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1. Introduction
Functional Dyspepsia (FD) is a functional gastrointestinal disorder defined by the Rome IV consensus as the presence of symptoms thought to originate from the upper gastrointestinal region without organic causes; it can be divided into postprandial distress syndrome (PDS) and epigastric pain syndrome (EPS) [1]. Despite not being a life-threatening condition, it severely reduces quality of life for affected patients [2]. Current conventional allopathic treatment options exist for FD, such as H. pylori eradication, proton pump inhibitors (PPIs), and histamine-type-2-receptor antagonists (H2RAs); however, their efficacies are modest at best [3, 4], and they also result in negative side effects or negative long-term effects to the patient [5, 6]. For example, H. pylori eradication using antibiotics often produces gastrointestinal side effects such as diarrhea, nausea, taste distortion, stomatitis, and bloating, which reduce the tolerability of treatment and lead to treatment withdrawal [5]; treatments using PPIs have been shown to potentially cause serious long-term adverse effects, such as pneumonia, C. difficile diarrhea, risk of fractures, and hypomagnesemia [6]. Studies on the effects of H2RAs have typically suffered from poor quality or have shown a small effect on FD at best [4].
As an alternative form of treatment for FD that does not result in the same long-term side effects and resistance as drugs [7], acupuncture and/or electroacupuncture (EA) has been used in China for thousands of years to help relieve its various symptoms [8]. Research in this area has focused on the mechanisms behind both the pathogenesis of the condition [9] and the therapeutic effects of acupuncture on human and animal subjects [10–12]. Such studies often use imaging technologies such as positron emission tomography-computed tomography (PET-CT) [8, 9, 12] and functional magnetic resonance imaging (fMRI) [13–15]. Regardless of the type of imaging study, results have consistently shown that the insula, a brain region in the deep cerebral hemisphere involved in processing emotional responses, visceral sensation, interoceptive awareness, cognitive and affective regulatory functions, and olfactory and gustatory stimulation processing [9, 16–18], is an important area in FD research, since it is involved in both the pathogenesis and treatment of FD [8, 9, 12]. Studies involving human subjects in this area have shown weakened structural changes and functional connections of the insula in patients with FD [9], correlation between these changes and severity of FD symptoms [12], and changes in functional connections occurring through acupuncture or EA treatment of FD [8]. However, there has been little research into the activation pathways and mechanisms that are triggered through the insula when treating FD with acupuncture or EA. Furthermore, modeling of FD using animals has become an emerging area of research due to ethical or economic considerations arising from use of human FD patients.
Rats have commonly been used to mimic some of the disease outcomes and conditions of FD, such as psychological distress, delayed gastric emptying, impaired gastric accommodation, and visceral hypersensitivity, as described by Ye et al. [11]. Acupuncture point combinations such as the pairing of Stomach back-shu (BL-21) and front-mu (RN-12) points are among those typically used in acupuncture or EA treatment modalities of animal models [19, 20]. This combination has been shown specifically to improve decreased gastric motility through the hippocampus [21], dorsal vagal complex (DVC) [19, 20], or the paraventricular hypothalamic nucleus (PVA) [20]. However, like similar studies involving human counterparts, there has been little research into the activation pathways and mechanisms involving the insula in acupuncture or EA treatment of FD [21]. Due to the importance of the insula in both the pathogenesis and treatment aspects of FD, we hypothesize that it occupies a major role in the central mechanisms in acupuncture or EA treatment of FD. Our study aims to explore this hypothesis by conducting a seed-based functional connectivity analysis of FD rat models with EA intervention, in which the insula is designated as the region of interest (ROI).
2. Materials and Methods
2.1. Ethical Approval
This study was approved by the Experimental Animal Welfare and Ethics Committee of Chengdu University of Traditional Chinese Medicine (no. 2016-10). All efforts were made to minimize suffering.
2.2. Materials
The materials used are as follows: 0.1% iodoacetamide (Sigma Corporation, USA), isoflurane (ISO) (RWD Living Science Technology Inc., Shenzhen, China), Safe 2010 Safety Cabinet (Heto-Holten A/S, Denmark), PF Hetotherm Heating circulator (Heto-Holten A/S, Denmark), G6805-II electroacupuncture pulse generator (Qingdao Xinsheng Medical Instrument Factory, Shandong, China), Bruker BioSpec 70/20 USR small animal 7T MRI scanner (600 MHz) (Bruker Corporation, Germany), SPSS 20.0 (SPSS Inc., Chicago, IL, USA), and spmratIHEP based on the statistical parametric mapping (SPM8) software (Welcome Department of Cognitive Neurology, London, UK).
2.3. Animals and Grouping
Thirty-six healthy Sprague-Dawley (SD) rat pups (7 days old, day of birth = day 0) were used in this study (Certificate no.: CXK [Sichuan] 2015-030). The rat pups were randomly divided into control group (n = 12), FD model group (n = 12), and FD acupuncture group (n = 12) and placed in three separate cages. Although neonatal maternal separation has been shown to be one of the commonly used methods in producing FD animal models [11], it has also been identified as a risk factor in irritable bowel syndrome (IBS) [22]. To prevent the possibility of creating IBS models as a confounding factor, we placed one lactating female rat in each cage with sufficient food and water to provide feeding for the pups. After seven days of nursing to help rat pups acclimatize, the first phase of FD modeling was commenced.
