence that sepsis is associated with failure of the hypothalamic-pituitary-adrenal-axis. In patients with sepsis, glucocorticoids (e.g. corticosterone, cortisol) released from adrenal glands play an essential role in preventing an excessive pro-inflammatory response. Adrenal insufficiency occurs in a large number of patients with septic shock and is associated with an increased mortality. In the innate immune system, Toll-like receptors (TLRs) play a crucial role in its onset by recognizing pathogenassociated molecules. It is well known that there are interactions between the immune and endocrine stress systems; glucocorticoids and TLRs regulate each other in a bi-directional way. Therefore, a coordinated response of the adrenal and immune system is of vital importance for survival during severe inflammation. This experimental study focuses on the role of TLR-2, TLR-4 and TLR-9 during adrenal stress. The results show that in mice, the absence of TLR-2 and TLR-4, but not TLR-9 leads to altered adrenal morphology, relating to size and cellular structure. However, this alteration does not appear to compromise the phenotype of TLR knock-out mice. Mice deficient of TLR-2, 4 and 9 are not able to respond adequately to inflammatory stress induced by their potential ligands lipopolysaccharide (LPS), lipoteichoic acid (LTA) or cytidine phosphate guanosine-oligodeoxynucleotides (CpG-ODN). This impaired adrenal stress response appears to be associated with a decrease in systemic and intra-adrenal cytokine expressions. Taken together, these results suggest that TLR-2, 4 and 9 are key players in the immuno-endocrine response during inflammation and SIRS. In conclusion, TLRs play a crucial role in the immune-adrenal crosstalk. This close functional relationship needs to be considered in the treatment of inflammatory diseases where an intact adrenal stress response is required. Furthermore, TLR polymorphisms could contribute to the underlying mechanisms of impaired adrenal stress response in patients with bacterial sepsis
To date it is not clear at which stage of differentiation mature T cell leukaemia/lymphoma is initiated. Previous studies in our group showed that mature T cells are relatively resistant to transformation. We wanted to further investigate the transformation potential of NPM-ALK, p21SNFT and the viral oncoprotein Tax on mature T cells. First, we analyzed the effects on T cell growth in vitro after transducing human T cell lines with gammaretroviral vectors encoding these genes. No growth or proliferation promoting effect of all three genes was observed. In the second part of the project, we transduced murine, mature T cells and/or haematopoietic stem cells (HPCs/HSCs) and transplanted these cells into Rag-1 deficient recipients. All mice transplanted with NPM-ALK transduced monoclonal mature T cells (OT-1) developed leukaemia/lymphoma. In contrast, only few NPM-ALK transduced polyclonal T cell and HPC/HSC transplanted mice developed leukaemia/lymphoma. From the p21SNFT group, only two mice transplanted with transduced OT-1 T cells developed leukaemia/lymphoma, which showed high eGFP and interestingly CD19 expression. No malignancies were observed in Tax transplanted animals so far. Furthermore, the recipients do not show any eGFP marking in the periphery. In conclusion, our results show that compared to polyclonal T cells, monoclonal T cells are transformable after gammaretroviral transfer of NPM-ALK and p21SNFT.
