Long-term acupuncture treatment has a multi-targeting regulation on multiple brain regions in rats with Alzheimer's disease: a positron emission tomography study.

The acute effect of acupuncture on Alzheimer's disease, i.e., on brain activation during treatment, has been reported. However, the effect of long-term acupuncture on brain activation in Alzheimer's disease is unclear. Therefore, in this study, we performed long-term needling at Zusanli (ST36) or a sham point (1.5 mm lateral to ST36) in a rat Alzheimer's disease model, for 30 minutes, once per day, for 30 days. The rats underwent 18F-fluorodeoxyglucose positron emission tomography scanning. Positron emission tomography images were processed with SPM2. The brain areas activated after needling at ST36 included the left hippocampus, the left orbital cortex, the left infralimbic cortex, the left olfactory cortex, the left cerebellum and the left pons. In the sham-point group, the activated regions were similar to those in the ST36 group. However, the ST36 group showed greater activation in the cerebellum and pons than the sham-point group. These findings suggest that long-term acupuncture treatment has targeted regulatory effects on multiple brain regions in rats with Alzheimer's disease.

An FMRI study of neuronal specificity in acupuncture: the multiacupoint siguan and its sham point.

Clarifying the intrinsic mechanisms of acupuncture's clinical effects has recently been gaining popularity. Here, we choose the Siguan acupoint (a combination of bilateral LI4 and Liv3) and its sham point to evaluate multiacupoint specificity. Thirty-one healthy volunteers were randomly divided into real acupoint (21 subjects) and sham acupoint (10 subjects) groups. Our study used a single block experimental design to avoid the influence of posteffects. Functional magnetic resonance imaging data were acquired during acupuncture stimulation. Results showed extensive increase in neuronal activities with Siguan acupuncture and significant differences between stimulation at real and sham points. Brain regions that were activated more by real acupuncture stimulation than by sham point acupuncture included somatosensory cortex (the superior parietal lobule and postcentral gyrus), limbic-paralimbic system (the calcarine gyrus, precuneus, cingulate cortex, and parahippocampal gyrus), visual-related cortex (the fusiform and occipital gyri), basal ganglia, and the cerebellum. In this way, our study suggests Siguan may elicit specific activities in human brain.

FMRI evidence of acupoints specificity in two adjacent acupoints.

Objectives. Acupoint specificity is the foundation of acupuncture treatment. The aim of this study is to investigate whether the acupoint specificity exists in two adjacent acupoints. Design and Setting. Two adjacent real acupoints, LR3 (Taichong) and ST44 (Neiting), and a nearby nonacupoint were selected. Thirty-three health volunteers were divided into three groups in random order, and each group only received acupuncture at one of the three points. While they received acupuncture, fMRI scan was performed. Results. The common cerebral activated areas responding to LR3 and ST44 included the contralateral primary somatosensory area (SI) and ipsilateral cerebellum. Acupuncture at LR3 specifically activated contralateral middle occipital gyrus, ipsilateral medial frontal gyrus, superior parietal lobe, middle temporal gyrus, rostral anterior cingulate cortex (rACC), lentiform nucleus, insula, and contralateral thalamus. Stimulation at ST44 selectively activated ipsilateral secondary somatosensory area (SII), contralateral middle frontal gyrus, inferior frontal gyrus, lingual gyrus, lentiform nucleus, and bilateral posterior cingulate cortex (PCC). Conclusions. Acupuncture at adjacent acupoints elicits distinct cerebral activation patterns, and those specific patterns might be involved in the mechanism of the specific therapeutic effects of different acupoints.

[Characteristics of PET cerebral functional imaging during "Deqi" of acupuncture in healthy volunteers].

OBJECTIVE: To observe the characteristics of needling sensation of "Deqi" (feelings of soreness, numbness, distending and heaviness, SNDH) by using positron emission tomography (PET) based on changes of glucose metabolism in different functional brain areas. METHODS: Eighteen normal volunteers [9 men and 9 women, mean age (23.23-1- 3. 32) years] were randomly divided into control, Waiguan (SJ 5) and non-acupoint groups (n=6 in each group). SJ 5 and non-acupoint (the midpoint between SJ 5 and the running course of the Small Intestine Meridian on the right forearm) were punctured by using a sterilized filiform needle. PET scan of the brain began 40 min after intravenous 18 F-fluorodeoxyglucose (FDG) injection (0. 11 mCi/kg body weight, left opisthenar vein). Needling sensations including "Deqi"(n= 5), tingling (n 5) and no-apparently-specific-feeling (NASF) were acquired by acupuncture stimulation and grouped. The needling sensations were evaluated by using Visual Analog Scale(VAS). The acquired image data of different needling-sensation groups were analyzed using SPM 2. 0 software in the Matlab Platform. RESULTS: After receiving acupuncture stimulation of SJ 5, 5 volunteers in the Waiguan (SJ 5) group experienced fee- lings of SNDH, with the mean VAS score being 4.23 +/- 1. 50, and 5 volunteers of the non-acupoint group had a tingling feeling, with the mean VAS score being 5.73 2.40. The VAS score of the tingling group was significantly higher than that of SNDH group (P<0. 05). Compared with the NASF control group, the activated cerebral areas were Brodmann area (BA) 7, 13, 20, 22, 39, 42 and BA 45 in the SNDH group, mainly involving the left temporal lobe, superior temporal gyrus, etc. and being obviously different to those of the control group (P<0. 001,k>10 voxels). The activated cerebral areas in the tingling group were BA 18, 19, 22, 24, 25, 32, 36, 40 and BA 45, predominantly involving the left limbic lobe, hippocampal gyrus, etc. and being apparently different to those of the control group (P<0. 001,k> 10 voxels). CONCLUSION: Acupuncture of Waiguan (SJ 5) mainly produces feelings of soreness, numbness, distending and heaviness, and the activated cerebral areas mainly involve the left temporal lobe, superior temporal gyrus, etc. ; while acupuncture of its neighboring non-acupoint chiefly induces a feeling of tingling in the healthy subjects, and the activated regions predominately involve the left limbic lobe, hippocampal gyrus, etc.