2.4. FD Modeling
A two-phase multiple-feature modeling method was used to create the FD model used in this study, including iodoacetamide-sucrose administration, tail clamping, and irregular feeding, which have been previously described [11, 21–24]. We aimed to produce FD rat models with the specific set of characteristics: presence of anxiety-like behaviour resulting in decreased appetite and water intake, reduction in activity, decrease of coat luster, increased knots in fur, and delayed gastric emptying. Phase one consisted of oral gavage administration of an iodoacetamide-sucrose solution, consisting of 0.1% iodoacetamide (IA) distilled water solution with a 2% sucrose distilled water solution, mixed at a ratio of 1 : 1 to induce neonatal gastric irritation [11]. The FD model and FD acupuncture groups received oral gavage administration of the IA-sucrose solution over 6 days, 0.2 mL per day, while the control group received oral gavage administration of 0.2 mL 2% sucrose distilled water solution over the same period, all alongside regular nursing [25]. After the six-day period, regular nursing was resumed until day 22, at which point the female rats were separated from the litters. From day 22 onwards, feed pellets were introduced until the rat pups reached 7 weeks of age, and we commenced phase two of FD modeling. Phase two consisted of tail clamping to induce stress and delayed gastric emptying [11, 26] and irregular feeding to disrupt regular feeding cycles [21] over a period of 14 days. Tail clamping provocation was implemented in the FD model and FD acupuncture groups by clamping sponge forceps at the distal 1/3 region of rat tails, without injury to the skin, for 30 minutes at a time, four times per day [27]. Discomfort from tail clamping made the rats irritable and anxious and caused infighting. Irregular feeding was also administered to the FD model and FD acupuncture groups during this period by withholding food (but not water) on odd-numbered days and feeding normally on even-numbered days [21]. The control group was fed normally during phase two without tail clamping. At the end of phase two on day 63, successful FD modeling was confirmed by rats in the FD groups having exhibited the desired model characteristics prior to the beginning of EA intervention. EA intervention was then administered from day 63 to day 73, followed by subsequent fMRI scanning and gastric extraction. Indirect indication of successful FD modeling was also confirmed after gastric extraction, when delayed gastric emptying rates were measured in the FD model group and compared to the control group, after EA intervention. The workflow of the experimental protocol is shown in Figure 1.
[figure omitted; refer to PDF]
Table 1
FC results (control group versus FD model group).
| Brain region | Brain functional connection results | Standard deviations | ||
| Voxel size | t value | Mean ± SD (control) | Mean ± SD (FD model) | |
| Primary somatosensory cortex (S1) | 133 | −3.4199 | 0.16 ± 0.11 | 0.06 ± 0.06 |
| Hippocampal CA3 (CA3) | >200 | −4.9154 | 0.23 ± 0.09 | 0.10 ± 0.08 |
| Thalamus (THa) | >100 | −3.1142 | 0.10 ± 0.11 | 0.02 ± 0.06 |
| Ectorhinal cortex (Ect) | 35 | −2.6699 | 0.25 ± 0.12 | 0.16 ± 0.09 |
| Polymorphic layer of dentate gyrus (PoDG) | >100 | −4.4994 | 0.13 ± 0.08 | 0.02 ± 0.06 |
| Medial parietal association cortex (MPtA) | >100 | −3.2009 | 0.22 ± 0.16 | 0.09 ± 0.09 |
| Primary visual cortex (V1) | >100 | −3.9261 | 0.16 ± 0.12 | 0.06 ± 0.08 |
| Temporal association cortex (TeA) | >100 | −4.4293 | 0.19 ± 0.11 | 0.07 ± 0.09 |
In the FD model group, regions exhibit significant functional connections to the insula. Negative t values denote weakening connection, while positive t values denote strengthening connections.
3.5. Rat fMRI Imaging Results
Six rats were chosen from each of the three groups, and rs-fMRI scanning was performed after EA intervention. The scans established the insula as the seed while exploring its functional connections with the rest of the brain:
(1) Compared to the control group, the FD model group contained regions which had significant functional connections with the insula, as seen in Table 1 and Figure 8. Compared with the control group, rats in the FD model group exhibited decreased functional connections in regions including the primary somatosensory cortex, hippocampal CA3, thalamus, ectorhinal cortex, polymorphic layer of dentate gyrus, medial parietal association cortex, primary visual cortex, and temporal association cortex (
(2) After EA intervention, when compared to the FD model group, the FD acupuncture group displayed regions which had significant functional connections to the insula, summarized in Table 2 and Figure 9. The regions which exhibited increased functional connections include caudate putamen, barrel field of primary somatosensory cortex, hippocampal CA3, oral pontine reticular nuclei, and polymorphic layer of dentate gyrus (
Table 2
FC results (FD model group versus FD acupuncture group).
| Brain region | Brain functional connection results | Standard deviations | ||
| Voxel size | t value | Mean ± SD (FD model) | Mean ± SD (FD acupuncture) | |
| Right primary and secondary motor cortexes (M1/2) | 44 | −2.909 | 0.13 ± 0.09 | 0.05 ± 0.10 |
| Left primary and secondary motor cortexes (M1/2) | 23 | −3.3159 | 0.09 ± 0.05 | 0.04 ± 0.07 |
| Paraventricular nucleus of hypothalamus (PVA) | 13 | −2.7523 | 0.11 ± 0.08 | 0.05 ± 0.09 |
| Caudate putamen (CPu) | 9 | 2.56917 | 0.10 ± 0.05 | 0.14 ± 0.07 |
| Barrel field of primary somatosensory cortex (S1BF) | 29 | 2.0751 | 0.12 ± 0.07 | 0.19 ± 0.09 |
| Hippocampal CA3 (CA3) | 60 | 3.1749 | 0.07 ± 0.09 | 0.16 ± 0.11 |
| Oral pontine reticular nuclei (PnO) | 257 | 3.6603 | −0.01 ± 0.06 | 0.09 ± 0.10 |
| Polymorphic layer of dentate gyrus (PoDG) | 62 | 3.5844 | 0.04 ± 0.07 | 0.11 ± 0.10 |
In the FD acupuncture group, regions exhibit significant functional connections to the insula. Negative t values denote weakening connection, while positive t values denote strengthening connections.