Clinical application of transcranial Doppler for detection of cerebral emboli during cardiac surgery
(2010)
Objective: Neurologic injury is one of the most damaging complications for cardiac surgery. How to decrease neurologic impairment by improving perioperative monitoring remains a challenge for both cardiac surgeons and anesthetists. For this reason, transcranial doppler (TCD) has been widely used in cerebral monitoring during cardiac surgery. In this study, two experiments of clinical application of TCD for detection of cerebral emboli during cardiac surgery were to be done. One was “Solid and gaseous cerebral emboli during valvular surgery are significantly reduced with axillary artery cannulation”. The other was “Do intraoperative cerebral embolic signals differ between valvular surgery (VS) and CABG”. Methods: In experiment one, 20 valve and combined procedures with aortic cannulation (AoC group) were compared to 18 procedures with axillary cannulation (AxC group) in a prospective non-randomized study. In experiment two, 18 VS patients and 18 CABG patients were matched by extracorporeal circulation (ECC) time retrospectively. Intraoperative monitoring of both middle cerebral arteries was performed with TCD discriminating between solid and gaseous embolic signals (ES). Results: In experiment one, the AxC group had less solid ES than the AoC group (38±22 vs 55±25, P<0.05), but no significant difference was found in gaseous (501±271 vs 538±333, P>0.05) and total (539 ± 279 vs 593 ± 350, P>0.05) ES. The AxC group had less solid ES during arterial cannulation (2.1±1.5 vs 6.6±3.6, P<0.05) and during aortic cross-clamp time (4.4 ±3.1 vs 10.2 ± 5.1, P<0.05) than the AoC group. During ECC, gaseous ES was not significantly different between groups (398±210 vs 448±291, P>0.05). However, AxC showed less gaseous ES (85±68 vs 187±148, P<0.05) and less gaseous ES per minute (1.8±1.5 vs 4.5±3.2, P<0.05) during weaning off extracorporeal circulation than the AoC group. No significant difference in gaseous ES (313±163 vs 261±189, P>0.05) and gaseous ES per minute (3.1±2.2 vs 2.8±2.2, P>0.05) was found between groups from bypass start to aortic declamping. No neurologic complications occurred. In experiment two, no significant difference was found in solid (38±20 vs 40±26, P>0.05) or gaseous (457±263 vs 412±157, P>0.05) ES between the VS and CABG group during the whole recording time. During ECC, solid ES (20±10 vs 24±19, P>0.05) and gaseous ES (368±230 vs 317±157, P>0.05) were comparable between groups. Specifically, during weaning off ECC, the VS group had more gaseous ES/min (5.6±3.6 vs 3.1±1.2, P<0.05) than the CABG group. But this difference in gaseous ES/min was not significant during the period from bypass start to aortic declamping (2.5±1.8 vs 3.0±1.8, P>0.05). Conclusion: Cerebral embolization does occur during cardiac surgery. Through these two experiments, we demonstrated the feasibility and importance of clinical application of transcranial doppler for detection of cerebral emboli during cardiac surgery. Due to the diversity in clinical application of TCD, it is impossible to compare the number of ES between different research centers. More unified standards should be drawn in order to make wider clinical application possible. Up till now, no robust evidence shows the correlation between intraoperative ES and postoperative neurological impairment. The research on intraoperative ES and postoperative neurological impairment should rely on a complete concept.
Despite sensible guidelines for the use of opioid analgesics, respiratory depression remains a significant risk with a possibility of fatal outcomes. Clinicians need to find a balance of analgesia with manageable respiratory effects. The ampakine CX717 (Cortex Pharmaceuticals, Irvine, CA, USA), an allosteric enhancer of glutamate-stimulated AMPA receptor activation, has been shown to counteract opioid-induced respiratory depression in rats while preserving opioid-induced analgesia. Adopting a translational approach, we orally administered 1500 mg of CX717 to 16 male healthy volunteers in a placebo controlled double-blind study. Starting 100 min after CX717 or placebo intake, alfentanil was administered by computerized intravenous infusion targeting a plateau of effective alfentanil plasma concentrations of 100 ng/ml. One hour after start of opioid infusion, its effects were antagonized by intravenous injection of 1.6 mg of the classical opioid antidote naloxone. Respiration was quantified prior to drug administration (baseline), during alfentanil infusion and after naloxone administration by (i) counting the spontaneous respiratory frequency at rest and (ii) by employing hypercapnic challenge with CO2 rebreathing that assessed the expiratory volume at a carbon dioxide concentration in the breathable air of 55% (VE55). Pain was quantified at the same time points, immediately after assessment of respiratory parameters, by (i) measuring the tolerance to electrical stimuli (5 Hz sine increased by 0.2 mA/s from 0 to 20 mA and applied via two gold electrodes placed on the medial and lateral side of the mid-phalanx of the right middle finger) and (ii) by measuring the tolerance to heat (increased by 0.3°C/s from 32 to 52.5°C applied to a 3 x 3 cm2 skin area of the left volar forearm, after sensitization with 0.15 g capsaicin cream 0.1%). CX717 was tolerated by all subjects without side effects that would have required medical intervention. We observed that CX717 was approximately as effective as naloxone in reversing the opioid induced reduction of the respiratory frequency. Despite the presence of high plasma alfentanil concentrations, the respiratory frequency decreased only by 8.9 ± 22.4% when CX717 was pre-administered, which was comparable to the 7.0 ± 19.3% decrease observed after administration of naloxone. In contrast, after placebo pre-administration