Brain areas involved in acupuncture treatment on functional dyspepsia patients: a PET-CT study.

Neuroimaging studies on brain responses to acupuncture stimulations have received considerable attention recently. The majority of these studies are centered on healthy controls (HC) and neuropathy, while little work has addressed other disorders. This study aimed to investigate the influence of acupuncture stimulations on brain activities in functional dyspepsia (FD) patients. Eight FD patients and eight healthy controls (HC) were involved in this study. Each HC received an 18F-FDG PET-CT scan at baseline, while each patient received scans at baseline and after acupuncture stimulations. Manual acupuncture stimulations were performed at ST34 (Liangqiu), ST36 (Zusanli), ST40 (Fenglong) and ST42 (Chongyang) in FD patients. The images were analyzed with the Statistical Parametric Mapping software 2.0. Compared to HC, the FD patients showed a lower glycometabolism in the right orbital gyrus, the left caudate tail and the cingulate gyrus, and a higher glycometabolism in the left inferior temporal gyrus (p<0.005). After acupuncture stimulations, the FD patients showed a glycometabolism decrease in the postcentral gyrus and the cerebella, and an increase in the visual-related cortices(p<0.005). The results suggest that the anterior cingulate cortex, the prefrontal cortices and the caudate tail involve in processing gastric perceptions in FD patients and that the deactivation of the primary somatosensory area and the cerebella is contributable to acupuncture stimulation, while activation of the visual-related cortex is a response to pain or acupoint actions.

The human brain response to acupuncture on same-meridian acupoints: evidence from an fMRI study.

OBJECTIVES: Stimulation of acupuncture points (acupoints) located on meridians has been proven to activate specific areas of the human brain, as evidenced by functional imaging studies. To date, the specificity of acupoints located on different meridians has been investigated with functional magnetic resonance image (fMRI). The present fMRI study explored the effects of stimulating 4 acupoints on 2 different meridians for the purpose of researching the characteristic response of acupoints on the same meridian. MATERIALS AND METHODS: The acupoints studied were LR3 (Taichong) and LR6 (Zhongdu), which belong to the Liver meridian of Foot-Jueyin; ST36 (Zusanli) and ST43 (Xiangu), which belong to the Stomach meridian of Foot-Yangming; and 2 nearby sham acupoints. Fifty-three (53) healthy right-handed subjects were divided randomly into 6 groups. Each group only received acupuncture at one acupoint. All the acupoints in this study were stimulated only on the right side of the subject's body. Through analysis of fMRI data from all subjects, we obtained the activation patterns in the central nervous system (CNS) evoked by acupuncture. RESULTS: In contrast to the CNS activation by sham acupoint, the results showed that all 4 real acupoints under consideration had the common effect of activating 2 specific areas of the brain: the bilateral primary somatosensory area and the ipsilateral cerebellum. Acupuncture stimulation of both acupoints LR3 and LR6 evoked activation at the ipsilateral superior parietal lobe (BA7). Acupuncture stimulation of both acupoints ST36 and ST43 evoked activation at the ipsilateral middle frontal gyrus (BA10). CONCLUSIONS: These results suggest that different acupoints on the same meridian may activate certain similar areas of the brain. In addition, acupoints that are commonly used in clinical practice might modulate a greater extent of cortical areas than uncommonly used acupoints.

Improved temporal clustering analysis method applied to whole-brain data in acupuncture fMRI study.

Temporal clustering analysis (TCA) has been proposed as a method for detecting the brain responses of a functional magnetic resonance imaging (fMRI) time series when the time and location of activation are completely unknown. But TCA is not suitable for treating the time series of the whole brain due to the existence of many inactive pixels. In theory, active pixels are located only in gray matter (GM). In this study, SPM2 was used to segment functional images into GM, white matter and cerebrospinal fluid, and only the pixels in GM were considered. Thus, most of inactive pixels are deleted, so that the sensitivity of TCA is greatly improved in the analysis of the whole brain. The same set of acupuncture fMRI data was treated using both conventional TCA and modified TCA (MTCA) for comparing their analytical ability. The results clearly show a significant improvement in the sensitivity achieved by MTCA.