Chao-Hsien Hsieh scite author profile

The aim of this study is to compare the distinct cerebral activation with continued wave (CW) and 10 Hz-modulated wave (MW) stimulation during low-level laser acupuncture. Functional magnetic resonance imaging (fMRI) studies were performed to investigate the possible mechanism during laser acupuncture stimulation at the left foot's yongquan (K1) acupoint. There are 12 healthy right-handed volunteers for each type of laser stimulation (10-Hz-Modulated wave: 8 males and 4 females; continued wave: 9 males and 3 females). The analysis of multisubjects in this experiment was applied by random-effect (RFX) analysis. In CW groups, significant activations were found within the inferior parietal lobule, the primary somatosensory cortex, and the precuneus of left parietal lobe. Medial and superior frontal gyrus of left frontal lobe were also aroused. In MW groups, significant activations were found within the primary motor cortex and middle temporal gyrus of left hemisphere and bilateral cuneus. Placebo stimulation did not show any activation. Most activation areas were involved in the functions of memory, attention, and self-consciousness. The results showed the cerebral hemodynamic responses of two laser acupuncture stimulation modes and implied that its mechanism was not only based upon afferent sensory information processing, but that it also had the hemodynamic property altered during external stimulation.

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A Portable Wireless Online Closed-Loop Seizure Controller in Freely Moving Rats

Young

Liang

Chang

et al. 2011

IEEE Trans. Instrum. Meas.

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Slow-paced inspiration regularizes alpha phase dynamics in the human brain

Hsu

Tseng

Hsieh

et al. 2020

Journal of Neurophysiology

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The phase of low-frequency, rhythmic cortical activity is essential for organizing brain processes because it provides a recurrent temporal frame for information coding. However, the low-frequency cortical phase exhibits great flexibility in response to external influences. Given that brain rhythms have been found to track respiratory inputs, we hypothesized that slow breathing, commonly associated with mental regulation, could reorganize the relationship between these two rhythmic systems through the adjustment of the cortical phase to such a slow train of inputs. Based on simultaneous magnetoencephalography and respiratory measurements, we report that while participants performed paced breathing, slow relative to normal breathing modulated cortical phase activity in the alpha range across widespread brain areas. Such modulation effects were specifically locked to the middle of the inspiration stage and exhibited a well-structured pattern. At the single-subject level, the phase angles underlying the effects became more likely to be diametrically opposed across breaths, indicating unique and consistent phase adjustment to slow inspiratory inputs. Neither cardiac fluctuations nor breathing-unrelated task effects could account for the findings. We suggest that slow-paced inspiration could organize the cortical phase in a regularized phase pattern, revealing a rhythmic but dynamic neural network integrated with different neurophysiological systems through volitional control. NEW & NOTEWORTHY Breathing is more complicated than a simple gas exchange, as it is integrated with numerous cognitive and emotional functions. Controlled slow breathing has often been used to regulate mental processes. This magnetoencephalography study demonstrates that slow-paced relative to normal-paced inspiration could organize the timing of alpha rhythmic activities across breathing cycles in a structured manner over widespread brain areas. Our results reveal how a volitionally controlled change in respiratory behavior could systematically modulate cortical activity.

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Brain Deactivation in the Outperformance in Bimodal Tasks: An fMRI Study

et al. 2013

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While it is known that some individuals can effectively perform two tasks simultaneously, other individuals cannot. How the brain deals with performing simultaneous tasks remains unclear. In the present study, we aimed to assess which brain areas corresponded to various phenomena in task performance. Nineteen subjects were requested to sequentially perform three blocks of tasks, including two unimodal tasks and one bimodal task. The unimodal tasks measured either visual feature binding or auditory pitch comparison, while the bimodal task required performance of the two tasks simultaneously. The functional magnetic resonance imaging (fMRI) results are compatible with previous studies showing that distinct brain areas, such as the visual cortices, frontal eye field (FEF), lateral parietal lobe (BA7), and medial and inferior frontal lobe, are involved in processing of visual unimodal tasks. In addition, the temporal lobes and Brodmann area 43 (BA43) were involved in processing of auditory unimodal tasks. These results lend support to concepts of modality-specific attention. Compared to the unimodal tasks, bimodal tasks required activation of additional brain areas. Furthermore, while deactivated brain areas were related to good performance in the bimodal task, these areas were not deactivated where the subject performed well in only one of the two simultaneous tasks. These results indicate that efficient information processing does not require some brain areas to be overly active; rather, the specific brain areas need to be relatively deactivated to remain alert and perform well on two tasks simultaneously. Meanwhile, it can also offer a neural basis for biofeedback in training courses, such as courses in how to perform multiple tasks simultaneously.

