| 其他摘要 | Schizophrenia is not only a mental illness, but also a cognitive disease. Cognitive impairment is the core feature of schizophrenia, and the cognitive heterogeneity of patients with schizophrenia is high. The brain dysfunction of schizophrenic patients is not only manifested as abnormal local processing, but also the disorder among large-scale networks. The traditional method using resting state fMRI or simple repetitive tasks stimulation to study brain function in patients with schizophrenia, resting state fMRI mainly reflect subject’s endogenous neural spontaneous activity, and simple repetitive tasks to stimulate the stimulus confined in a very specific and narrow scope, may not be very good induction of abnormal brain activity in patients with schizophrenia. This series of studies is an innovative use of the natural stimulus paradigm to study brain dysfunction in patients with schizophrenia. The natural stimulus paradigm refers to the video or/and auditory stimuli that present the subject with complex dynamics. These stimuli simulate events in the real world, with the purpose of evoking the subject's brain response to the real world. This series of studies used a variety of innovative methods to quantify brain responses to natural stimuli in schizophrenia and to compare them with healthy controls.
This series of studies is divided into five parts, respectively investigating the local brain dysfunction in patients with first-episode schizophrenia, the new insula partitioning method, the functional connectivity analysis of seeds based on insula, the functional connectivity analysis based on whole-brain seeds, and the intersubject functional correlation analysis based on whole-brain seeds. The first study explored the local brain dysfunction in patients with first episode schizophrenia. Inter-subject correlation (ISC) refers to the correlation of time series in the same brain region between different subjects viewing video stimulation. ISC provides a model-free approach to quantify brain responses during natural scene perception without the need to define a priori stimulus model. Such data-driven analysis is efficient for solving research problems such as social perception, because the stimulus space is too high dimensional to generate a complete set of prior hypotheses for an appropriate feature model. ISC filters out the effects of endogenous neural signals and non-neural signals, reflecting the role of neural signals evoked by stimulation. The results showed that compared with healthy controls, patients with first episode schizophrenia showed significantly lower ISC in a wide range of brain regions including bilateral precuneus, posterior cingulate gyrus, anterior cingulate gyrus, temporoparietal junction, precuneus gyrus, superior temporal gyrus, middle frontal gyrus, and insula when viewing video stimulation. A high ISC in the visual cortex reflects video stimulation that schizophrenics and healthy controls looked at carefully as well. Abnormalities in the core nodes of the salient network and the default network indicate abnormal activity in these core regions during self-processing and social processing, memory retrieval, and attention allocation to internal and external stimuli.
Based on the results of study 1, studies 2 and 3 mainly investigated insula subdivision and functional connectivity analysis based on insula seeds. The ISC study found that large bilateral insula showed high inter-group activity heterogeneity, while the right insula showed the highest inter-group functional heterogeneity. The results showed that the insula showed a trend of anterior and posterior insula function separation in both schizophrenic patients and healthy controls. Functional connectivity studies based on insula seeds found that bilateral anterior insula and posterior insula had high functional connectivity with sensorimotor cortex, visual cortex, anterior cingulate cortex, posterior cingulate cortex, dorsal prefrontal cortex and insula itself. Statistical analysis of intergroup functional connectivity showed that for the left anterior insula and posterior insula, the functional connectivity differences were distributed in bilateral prominence networks. For the right anterior insula and the right posterior insula, functional connectivity differences between groups were distributed in the right highlighting network. These results suggest that the insula is abnormal in processing salient stimuli and allocating attention.
Study 4 explored functional connectivity based on whole-brain seeds in the natural stimulus paradigm. After comparing the functional connections between groups, it was found that the nodes in the default network had weaker functional connectivity with the cingulate cortex, insula, sensory and perceptual cortex and visual cortex. Functional connectivity of sensory motor cortex nodes are almost all related to abnormal cingulate gyrus, especially anterior cingulate gyrus. For the cingulate task control network, auditory network and memory extraction network, functional connectivity differences between groups were mainly concentrated in the right insula, which was one of the core nodes of the salient network. For the nodes of the frontal and parietal control network, the differences in functional connections between groups were manifested in cingulate gyrus, precuneus and insula. Posterior cingulated gyrus and precuneus are the core nodes of the default network, while insula is the core node of the salient network. These results again validate the default network, task control network, and the communication patterns that highlight the connections and exceptions between networks, and the anomalies among the three networks. For the salience networks, the functional connectivity between groups show large-scale dissonance between networks, especially thos between groups and default networks, sensorimotor cortex and task control networks. Overall, we can conclude that under the natural stimulus paradigm, schizophrenia patients and healthy controls had abnormal connections between the default network, sensorimotor cortex, taskcontrol network, and salience network, and that almost all of these connections pointed to abnormalities in the insula.e Finally, we investigated the inter-subject functional correlation (ISFC) group based on 264 functional seeds. On a more macroscopic scale, the activity consistency of the stimulus evoked signals between the two groups was examined. Unlike functional connectivity based on wholebrain seeds, ISFC filters out the effects of endogenous neural signals in the subjects, as well as the effects of non-neural signals brought about by the scanner. The results showed that the intergroup functional variation was mainly focused on the difference of activity consistency between sensory motor network, cingulate task control network, auditory network, visual network, frontal and parietal control network, salience network and a small part of subcortical network and the default network of healthy controls. These results show that compared with the default network activity consistency of healthy controls, the brain network of patients with schizophrenia has abnormalities in the information communication with the default network, that is, as the information integration center, the default network has great heterogeneity in the activity of patients with schizophrenia. This series of studies establishes anomalies in the communication between salient networks, default networks, and task-control networks. Highlighting that the network is responsible for allocating attention to internal and external stimuli in cognitive processing, while the default network is a more advanced information integration center, the task control network also shows abnormalities in the implementation of various task control. We conclude that the abnormal information exchange in these three networks is a typical feature of information processing in patients with schizophrenia, and provides a very important biomarker for later diagnosis of the disease.
Overall, this series of experiments, starting with how first-episode schizophrenics with natural stimuli perceive stimuli, found variations in many areas of higher cognitive integration, such as the cingulate gyrus, precuneus, temporoparietal junction, and insula. Since the insula showed the largest inter-group differences in this study, because we used the insula as a seed point to conduct a separate study, it was found that insula differentiation was greater in patients with schizophrenia, and the insula as a key node of the highlighted network also had lower functional connectivity intensity compared with healthy subjects. On the basis of local abnormalities, the experiment also examined the differences between groups in whole-brain functional connections based on whole-brain seed points, and the results showed that almost all the brain functional networks in patients with schizophrenia were disconnected compared with healthy subjects. Since the functional connectivity analysis method could not exclude the influence of endogenous signals, we used the intergroup functional correlation method to explore the activity consistency of brain networks between groups, and found that the activity consistency of schizophrenia patients in almost all functional networks was low.
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