the respiratory rate decreased by 30.0 ± 21.3% (p=0.0054 for CX717 versus placebo). In agreement with this, periods of a very low respiratory frequency of <= 4 min-1 under alfentanil alone were shortened by ampakine pre-dosing by 52.9% (p=0.0182 for CX717 versus placebo). Furthermore, VE55 was decreased during alfentanil infusion by 55.9 ± 16.7% under placebo preadministration but only by 46.0 ± 18.1% under CX717 pre-administration (p=0.017 for CX717 versus placebo). Most importantly, in contrast to naloxone, CX717 had no effect on opioid induced analgesia. Alfentanil increased the pain tolerance to electrical stimuli by 68.7 ± 59.5% with placebo pre-administration. With CX717 pre-administration, the increase of the electrical pain tolerance was similar (54.6 ± 56.7%, p=0.1 for CX717 versus placebo). Similarly, alfentanil increased the heat pain tolerance threshold by 24.6 ± 10.0% with placebo pre-administration. Ampakine co-administration had also no effect on the increase of the heat pain tolerance of the capsaicin-sensitized skin (23.1 ± 8.3%, p=0.46 for CX717 versus placebo). The results of this study allow us to draw the conclusion, that opioid induced ventilatory depression can be selectively antagonized in humans by co-administering an ampakine. This is the first successful translation of a selective antagonism of opioidinduced respiratory depression from animal research into application in humans. Ampakines, namely CX717, thus are the first selective antidote for opioid-induced respiratory depression without loss of analgesia, available for the use in humans.
Summary: Information and communication is critical to the successful management of infectious diseases because an effective communication strategy prevents the surge of anxious patients who have not been genuinely exposed to the pathogen ('low risk patients') affecting medical infrastructures (1) and the future transmission of the infectious agent (2). Surge of low risk patients: The arrival of large numbers of low risk patients at hospitals following an infectious diseases emergency would be problematic for three main reasons. First, it would complicate the situation at hospitals receiving exposed patients, delaying the treatment of the acutely ill, creating difficulties of crowd control and tying up medical resources. Second, for the low risk patients themselves, attending hospital following an infectious disease emergency might increase their risk of exposure to the agent in question. Third, the needs of low risk patients may be poorly attended to at hospitals which are already overstretched dealing with medical casualties. Future transmission: Obtaining early information about symptoms and isolating infected patients is the most effective strategy to interrupt the chain of infection in the public in the absence of specific prophylaxis or treatment. Particularly at the beginning of an outbreak, these nonpharmaceutical interventions play an important role in enabling the early detection of signs or symptoms and in encouraging passengers to adopt appropriate preventive behaviour in order to limit the spread of the disease. This thesis includes two papers dealing with this problem: The first part is a systemic literature review of information needs following an infectious disease emergency (Anthrax, SARS, Pneumonic Plague). The key question was: what are the information needs of the public during an infectious disease emergency? The second part is an empirical investigation of information needs and communication strategies at the airport during the early stage of the Influenza Pandemic. The key question here was: what communication strategies help to meet the information needs and to enable the public to behave appropriately and responsibly? Conclusions: Evidence from the anthrax attacks in the United States suggested that a surge of low risk patients is by no means inevitable. Data from the SARS outbreak illustrated that if hospitals are seen as sources of contagion, many patients with non-bioterrorism related health care needs may delay seeking help. Finally, the events surrounding the Pneumonic Plague outbreak of 1994 in Surat, India, highlighted the need for the public to be kept adequately informed about an incident to avoid creating rumours. Clear, consistent and credible information is key to the successful management of infectious disease outbreaks. The results of the empirical investigation suggested that the desire for information is a reflection of current anxiety and does not mirror the objective scientific assessment of exposure. The airport study showed that perceived information needs were directly related to anxiety – the least anxious did not require any further information, the most anxious reported significant information needs concerning medical treatment, public health management and the assessment of the ongoing situation – irrespective of their actual exposure. A communication strategy only focussing on the 'real' exposed individuals neglects the information needs of those worrying about having contracted the virus and seeking medical attendance. Effective communication strategies should enable the general public to detect early signs or symptoms and provide them with behaviour advice to prevent the further transmission of the infectious agent. These include the provision of clear information about the incident, the symptoms and what to do to prevent the further transmission, detailed and regularly updated information in various media formats (telephone, internet, etc.) and rapid triage at hospital entrances to guide patients to the appropriate medical infrastructures. Relevance: These research findings could contribute to a shift in the organisational and communicative approach responding to infectious diseases outbreaks and could be considered relevant for future risk communication and policy decision making.