[figure omitted; refer to PDF]3.6. Discussion
Present explanations on the mechanism of acupuncture center around neural mechanisms or humoral mechanisms; thus our exploration focuses on the neural mechanism of acupuncture in the treatment of FD. There is increasing evidence in support of the presence of abnormal central changes of FD patients in addition to the peripheral changes in gastrointestinal tract. Previous results have suggested that the frontal cortex, somatosensory cortex, insula, ACC, thalamus, hippocampus, and amygdala were activated in FD patients prior to treatment, with the insula in particular occupying a key role [9, 32]. Interestingly, several studies have indicated that the brain regions activated in FD patients at baseline are different than those with acupuncture or EA intervention [8, 10]. This phenomenon suggests that the central mechanism involved in the pathogenesis of FD may be different than that of acupuncture treatment of FD patients and suggests the possibility of different pathway(s) in acupuncture treatment of FD patients, which we also explore in our results.
Our current rs-fMRI study involving seed-based functional connectivity analysis on EA treatment of FD rat models establishing the insula as ROI has revealed the following: (a) the combination of RN-12 and BL-21 acupoints can be used to improve gastric motility, which confirms the results of previous studies [19–21], and, more importantly, (b) specific patterns of increasing and decreasing functional connectivity not only exist with regard to the insula in FD rat models but also occur in EA intervention of FD.
Initially, we created a two-phase, multiple feature rat model of FD using methods previously established, including neonatal gastric irritation through oral gavage administration of iodoacetamide, tail clamping, and irregular feeding [11, 21, 23]. Successful models of both FD model and FD acupuncture groups were confirmed through monitoring of decreasing point measurements of general observations, increased anxiety-like behaviour, and infighting, resulting in decreased body weight and food and water intake, and through delayed gastric emptying rates which were measured subsequent to rs-fMRI scans. All measures that were recorded, except for gastric emptying rates, showed that statistically significant differences existed between the two FD groups and the control group. Our results also showed no statistically significant differences amongst the two FD groups prior to EA intervention, which confirmed successful FD modeling as reported in other studies [11, 21, 23]. Throughout the EA intervention phase of the study, the data collected regarding weight gain and food and water intake of the FD model group revealed two points of interest which seemed to contradict the initial effects of FD modeling to produce decreased weight gain, food intake, and water intake. First, the FD model group exhibited more weight gain than the control group throughout the EA intervention phase, even though FD model group was only restrained and not subject to EA intervention, as shown in Figure 5(c). Second, the FD model group also exhibited significant increases in food and water intake throughout the EA intervention phase, despite not being subject to EA intervention, as shown in Figures 6(a) and 6(b). These changes were unexpected because we initially believed that the FD modeling measures employed would produce permanent pathophysiological changes such as permanent increases in weight loss as noted by Wu et al. [23]. However, similar trends were shown in another study by Zhang et al. measuring the effects of Shen-Ling-Bai-Zhu-San on FD rat models [33], where the FD model group exhibited increases in food and water intake without intervention. Here, the data seemed to show other factors at work which decreased the effects of FD modeling on the FD model group, despite this group not being subject to EA intervention. Since no other interfering measures were applied to the FD model group, we hypothesize that these improvements may have had to do with the natural healing functions of the body and take note of this as a point of interest to consider in future research.
After EA intervention and the rs-fMRI process, gastric ligation was performed to both indirectly confirm successful modeling and measure the effect of EA intervention on gastric emptying rates. We found that the control group had the highest gastric emptying rate (56.82%), followed by the FD acupuncture group (53.39%) and then followed by the FD model group (41.54%), which confirmed the results of previous research, indicating that EA treatment using the combination of RN-12 and BL-21 acupoints improves gastric motility [21]. Interestingly, despite previous research by Li et al., which showed that EA at RN-12 tended to suppress gastric motility in human subjects when used by itself [34], our results showed that the opposite was true. We hypothesize that the difference in outcome may be related to the synergistic effects of the BL-21 and RN-12 acupoint combination, as opposed to just using the RN-12 acupoint by itself.
In the brain imaging process, we conducted a seed-based functional connectivity analysis of the FD model and FD acupuncture groups after EA intervention, establishing the insula as ROI.
3.6.1. Functional Connections in FD Model Group and Comparisons to Previous Results
In the FD model group, significantly decreased functional connections were found only in the following brain regions: S1, CA3, THa, Ect, PoDG, MPtA, V1, and TeA, which bear both similarities and contrasts to previous results. Our results are similar to previous findings that indicate abnormal functional connections found between insula and S1, hippocampal CA3, and PoDG regions. In a systematic review of sixteen studies of FD patient brain activity by Lee et al., abnormal brain activity was frequently found in several areas across resting-state FD patients, including the insula, hippocampus, S1, prefrontal cortex, anterior cingulate cortex, and amygdala [32].
Activation in S1 has been reported in the literature previously. In a PET-CT study on FD patients by Zeng et al., S1 activity was shown in FD patients treated with acupuncture, though not in FD model patients [10]. Similar results were observed in a review by Lee et al. in terms of functional abnormalities of FD patients in several brain regions including S1 [32]. Findings from the same review also indicate that the temporal lobe and S1 were commonly activated during simulated distension of FD rat models using balloons [32]. Since one of the main symptoms of FD is epigastric pain, which may be accompanied by distension, the activation of S1 in our results could be interpreted as another measure of FD modeling success.
Both CA3 and PoDG are located within the hippocampus, and previous results in an H215O PET study by Van et al. have shown that the hippocampus is activated in resting-state FD patients with history of physical abuse [35]. Another FD study reported that mRNA expression of GHS-R in hippocampus increased in the EA group compared with the model group [36]. In our study, the tail clamping and irregular feeding phases have been shown to create stress in rats and could have contributed to similar activation in the hippocampus.