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Correlation between Pineal Activation and Religious Meditation Observed by Functional Magnetic Resonance Imaging

Liou

Hsieh²,

Hsieh

et al. 2007

Nat Prec

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The human brain possesses plenty of functions but little is known about its scientific relationship with mind and spirit. Conferences^1,2^ focused on the connection between science and religion were held very recently in which neuroscientists, Buddhist scholars and Dalai Lama discussed attention, mental imagery, emotion, mind, brain functions and meditation, suggesting religious meditation offers an effective means to investigate the mystery of mind and spirit. In the past decade, scientists struggled to obtain brain mappings for various meditation styles using different brain imaging techniques and stimulating results have been observed^3-17^. In this letter we report that, together with other brain regions, pineal body exhibit significant activation during meditation process, supporting the long lasting speculation that pineal plays an important role in the intrinsic awareness which might concern spirit or soul. Pineal is known as an endocrine organ which produces substrates including melatonin and has been ascribed numerous even mysterious functions but its activation during meditation has never been observed by brain imaging technique. In seventeenth century, based on anatomic observation, Descartes ventured to suggest that pineal serves as the principal seat of the soul^18-20^. Inspired by its geometric center in the brain, physiologists, psychologists, philosophers and religionists have been speculating for centuries about pineal's function relevant to spirit and soul. In this study, we chose Chinese Original Quiet Sitting, one style of meditation, to explore this long lasting speculation by functional magnetic resonance imaging technique. Our results demonstrate a correlation between pineal activation and religious meditation which might have profound implications in physiological understanding of the intrinsic awareness.

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Studies of Chinese Original Quiet Sitting by Using Functional Magnetic Resonance Imaging

Liou

Hsieh

et al. 2005

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Since different meditations may activate different regions in brain, we can use functional magnetic resonance imaging (fMRI) to investigate it. Chinese original quiet sitting is mainly one kind of traditional Chinese meditation. It contains two different parts: a short period of keeping phrase and intake spiritual energy, and a long period of relaxation with no further action. In this paper, both those two stages were studied by fMRI. We performed two different paradigms and found the accurate positions in the brain. The pineal gland and the hypothalamus showed positive activation during the first and second stages of this meditation. The BOLD (Blood Oxygenation Level Dependent) signal changes had also been found.

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A Multidimensional Quantum Model of Brain Activity: the Exploration of Increased Neural Energy States in Daoist Meditation

Liou

Hsieh

et al. 2016

Neuroquantology

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In the study of high energy physics, as subatomic particles are in different energy states, a suitable accelerator is needed to explore information inside the atom at deeper and deeper levels. Particularly, there are different neural energy patterns or neuro-quantum states within the brain associated with meditative practices; to find out certain information inside the body, it is necessary to reach a meditative state having increased energy levels. Here we report that Chinese Original Quiet Sitting (COQS)-one style of Chinese Daoist meditation-exhibits noticeable results about different neural energy levels or quantum types using functional magnetic resonance imaging technique. Two different states within COQS were examined. Firstly, a prolonged rest-like meditative state, maintaining a relatively low energy level and showing both activation and deactivation of certain brain regions, was observed. Secondly, a higher energy state was found, showing different pattern with only positive activation of certain brain regions. In particular, it appears that there is a correlation between pineal activation and this high energy meditation practice. Also, the pineal body seems concerning with the "upper elixir field" which is an important region in Daoist meditation. Our results provide new evidence for a seldom studied aspect of human physiological performance which has life science implications. Also, a multidimensional quantum model of brain activity is established to offer a scientific description more properly.

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Chao-Hsien Hsieh

Using functional Magnetic Resonance Imaging (fMRI) to analyze brain region activity when viewing landscapes

Different Brain Network Activations Induced by Modulation and Nonmodulation Laser Acupuncture

A Portable Wireless Online Closed-Loop Seizure Controller in Freely Moving Rats

Slow-paced inspiration regularizes alpha phase dynamics in the human brain

Brain Deactivation in the Outperformance in Bimodal Tasks: An fMRI Study

Correlation between Pineal Activation and Religious Meditation Observed by Functional Magnetic Resonance Imaging

Studies of Chinese Original Quiet Sitting by Using Functional Magnetic Resonance Imaging

A Multidimensional Quantum Model of Brain Activity: the Exploration of Increased Neural Energy States in Daoist Meditation

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