Atherosclerosis is accompanied by infiltration of macrophages to the intima of blood vessels. There they engulf oxLDL (oxidized low-density lipoproteins) and differentiate to foam cells. These cells are known as major promoters of atherosclerosis progression. In initial experiments I could demonstrate that foam cell formation caused a severe loss in the ability to produce IFNA (interferon A) in response to stimulation with the bacterial cell wall component LPS (lipopolysaccharide). Since IFNA is discussed to have anti-atherosclerotic potential and has the capability to induce immune tolerance, its inhibition in foam cells might promote the atherosclerotic process. For this reason the aim of my PhD project was to clarify the underlying molecular mechanisms that attenuate LPS-induced IFNA expression in foam cells. LPS activates TLR4 (Toll-like receptor 4) in macrophages. Downstream this receptor two distinct signaling pathways are activated, namely a MyD88 (myeloid differentiation primary response gene 88)-dependent and a TRIF (TIR-domain-containing adapter-inducing IFNA)-dependent one. Foam cell formation targeted the TRIF-dependent TLR4 signaling pathway, as seen by loss of IRF3 activation and IFNA expression inhibition, whereas MyD88-initiated NFBB (nuclear factor 'B-light-chain-enhancer' of activated B-cells) activation and subsequent TNF@ (tumor necrosis factor @) expression remained unaltered. The TRIF signaling cascade results in transactivation of the transcription factor IRF3 (interferon regulatory factor 3), the main activator of IFNA expression. This event demands IRF3 phosphorylation by TBK1 (TANK-binding kinase 1), whereas TBK1 needs to be recruited to TRAF3 (TNF receptor associated factor 3) by the scaffold protein TANK (TRAF family member-associated NFBB activator) for its activation. This work allowed to propose the following scheme: OxLDL utilizes SR-A1 (scavenger receptor A1) to activate IRAK4 (interleukin-1 receptor-associated kinase 4), IRAK1 and Pellino3. Active IRAK1 and Pellino3 associate with TRAF3 and Pellino3 promotes mono-ubiquitination of the adaptor molecule TANK. Mono-ubiquitination of TANK interrupts TBK1 recruitment to TRAF3 and thereby abrogates phosphorylation and transactivation of IRF3 as well as subsequent expression of IFNA. In this study I provide evidence for a negative regulatory role of Pellino3 for TRIF-dependent TLR4 signaling. This expands the current knowledge of the interplay between pathways downstream scavenger and Toll-like receptors. Due to the multifaceted roles of TLR4 signaling in pathology, the new TRIF-signaling inhibitor Pellino3 might be of importance as therapeutical target for disease intervention.