Similar to the decreasing functional connections found between insula and THa within our results, a previous fMRI study of FD patients with acupuncture intervention by Liu et al. also found decreased functional connectivity in the right THa with the right anterior insula in resting-state FD patients [9]. An 18F-FDG PET-CT study by Zeng et al. showed deactivating THa activity in FD patients treated with acupuncture but not in resting state [8]. However, the discrepancies in THa activity were also observed by Liu et al. in another study investigating neural patterns in FD patients without acupuncture intervention, while their explanation for the differences was that dysfunctions in visceral sensory pathway can affect the “switchboard” ability of the THa to coordinate multiple actions [14]. Likewise, similar discrepancies exist for the decreasing functional connections for the TeA region found in our study compared to results of previous studies. The aforementioned fMRI study with acupuncture intervention by Liu et al. found decreased functional connectivity of the right anterior insula with right THa, and FD patients had negative correlation between disease duration and the functional connectivity of right anterior insula with THa [9]. However, another fMRI study by Fang et al. showed activity in the inferior temporal gyrus in FD patients prior to acupuncture treatment [13], while the neural pattern study by Liu et al. found resting-state activity in both the THa and temporal pole [14]. The explanation of discrepancies by Liu et al. in their neural pattern study was that the temporal pole was related to the neuropsychological mechanism of emotion in FD patients and that patients with different disease durations could exhibit differing activity in this region [14]. In our study, the duration of disease was uniform among the FD model and FD acupuncture groups, leading us to reject the disease duration explanation for rat models. Instead, we believe that the activation of the TeA region in our results may be due to recall of fear in the rat models, as suggested by Cho et al. in their study on activation of the TeA from remote recall of fear [37].
Activities in V1, MPtA, and ectorhinal regions from our results were not observed in other studies. Increasing functional connectivity in V1 had been observed in a previous fMRI study of healthy subjects treated via acupuncture by Dhond et al., although their study did not focus on FD patients [38]. The MPtA region has been shown to be associated with the processing of spatial tasks in rats [39]. Furthermore, the ectorhinal complex has been shown to relate to the freezing of movements in conditioned fear in rats [40], and its activation may be due to similar reasons as our proposed explanation of TeA activation. Due to limited availability of research, further study of these brain regions is required.
3.6.2. Functional Connections in FD Acupuncture Group and Comparisons to Previous Results
In the FD acupuncture group, a different pattern of both significantly increasing and decreasing functional connections is seen in the following brain regions: left and right M1/2, PVA, CPu, S1BF, CA3, PRh, PnO, and PoDG.
In contrast to the FD model group, functional connections increased between the insula and the regions of S1, hippocampal CA3, and PoDG. Changes in these same regions were found in one study reviewed by Lee et al., indicating that brain activity increased in S1 but decreased in the insula and hippocampus in FD patients after 20 EA sessions [32]. Besides these similarities, we also noticed differences in comparison to results from another fMRI study by Zeng et al. [8], in which functional connectivity was measured between various ROIs in human FD patients before and after acupuncture treatment, in that they did not find functional connections between the anterior insula and hippocampus regions. The hippocampus brain region was previously shown by Wang et al. to be related to the regulation of gastric motility, as EA of RN-12 and BL-21 resulted in reduction of glutamate and subsequently improved gastric mobility [21]. The specific hippocampal CA3 and PoDG regions not only form part of the hippocampal formation [41] but also are involved in memory [38, 42, 43], production of new neurons after injury [44], the healing of physical trauma [45], and the remodeling of synapses after injury, all of which are functions that may help explain the treatment efficacies of EA or acupuncture towards FD. We attribute the discrepancies between our results and those of Fang et al. to differences in methodology, including different acupuncture points used, and differences in manual acupuncture versus EA. Furthermore, our findings would appear to suggest that abnormal functional connections between the insula and the hippocampal CA3 and PoDG regions form part of the mechanism which EA regulates in treating FD.
With regard to increased functional connectivity between the insula and CPu, S1BF, and PnO regions, research has shown that functional connections decreased between the insula and CPu in alcohol-dependent rats going through early withdrawal [46]. Both the insula and S1BF have also been shown to belong to the circuit which regulate gustatory information [47], and connections between the insula and PnO are yet to be explored, with more research required in these areas overall.
In contrast to the FD model group, functional connections decreased in the regions of left and right M1/M2, PVA, and PrH. PVA of the hypothalamus region is of particular interest, as previous studies, including a PET-CT brain imaging study by Zeng et al., have shown that the hypothalamus, insula, and ACC have been considered as key regions of the brain-gut axis [8] and that activations of these areas have been shown in studies for most gastrointestinal diseases [48]. The hypothalamus PVA has been shown in previous studies to play a role on its own in the regulation of appetite through the release of Neuropeptide Y (NPY) [49, 50], as well as in the regulation of thirst [51]. Functional connections between the insula and PVA were not exhibited in the FD model group but were exhibited in the FD acupuncture group. Therefore, the connection between insula and PVA may be part of the mechanism which improves food and water intake as part of acupuncture treatment of FD. Together with the results related to the hippocampus region discussed earlier in this paper, our results suggest that functional connections between the insula and the CA3, PoDG, and PVA regions are regulated through EA treatment in FD.
The functional connection results of the FD model (Table 1) and FD acupuncture groups (Table 2) indicate that different brain regions are activated in the two groups and that the only common active regions in the two groups are CA3 and PoDG of the hippocampus. Even though the importance of the CA3 and PoDG regions had been discussed earlier in this section, the observation of differing brain regions between two groups warrants attention. While it may be simple to hypothesize that the functional connections between the insula and brain regions in FD model patients would be reversed after EA intervention, both our results and those of prior studies have shown that this is not the case. One reason for this difference may be due to the way that compensatory strategies are used in healing of the brain. Hylin et al. examine the healing of brain injuries in their review and suggest that the brain is able to intrinsically react to change by inducing new growth pathways which help neurons near and distant from the affected area to survive, repair, and form new connections in order to achieve compensation or recovery [52]. Likewise, it is possible that EA intervention in our FD acupuncture group could contribute to a similar effect through compensation, thus resulting in the differences in brain regions, and this could be an area of research for future studies.