One of the earliest and most striking observations made about HIV is the extensive genetic variation that the virus has within individual hosts, particularly in the hypervariable regions of the env gene which is divided into 5 variable regions (V1-V5) and 5 more constant (C1-C5) regions. HIV evolves at any time over the course of an individual’s infection and infected individuals harbours a population of genetically related but non-identical viruses that are under constant change and ready to adapt to changes in their environment. These genetically heterogeneous populations of closely related genomes are called quasispecies [65]. Tuberculosis or tubercle forming disease is an acute and/or chronic bacterial infection that primarily attacks the lungs, but which may also affect the kidneys, bones, lymph nodes, and brain. The disease is caused by Mycobacterium tuberculosis (MTB), a slow growing rod-shaped, acid fast bacterium. It is transmitted from person to person through inhalation of bacteria-carrying air droplets. Worldwide, one person out of three is infected with Mycobacterium tuberculosis – two billion people in total. TB currently holds the seventh place in the global ranking of causes of death [73]. In 2008, there were an estimated 9.4 (range, 8.9–9.9 million) million incident cases (equivalent to 139 cases per 100 000 population) of TB globally [75]. A complex biological interplay occurs between M. tuberculosis and HIV in coinfected host that results in the worsening of both pathologies. HIV promotes progression of M. tuberculosis either by endogenous reactivation or exogenous reinfection [77, 78] and, the course of HIV-1 infection is accelerated subsequent to the development of TB [80]. Active TB is associated with an increase in intra-patient HIV-1 diversity both systemically and at the infected lung sites [64,122]. The sustainability or reversal of the HIV-1 quasispecies heterogeneity after TB treatment is not known. Tetanus toxoid vaccinated HIV-1 infected patients developed a transient increase in HIV-1 heterogeneity which was reversed after few weeks [121]. Emergence of a heterogeneous HIV-1 population within a patient may be one of the mechanisms to escape strong immune or drug pressure [65,128]. The existence of better fitting and/or immune escape HIV-variants can lead to an increase in HIV-1 replication [129,130]. It might be that TB favourably selected HIV-1 variants which are sources for consistent HIV-1 replication. Understanding the mechanisms underlying the impacts of TB on HIV-1 is essential for the development of effective measures to reduce TB related morbidity and mortality in HIV-1 infected individuals. In the present study we studied whether the increase in HIV-1 quasispecies diversity during active TB is reversed or preserved throughout the course of antituberculous chemotherapy. For this purpose Two time point HIV-1 quasispecies were evaluated by comparing HIV-1 infected patients with active tuberculosis (HIV-1/TB) and HIV-1 infected patients without tuberculosis (HIV-1/non TB). Plasma samples were obtained from the Frankfurt HIV cohort and HIV-1 RNA was isolated. C2V5 env was amplified by PCR and molecular cloning was performed. Eight to twenty five clones were sequenced from each patient. Various phylogenetic analyses were performed including tree inferences, intra-patient viral diversity and divergence, selective pressure, co-receptor usage prediction and two time point identity of quasispecies comparison using Mantel’s test. We found out from this study that: 1) Active TB sustains HIV-1 quasispecies diversity for longer period 2. Active TB increases the rate of HIV-1 divergence 3) TB might slow down evolution of X4 variants And we concluded that active TB has an impact on HIV-1 viral diversity and divergence over time. The influence of active TB on longitudinal evolution of HIV- 1 may be predominant for R5 viruses. The use of CCR5-coreceptor inhibitors for HIV-1/TB patients as therapeutic approach needs further investigation.
The pathophysiology of schizophrenia is still poorly understood. Investigating the neurophysiological correlates of cognitive dysfunction with functional neuroimaging techniques such as electroencephalography (EEG) and functional magnetic resonance imaging (fMRI) is widely considered to be a possible solution for this problem. Working memory impairment is one of the most prominent cognitive impairments found in schizophrenia. Working memory can be divided into a number of component processes, encoding, maintenance and retrieval. They appear to be differentially affected in schizophrenia, but little is known about the neurophysiological disturbances which contribute to deficits in these component processes. The aim of this dissertation was to elucidate the neurophysiological underpinnings of the component processes of working memory and their disturbance in schizophrenia. In the first study the the neurophysiological substrates of visual working memory capacity limitations were investigated during encoding, maintenance and retrieval in 12 healthy subjects using event-related fMRI. Subjects had to encode up to four abstract visual shapes and maintain them in working memory for 12 seconds. Afterwards a test stimulus was presented, which matched one of the previously shown shapes in fifty percent of the trials. A bilateral inverted U-shape pattern of BOLD activity with increasing memory load in areas closely linked with selective attention, i.e. the frontal eye fields and areas around the intraparietal sulcus, was observed already during encoding. The increase of the number of stored items from memory load three to memory load four in these regions was negatively correlated with the increase of BOLD activity from memory load three to memory load four. These results point to a crucial role of attentional processes for the limited capacity of working memory. In the second study, the contribution of early perceptual processing deficits during encoding and retrieval to working memory dysfunction was investigated in 17 patients with schizophrenia and 17 healthy control subjects using EEG and event-related fMRI. A slightly modified version of the working memory task used in the fist study was employed. Participants only had to encode and maintain up to three items. In patients the amplitude of the P1 event-related potential was significantly reduced already during encoding in all memory load conditions. Similarly, BOLD activity in early visual areas known to generate the P1 was significantly reduced in patients. In controls, a stronger P1 amplitude increase with increasing memory load predicted better performance. These findings indicate that in addition to later memory related processing stages early visual processing is disturbed in schizophrenia and contributes to working memory dysfunction by impairing the encoding of information. In the third study, which was based on the same data set as the second study, cortical activity and functional connectivity in 17 patients with schizophrenia and 17 to healthy control subjects during the working memory encoding, maintenance and retrieval was investigated using event-related fMRI. Patients had reduced working memory capacity. During encoding activation in the left ventrolateral prefrontal cortex and extrastriate visual cortex was reduced in patients but positively correlated with working memory capacity in controls. During early maintenance patients switched from hyper- to hypoactivation with increasing memory load in a fronto-parietal network which included left dorsolateral prefrontal cortex. During retrieval right ventrolateral prefrontal hyperactivation was correlated with encoding-related hypoactivation of left ventrolateral prefrontal cortex in patients. Cortical dysfunction in patients during encoding and retrieval was accompanied by abnormal functional connectivity between fronto-parietal and visual areas. These findings indicate a primary encoding deficit in patients caused by a dysfunction of prefrontal and visual areas. The findings of these studies suggest that isolating the component processes of working memory leads to more specific markers of cortical dysfunction in schizophrenia, which had been obscured in previous studies. This approach may help to identify more reliable biomarkers and endophenotypes of schizophrenia.