3.6.3. Limitations
With regard to limitations, although our results indicated functional connections between the insula and different brain areas in FD rats using fMRI technology, they do not provide insight into chemical composition of the definite pathways between the insula and these brain regions. This latter consideration was outside the scope of our current study, and so we did not include it in our submission but is part of ongoing trials in our research group. In order to further explore the key role of the insula in the central mechanism behind EA efficacy of gastrointestinal regulation, our research group used the same method of FD rat modeling for analysis and concentrations of important metabolites in the insula between control, FD model, and FD acupuncture groups through magnetic resonance spectroscopy (MRS) instead of fMRI, so as to analyze the chemical composition of our suggested central mechanism [53]. The results from Long showed that, after EA treatment using stomach front-mu and back-shu points, concentrations of N-acetylaspartate (NAA), aspartic acid (Asp), and glycine (Gly) decreased significantly. These results suggest changes in chemical composition of the insula in FD rats after EA treatment and serve as a preliminary investigation into the chemical composition of the insular pathway in the treatment of FD.
4. Conclusions
In conclusion, our study aimed to explore the role of the insula in the EA treatment of FD through rs-fMRI seed-based functional connectivity analysis. The results showed the following: (a) in our two-phase multiple feature rat FD models created using iodoacetamide-sucrose administration, tail clamping, and irregular feeding, EA intervention using RN-12 and BL-21 successfully improved several measures in our rat FD models, including general observations, increased food and water intake, and improved gastric motility and, (b) after EA intervention, a number of both increasing and decreasing functional connections were seen between the insula and a number of brain regions, in particular the hippocampal CA3 and PoDG regions which are related to injury healing, and the hypothalamus PVA region which regulates thirst and appetite, and these may be parts of the central mechanism through which EA expresses its efficacy in the treatment of FD. One significant question raised in our study is that although the insula was shown to play a role in EA treatment of FD, both the magnitude and exclusiveness of its role are unknown. A potential subsequent step in this area of research would be to try and determine the magnitude and exclusivity of the role of the insula by blocking insular cortex function in rat FD models and then observing whether there are changes in the efficacy of EA intervention to see whether other action mechanisms are at work.
Authors’ Contributions
Yuan Chen, Ying Zhao, and Robert Yu-Sheng Tan contributed equally to this work. Yuan Chen, Ying Zhao, and Robert Yu-Sheng Tan designed the study. Hua-bin Zheng was responsible for the planning of the statistical analysis. Yuan Chen, Ying Zhao, and Robert Yu-Sheng Tan wrote the first draft of the manuscript. Tao Long, Pu-yue Zhang, and Yu Shi designed and completed the whole animal experiment. All authors participated in the revision, reading, and approval of the submitted version.
Acknowledgments
This paper was financially supported by National Natural Science Fund of China Youth Foundation Project (no. 81603707) and Chengdu University of TCM “Xinglin Scholar” Disciplinary Talent Plan (no. 030041102) and the authors are grateful to them.
[1] Y. Guo, W. Wei, J. D. Chen, "Effects and mechanisms of acupuncture and electroacupuncture for functional dyspepsia: a systematic review," World Journal of Gastroenterology, vol. 26 no. 19, pp. 2440-2457, DOI: 10.3748/wjg.v26.i19.2440, 2020.
[2] S. Mahadeva, K.-L. Goh, "Epidemiology of functional dyspepsia: a global perspective," World Journal of Gastroenterology, vol. 12 no. 17, pp. 2661-2666, DOI: 10.3748/wjg.v12.i17.2661, 2006.
[3] J. Tack, R. Bisschops, G. Sarnelli, "Pathophysiology and treatment of functional dyspepsia," Gastroenterology, vol. 127 no. 4, pp. 1239-1255, DOI: 10.1053/j.gastro.2004.05.030, 2004.
[4] B. E. Lacy, N. J. Talley, G. R. Locke, E. P. Bouras, J. K. DiBaise, H. B. El-Serag, B. P. Abraham, C. W. Howden, P. Moayyedi, C. Prather, "Review article: current treatment options and management of functional dyspepsia," Alimentary Pharmacology & Therapeutics, vol. 36 no. 1,DOI: 10.1111/j.1365-2036.2012.05128.x, 2012.
[5] E. C. Nista, M. Candelli, F. Cremonini, I. A. Cazzato, M. A. Zocco, F. Franceschi, G. Cammarota, G. Gasbarrini, A. Gasbarrini, "Bacillus clausii therapy to reduce side-effects of anti-helicobacter pylori treatment: randomized, double-blind, placebo controlled trial," Alimentary Pharmacology & Therapeutics, vol. 20 no. 10, pp. 1181-1188, DOI: 10.1111/j.1365-2036.2004.02274.x, 2004.
[6] S. M. Wilhelm, R. G. Rjater, P. B. Kale-Pradhan, "Perils and pitfalls of long-term effects of proton pump inhibitors," Expert Review of Clinical Pharmacology, vol. 6 no. 4, pp. 443-451, DOI: 10.1586/17512433.2013.811206, 2013.
[7] B. Pang, T. Jiang, Y.-H. Du, J. Li, B. Li, Y.-C. Hu, Q.-H. Cai, "Acupuncture for functional dyspepsia: what strength does it have? A systematic review and meta-analysis of randomized controlled trials," Evidence-based Complementary and Alternative Medicine, vol. 2016,DOI: 10.1155/2016/3862916, 2016.
[8] F. Zeng, W. Qin, T. Ma, J. Sun, Y. Tang, K. Yuan, Y. Li, J. Liu, X. Liu, W. Song, L. Lan, M. Liu, S. Yu, X. Gao, J. Tian, F. Liang, "Influence of acupuncture treatment on cerebral activity in functional dyspepsia patients and its relationship with efficacy," American Journal of Gastroenterology, vol. 107 no. 8, pp. 1236-1247, DOI: 10.1038/ajg.2012.53, 2012.
[9] P. Liu, Y. Fan, Y. Wei, F. Zeng, R. Li, N. Fei, W. Qin, "Altered structural and functional connectivity of the insula in functional dyspepsia," Neuro-Gastroenterology and Motility, vol. 30 no. 9,DOI: 10.1111/nmo.13345, 2018.
[10] F. Zeng, W. Z. Song, X. G. Liu, H. J. Xie, Y. Tang, B. C. Shan, Z. H. Liu, S. G. Yu, F. R. Liang, "Brain areas involved in acupuncture treatment on functional dyspepsia patients: a PET-CT study," Neuroscience Letters, vol. 456 no. 1,DOI: 10.1016/j.neulet.2009.03.080, 2009.
[11] Y. Ye, X. R. Wang, Y. Zheng, J. W. Yang, N. N. Yang, G. X. Shi, C. Z. Liu, "Choosing an animal model for the study of functional dyspepsia," Canadian Journal of Gastroenterology & Hepatology, vol. 2018,DOI: 10.1155/2018/1531958, 2018.
[12] F. Zeng, W. Qin, F. Liang, J. Liu, Y. Tang, X. Liu, K. Yuan, S. Yu, W. Song, M. Liu, L. Lan, X. Gao, Y. Liu, J. Tian, "Abnormal resting brain activity in patients with functional dyspepsia is related to symptom severity," Gastroenterology, vol. 141 no. 2, pp. 499-506, DOI: 10.1053/j.gastro.2011.05.003, 2011.
[13] J. Fang, D. Wang, Q. Zhao, Y. Hong, Y. Jin, Z. Liu, K. Zhou, X. Jing, X. Yu, R. Pan, A. Chang, H. Liu, B. Zhu, "Brain-gut axis modulation of acupuncture in functional dyspepsia: a preliminary resting-state fcMRI study," Evidence-Based Complementary and Alternative Medicine, vol. 2015,DOI: 10.1155/2015/860463, 2015.
[14] P. Liu, W. Qin, J. Wang, F. Zeng, G. Zhou, H. Wen, K. M. von Deneen, F. Liang, Q. Gong, J. Tian, "Identifying neural patterns of functional dyspepsia using multivariate pattern analysis: a resting-state FMRI study," PLoS One, vol. 8 no. 7,DOI: 10.1371/journal.pone.0068205, 2013.
[15] G. Zhou, P. Liu, J. Wang, H. Wen, M. Zhu, R. Zhao, K. M. von Deneen, F. Zeng, F. Liang, Q. Gong, W. Qin, J. Tian, "Fractional amplitude of low-frequency fluctuation changes in functional dyspepsia: a resting-state fMRI study," Magnetic Resonance Imaging, vol. 31 no. 6, pp. 996-1000, DOI: 10.1016/j.mri.2013.03.019, 2013.
[16] L. Q. Uddin, J. S. Nomi, B. Hébert-Seropian, J. Ghaziri, O. Boucher, "Structure and function of the human insula," Journal of Clinical Neurophysiology, vol. 34 no. 4, pp. 300-306, DOI: 10.1097/wnp.0000000000000377, 2017.
[17] L. Yi, H. Sun, C. Ge, Y. Chen, H. Peng, Y. Jiang, P. Wu, Y. Tang, Q. Meng, S. Xu, "Role of insular cortex in visceral hypersensitivity model in rats subjected to chronic stress," Psychiatry Research, vol. 220 no. 3, pp. 1138-1143, DOI: 10.1016/j.psychres.2014.09.019, 2014.
[18] S.-I. Ito, "Visceral region in the rat primary somatosensory cortex identified by vagal evoked potential," The Journal of Comparative Neurology, vol. 444 no. 1, pp. 10-24, DOI: 10.1002/cne.10120, 2002.
[19] H. Wang, G.-M. Shen, W.-J. Liu, S. Huang, M.-T. Zhang, "The neural mechanism by which the dorsal vagal complex mediates the regulation of the gastric motility by Weishu (RN12) and zhongwan (BL21) stimulation," Evidence-Based Complementary and Alternative Medicine, vol. 2013,DOI: 10.1155/2013/291764, 2013.
[20] H. Wang, W.-J. Liu, G.-M. Shen, M.-T. Zhang, S. Huang, Y. He, "Neural mechanism of gastric motility regulation by electroacupuncture at RN12 and BL21: a paraventricular hypothalamic nucleus-dorsal vagal complex-vagus nerve-gastric channel pathway," World Journal of Gastroenterology, vol. 21 no. 48, pp. 13480-13489, DOI: 10.3748/wjg.v21.i48.13480, 2015.
[21] H. Wang, W.-J. Liu, M.-J. Hu, M.-T. Zhang, G.-M. Shen, "Acupuncture at gastric back-shu and front-mu acupoints enhances gastric motility via the inhibition of the glutamatergic system in the Hippocampus," Evidence-Based Complementary and Alternative Medicine, vol. 2020,DOI: 10.1155/2020/3524641, 2020.
[22] T.-H. Ren, J. Wu, D. Yew, E. Ziea, L. Lao, W.-k. Leung, B. Berman, P.-j. Hu, J. J. Y. Sung, "Effects of neonatal maternal separation on neurochemical and sensory response to colonic distension in a rat model of irritable bowel syndrome," American Journal of Physiology-Gastrointestinal and Liver Physiology, vol. 292 no. 3, pp. G849-G856, DOI: 10.1152/ajpgi.00400.2006, 2007.