Apoptotic cell (AC)-derived factors alter the physiology of macrophages (M Phi s) towards a regulatory phenotype that is characterized by enhanced production of anti-inflammatory mediators, an attenuated pro-inflammatory cytokine profile and reduced nitric oxide (NO) formation. Impaired NO production in response to ACs or AC-conditioned medium (CM) is facilitated by arginase II (ARG II) expression, which competes with inducible NO synthase for L-arginine. In this study, I investigated the signaling pathway that allowed CM to upregulate ARG II in M Phi s. A sphingolipid, further identified as sphingosine-1-phosphate (S1P), was required but authentic S1P alone only produced small effects. S1P acted synergistically with a so far unidentified factor to elicit high ARG II expression. S1P signaled through S1P receptor 2 (S1P2), since the S1P2-antagonist JTE013 and siRNA knock-down of S1P2 prevented ARG II upregulation. Further, inhibition and knock-down of extracellular signal-regulated kinase 5 (ERK5) attenuated CM-mediated ARG II protein induction. Exploring ERK5-dependent transcriptional regulation, promoter deletion and luciferase reporter analysis of the murine ARG II promoter (mpARG II) suggested the involvement of cyclic adenosine monophosphate (cAMP) responsive element binding protein (CREB). This was confirmed by EMSA analysis and decoyoligonucleotides scavenging CREB, thereby preventing it from activating target genes and thus, blocking ARG II expression. I concluded that AC-derived S1P binds to S1P2 and acts synergistically with other factors to activate ERK5 and concomitantly CREB. This signaling cascade shapes an anti-inflammatory M Phi phenotype by ARG II induction. Further investigations of ERK5-dependent CREB activation suggested an indirect mechanism implying that ERK5 inhibited phosphodiesterase 4 (PDE4) and thus, prevented hydrolysis of cAMP. Since S1P-dependent ERK5 activation presumably inhibited PDE4, subsequent cAMP accumulation led to enhanced PKA activity and CREB-mediated transcription. The unidentified factor(s) besides S1P probably provoked the required elevation of cAMP production in M Phi s. Indeed, pharmacological inhibition of cAMP-producing adenylyl cyclase with SQ22536 as well as cAMP-dependent protein kinase A (PKA) with KT5720 suggested cAMP to be involved in CM-mediated ARG II up-regulation. Furthermore, forskolin-dependent activation of adenyly cyclase and simultaneous rolipram-mediated inhibition of PDE4 mimicked CM-induced ARG II expression. Considering these findings, I propose that one or several unidentified factors in CM provoke cAMP production in M Phi s. In parallel, AC-derived S1P activates ERK5, which inhibits PDE4-dependent cAMP hydrolysis, further raising intracellular cAMP levels. Thus, unrestricted continuous cAMP signaling via PKA/CREB, results in a time-dependent and sustained ARG II induction.
The role of gamma oscillatory activity in magnetoencephalogram for auditory memory processing
(2010)
Recent studies have suggested an important role of cortical gamma oscillatory activity (30-100 Hz) as a correlate of encoding, maintaining and retrieving auditory, visual or tactile information in and from memory. It was shown that these cortical stimulus representations were modulated by attention processes. Gamma-band activity (GBA) occurred as an induced response peaking at approximately 200-300 ms after stimulus presentation. Induced cortical responses appear as non-phase-locked activity and are assumed to reflect active cortical processing rather than passive perception. Induced GBA peaking 200-300 ms after stimulus presentation has been assumed to reflect differences between experimental conditions containing various stimuli. By contrast, the relationship between specific oscillatory signals and the representation of individual stimuli has remained unclear. The present study aimed at the identification of such stimulus-specific gamma-band components. We used magnetoencephalography (MEG) to assess gamma activity during an auditory spatial delayed matching-to-sample task. 28 healthy adults were assigned to one of two groups R and L who were presented with only right- or left-lateralized sounds, respectively. Two sample stimuli S1 with lateralization angles of either 15° or 45° deviation from the midsagittal plane were used in each group. Participants had to memorize the lateralization angle of S1 and compare it to a second lateralized sound S2 presented after an 800-ms delay phase. S2 either had the same or a different lateralization angle as S1. After the presentation of S2, subjects had to indicate whether S1 and S2 matched or not. Statistical probability mapping was applied to the signals at sensor level to identify spectral amplitude differences between 15° and 45° stimuli. We found distinct gamma-band components reflecting each sample stimulus with center frequencies ranging between 59 and 72 Hz in different sensors over parieto-occipital cortex contralateral to the side of stimulation. These oscillations showed maximal spectral amplitudes during the middle 200-300 ms of the delay phase and decreased again towards its end. Additionally, we investigated correlations between the activation strength of the gamma-band components and memory task performance. The magnitude of differentiation between oscillatory components representing 'preferred' and 'nonpreferred' stimuli during the final 100 ms of the delay phase correlated positively with task performance. These findings suggest that the observed gamma-band components reflect the activity of neuronal networks tuned to specific auditory spatial stimulus features. The activation of these networks seems to contribute to the maintenance of task-relevant information in short-term memory.