[23] Z. Wu, X. Lu, S. Zhang, C. Zhu, "Sini-san regulates the NO-cGMP-PKG pathway in the spinal dorsal horn in a modified rat model of functional dyspepsia," Evidence-Based Complementary and Alternative Medicine, vol. 2020,DOI: 10.1155/2020/3575231, 2020.
[24] C. Zhu, L. Zhao, J. Zhao, "Sini San ameliorates duodenal mucosal barrier injury and low-grade inflammation via the CRF pathway in a rat model of functional dyspepsia," International Journal of Molecular Medicine, vol. 45 no. 1, pp. 53-60, 2020.
[25] L. S. Liu, J. H. Winston, M. M. Shenoy, G. Q. Song, J. D. Z. Chen, P. J. Pasricha, "A rat model of chronic gastric sensorimotor dysfunction resulting from transient neonatal gastric irritation," Gastroenterology, vol. 134 no. 7, pp. 2070-2079, DOI: 10.1053/j.gastro.2008.02.093, 2008.
[26] H. Li, Q. Liang, Y. Yan, L. Mao, X. Du, J. Liang, J. Liu, L. Wang, "Evaluation of a modified rat model for functional dyspepsia," Saudi Journal of Gastroenterology, vol. 24 no. 4, pp. 228-235, DOI: 10.4103/sjg.sjg_505_17, 2018.
[27] Y. Yang, P. Xu, Y. Xin, Z. Kang, H. Zhang, L. Zhou, "Involvement of neurotensin-mediated brain-gut Axis in electroacupuncture intervention induced improvement of functional dyspepsia in rats," Zhenciyanjiu, vol. 41 no. 1, pp. 35-39+50, 2016.
[28] M. Ling, C. Li, Y. Ba, "Effect of Baoshen No.1 cataplasm on ET-1 in rats with chronic renal failure," Hubei Journal of traditional Chinese medicine, vol. 35 no. 1, pp. 22-23, 2013.
[29] B. Nie, J. Hui, L. Wang, P. Chai, J. Gao, S. Liu, Z. Zhang, B. Shan, S. Zhao, "Automatic method for tracing regions of interest in rat brain magnetic resonance imaging studies," Journal of Magnetic Resonance Imaging, vol. 32 no. 4, pp. 830-835, DOI: 10.1002/jmri.22283, 2010.
[30] J. Francis, D. Critchley, C. T. Dourish, S. J. Cooper, "Comparisons between the effects of 5-HT and DL-fenfluramine on food intake and gastric emptying in the rat," Pharmacology, Biochemistry, and Behavior, vol. 50 no. 4, pp. 581-585, DOI: 10.1016/0091-3057(94)00344-0, 1995.
[31] I. U. Asuzu, J. C. Njoku, "The pharmacological properties of the ethanolic root extract of Combretum dolichopetalum," Phytotherapy Research, vol. 6 no. 3, pp. 125-128, 2010.
[32] I.-S. Lee, H. Wang, Y. Chae, H. Preissl, P. Enck, "Functional neuroimaging studies in functional dyspepsia patients: a systematic review," Neuro-Gastroenterology and Motility, vol. 28 no. 6, pp. 793-805, DOI: 10.1111/nmo.12793, 2016.
[33] S. Zhang, L. Lin, W. Liu, B. Zou, Y. Cai, D. Liu, D. Xiao, J. Chen, P. Li, Y. Zhong, Q. Liao, Z. Xie, "Shen-Ling-Bai-Zhu-San alleviates functional dyspepsia in rats and modulates the composition of the gut microbiota," Nutrition Research, vol. 71, pp. 89-99, DOI: 10.1016/j.nutres.2019.10.001, 2019.
[34] H. Li, T. He, Q. Xu, Z. Li, Y. Liu, F. Li, B.-F. Yang, C.-Z. Liu, "Acupuncture and regulation of gastrointestinal function," World Journal of Gastroenterology, vol. 21 no. 27, pp. 8304-8313, DOI: 10.3748/wjg.v21.i27.8304, 2015.
[35] L. Van Oudenhove, J. Vandenberghe, P. Dupont, B. Geeraerts, R. Vos, S. Dirix, K. Van Laere, G. Bormans, D. Vanderghinste, K. Demyttenaere, B. Fischler, J. Tack, "Regional brain activity in functional dyspepsia: a H215O-PET study on the role of gastric sensitivity and abuse history," Gastroenterology, vol. 139 no. 1, pp. 36-47, DOI: 10.1053/j.gastro.2010.04.015, 2010.
[36] L. Zhou, Y.-p. Cheng, "Effect of electroacupuncture on expression of ghrelin and mRNA expression of its receptor in functional dyspesia rats," Zhongguo Zhong Xi Yi Jie He Za Zhi, vol. 36 no. 3, pp. 322-326, 2016.
[37] J.-H. Cho, B. S. Huang, J. M. Gray, "RNA sequencing from neural ensembles activated during fear conditioning in the mouse temporal association cortex," Scientific Reports, vol. 6 no. 1,DOI: 10.1038/srep31753, 2016.
[38] R. P. Dhond, C. Yeh, K. Park, N. Kettner, V. Napadow, "Acupuncture modulates resting state connectivity in default and sensorimotor brain networks," Pain, vol. 136 no. 3, pp. 407-418, DOI: 10.1016/j.pain.2008.01.011, 2008.
[39] F. Torrealba, J. L. Valdés, "The parietal association cortex of the rat," Biological Research, vol. 41 no. 4, pp. 369-377, DOI: 10./S0716-97602008000400002, 2008.
[40] L. Albrechet-Souza, K. G. Borelli, R. C. Almada, M. L. Brandão, "Midazolam reduces the selective activation of the rhinal cortex by contextual fear stimuli," Behavioural Brain Research, vol. 216 no. 2, pp. 631-638, DOI: 10.1016/j.bbr.2010.09.006, 2011.