Purpose of the Study: The purpose of the current study was to evaluate the role of radiofrequency (RF) and microwave (MW) ablation in the treatment of pulmonary neoplasms. Materials and Methods: From March 2004 to January 2009, 164 patients (92 males, 72 females; mean age 59.7 years, SD: 10.2) underwent computed tomography (CT)-guided percutaneous RFA of pulmonary malignancies. RFA was performed on 248 lung lesions (20 primary lesions and 228 metastatic lesions) in 248 sessions (one lesion per session). Tumors were pathologically proven and were classified as primary lung neoplasms in 20 patients (non-small cell lung cancer) and as metastatic lung neoplasms in 144 patients. RFA was performed using: a) CelonProSurge bipolar internally cooled applicator b) RITA®StarburstTMXL. From December 2007 to October 2009, 80 patients (30 males, 50 females; mean age 59.7 years, range: 48-68, SD: 6.4) underwent computed tomography (CT) guided percutaneous MW ablation of pulmonary metastases from variable histopathological primaries. MW was performed on 130 lung lesions in 130 sessions (one lesion per session) using Valleylab TM system. Results: The overall success rate of RFA was 67.7% (168/248 lesions), with overall failure rate either due to tumor residue or recurrence on follow up in 32.3% (80/248) with mean time to tumor progress was 5.6 months SD: 2.99 (Range:1-18 months). Complete successful ablation was achieved in patients treated by MWA in 73.1% (95/130 lesions), with failure rate either due to tumor residue or recurrence on follow up in 26.9% (35/130) with mean time to tumor progress 6 months SD: 2.83 (Range:1-12months). Correlation of the histopathological type of the lesion and the end result of ablation therapy revealed insignificant correlation in both RFA and MWA (p > 0.1). The preablation tumor size was one of the most significant factors that determined the end result of ablation. In RFA successful tumor ablation was significant statistically for lesions with maximal axial diameter up to 2.5 cm (110/140) in comparison to lesions of more than 2.5 cm in maximal axial diameter (58/108) (Fisher’s exact test: p < 0.0001). While in MW ablated lesions successful tumor ablation was significant statistically for lesions with maximal axial diameter up to 3 cm (90/110) in comparison to lesions of more than 3 cm in maximal axial diameter (5/20) (Fisher’s exact test: p < 0.001). The location of the lesion was another important factor that determined the end result of ablation. In both RFA and MWA successful ablation was significantly more correlated to peripheral lesions (RFA: 120/160, 80% / MWA: 80/100, 80%) than centrally located lesions (RFA: 48/88, 50%; MWA: 15/30, 50%) (Fisher’s Exact Test: p > 0.001). For successfully RFA ablated cases mean preablation tumor volumes 1.9 cc SD: 0.9 (range: 0.3 - 4.25 cc) while for failed cases the mean tumor volume was 3.7 SD: 2.4 (range: 0.8 – 6.8cc). For successfully MW ablated cases the mean preablation tumor volume: 2.4 cc SD: 2.2 (range: 0.25-8.2 cc) while for failed cases the mean tumor volume was 3.5 SD: 2.6 (range: 0.3 – 7.1 cc). In RFA the survival rates at 12, 24 and 36 months were 90%, 78% and 68% respectively while in MWA treated patients the survival rate within 12 months follow up period was 96% while at 20 month the survival rate was 77%. Complications associated with the ablation therapy were: a) procedure related mortality: 0.4% (1/248) in RFA due to massive pulmonary hemorrhage versus 0% (0/130) in MWA, b) pneumothorax: 11.3% (28/240) in RFA versus 8.5% (11/130) in MWA, c) pulmonary Hemorrhage: 17.7% (44 of 248 sessions) of which one patient had massive uncontrolled bleeding and immediate death versus 6.2% (8/130) in MWA, d) pleural effusion: 3.2 % (8 of 248 sessions) in RFA versus 3.8 % (6/130) in MWA, e) hemoptysis: 4% (10/248) in RFA versus 4.6% (6/130) in MWA ranging from mild tinged sputum to frank bleeding, f) infection: 0.4% (1/248) in RFA, versus 0% in MWA, and g) post ablation pain: 10% (25/248) in RFA versus 9.2% (12/130) in MWA. Pain was generally adequately controlled by analgesics. Conclusion: Radiofrequency and microwave ablation are effective minimally invasive tools and may be safely applied for management of lung malignancy. The success of ablation therapy is significantly correlated to the preablation tumor size, volume and tumor location.