[41] D. G. Amaral, H. E. Scharfman, P. Lavenex, "The dentate gyrus: fundamental neuroanatomical organization (dentate gyrus for dummies)," Progress in Brain Research, vol. 163,DOI: 10.1016/S0079-6123(07)63001-5, 2007.
[42] M. W. Brown, J. P. Aggleton, "Recognition memory: what are the roles of the perirhinal cortex and hippocampus?," Nature Reviews Neuroscience, vol. 2 no. 1, pp. 51-61, DOI: 10.1038/35049064, 2001.
[43] J. Jin, S. Maren, "Prefrontal-hippocampal interactions in memory and emotion," Frontiers in Systems Neuroscience, vol. 9,DOI: 10.3389/fnsys.2015.00170, 2015.
[44] A. K. Shetty, M. S. Rao, B. Hattiangady, V. Zaman, G. A. Shetty, "Hippocampal neurotrophin levels after injury: relationship to the age of the hippocampus at the time of injury," Journal of Neuroscience Research, vol. 78 no. 4, pp. 520-532, DOI: 10.1002/jnr.20302, 2004.
[45] Y. Song, G. X. Han, L. Chen, Y. Z. Zhai, J. Dong, W. Chen, T. S. Li, H. Y. Zhu, "The role of the hippocampus and the function of calcitonin gene-related peptide in the mechanism of traumatic brain injury accelerating fracture-healing," European Review for Medical and Pharmacological Sciences, vol. 21 no. 7, pp. 1522-1531, 2017.
[46] G. Scuppa, S. Tambalo, S. Pfarr, W. H. Sommer, A. Bifone, "Aberrant insular cortex connectivity in abstinent alcohol-dependent rats is reversed by dopamine D3 receptor blockade," Addiction Biology, vol. 25 no. 3,DOI: 10.1111/adb.12744, 2020.
[47] A. Maffei, M. Haley, A. Fontanini, "Neural processing of gustatory information in insular circuits," Current Opinion in Neurobiology, vol. 22 no. 4, pp. 709-716, DOI: 10.1016/j.conb.2012.04.001, 2012.
[48] E. A. Mayer, K. Tillisch, "The brain-gut axis in abdominal pain syndromes," Annual Review of Medicine, vol. 62 no. 1, pp. 381-396, DOI: 10.1146/annurev-med-012309-103958, 2011.
[49] S. P. Kalra, M. G. Dube, A. Sahu, C. P. Phelps, P. S. Kalra, "Neuropeptide Y secretion increases in the paraventricular nucleus in association with increased appetite for food," Proceedings of the National Academy of Sciences, vol. 88 no. 23, pp. 10931-10935, DOI: 10.1073/pnas.88.23.10931, 1991.
[50] B. A. Newmyer, W. Nandar, R. I. Webster, E. Gilbert, P. B. Siegel, M. A. Cline, "Neuropeptide Y is associated with changes in appetite-associated hypothalamic nuclei but not food intake in a hypophagic avian model," Behavioural Brain Research, vol. 236 no. 1, pp. 327-331, DOI: 10.1016/j.bbr.2012.08.015, 2013.
[51] D. E. Leib, C. A. Zimmerman, Z. A. Knight, "Thirst," Current Biology, vol. 26 no. 24, pp. R1260-R1265, DOI: 10.1016/j.cub.2016.11.019, 2016.
[52] M. J. Hylin, A. L. Kerr, R. Holden, "Understanding the mechanisms of recovery and/or compensation following injury," Neural Plasticity, vol. 2017,DOI: 10.1155/2017/7125057, 2017.
[53] T. Long, "The study on the metabolites in insula of rats with functional dyspepsia upon the impact of acupuncture," , 2019. Masters dissertation
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Abstract
Functional Dyspepsia (FD) is a common functional gastrointestinal disease, which can reduce the quality of life in patients. Prior research has indicated that insula is closely related to FD and that acupuncture can regulate the functional connectivity (FC) of FD. Therefore, we hypothesized that acupuncture on FD was effected through the insular pathway. To test our hypothesis, we performed electroacupuncture (EA) on FD rat models and then examined the FC between insula and other brain regions through resting-state functional magnetic resonance imaging (rs-fMRI). Seven-day-old male infant Sprague-Dawley (SD) rats were randomly divided into control group, FD model group, and FD acupuncture group, with twelve rats per group (n = 36). Upon establishing successful models, the FD acupuncture group was subjected to EA intervention using Stomach back-shu (BL-21) and front-mu (RN-12) points for ten consecutive days for durations of 20 minutes each day. After intervention, each group was subject to rs-fMRI. The digital image data obtained were analyzed using FC analysis methods. Subsequently, gastric ligation was performed to measure gastric emptying rates. Before EA intervention, the FD model group exhibited decreased functional connections between the insula and a number of brain regions. After EA intervention, FD acupuncture group exhibited increasing FC between insula and regions when compared to the FD model group, such as the primary somatosensory cortex (S1), hippocampal CA3 (CA3), polymorphic layer of dentate gyrus (PoDG), caudate putamen (CPu), and oral pontine reticular nuclei (PnO)
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Details
; Zhao, Ying 1
; Robert Yu-Sheng Tan 1
; Pu-yue, Zhang 1
; Long, Tao 1 ; Shi, Yu 2
; Hua-bin, Zheng 3
1 Acupuncture and Tuina School, Chengdu University of Traditional Chinese Medicine, Chengdu, China
2 Department of Oncology, Chongqing Beibei Traditional Chinese Medical Hospital, Chongqing, China
3 Department of Acupuncture and Moxibustion, Affiliated Hospital of Chengdu University of Traditional Chinese Medicine, Chengdu 610072, China