Efficacy and Safety of Herbal Medicine Treatment on Post-Surgical Recovery in Gastric Cancer Patients: A Systematic Review and Meta-Analysis

Soo-Dam Kim; Sook-Jin Pyo; Dong-Hyun Kim; Hwa-Seung Yoo; So-Jung Park

doi:10.20944/preprints202405.1198.v1

Submitted:

17 May 2024

Posted:

20 May 2024

You are already at the latest version

Abstract

Background: Gastric cancer (GC) is the second most prevalent cancer in Korea, significantly impacting morbidity and mortality. While advancements in early detection and treatment have improved survival rates, managing post-surgical recovery remains vital. Herbal medicine (HM) has emerged as a potential adjunct therapy to enhance recovery and quality of life (QoL) in patients post-GC surgery. Methods: This systematic review and meta-analysis evaluated the efficacy and safety of HM in the post-surgical recovery of GC patients. We searched both Korean and international databases, identifying 16 randomized controlled trials (RCTs) meeting our criteria. We assessed study quality using the Cochrane Risk of Bias tool and analyzed data with Review Manager Software (RevMan). Results: Our analysis included 1,546 patients from the selected studies, demonstrating that HM significantly improved gastrointestinal recovery times, including time to first flatus, bowel movement, and return of bowel sounds. Significant improvements were also seen in nutritional markers such as albumin and prealbumin, alongside beneficial effects on immune markers like CD3+ and CD4+ levels. QoL assessments using WHOQOL-BREF and QLQ-C30 scores indicated substantial improvements. HM had a favorable safety profile, showing a reduced incidence of adverse effects compared to controls. Conclusion: The findings suggest that HM can significantly enhance recovery and improve the quality of life following gastric cancer surgery, with a favorable safety profile. However, due to considerable heterogeneity in study results, extended clinical trials and rigorous follow-ups are recommended to assess long-term effects and side effects comprehensively.

Keywords:

gastric cancer

;

herbal medicine

;

post-surgical recovery

;

systematic review

;

meta-analysis

Subject:

Medicine and Pharmacology - Oncology and Oncogenics

1. Introduction

Gastric cancer (GC) includes all cancers arising in the stomach. Gastric adenocarcinoma, the predominant form of stomach cancer, originates from the glandular cells of the gastric mucosa [1]. According to the 2022 National Cancer Center survey data, GC is the second most prevalent cancer in Korea. It has a mortality rate of 8.6%, amounting to 71,747 individuals, and ranks fifth among all cancer deaths. The disease prevalence is 14.5%, affecting 330,217 people, with a leading incidence among men at 21.8% (217,881 individuals) and ranking fourth among women at 8.8% (112,336 individuals) [2].

Early diagnosis and intervention play pivotal roles in enhancing the survival and quality of life (QoL) of patients with GC [3]. In Korea, a national cancer screening initiative, initiated in 1999, subjects adults over 40 to upper gastrointestinal endoscopy or upper gastrointestinal tract surgery every 2 years. This effort has contributed to a notable decline in GC mortality, which has dropped to 13.5% in 2021 from 56.3% in 1997. Furthermore, the five-year relative survival rate for GC shows a consistent annual increase. The five-year relative survival rate for GC reached 78.0% in 2016-2020, marking a notable increase of 9.6 percentage points compared to 2006-2010 and a further 2.1 percentage points compared to 2011-2015. Patients with early-stage GC undergoing surgery exhibit a favorable prognosis, boasting a 5-year survival rate exceeding 90% [2]. As survival rates rise, recent studies highlight the growing significance of patient recovery and nutritional management post-surgery.

With advancements in GC surgical technologies, patients with early GC and low risk of lymph node metastasis undergo endoscopic resection (ER), and those who are ineligible for ER undergo gastrectomy [4]. Many patients experience post-surgical side effects like dumping syndrome, bile reflux, anastomotic leak, gastritis, and weight loss [5]. A previous study found that of 134 post-GC surgery patients, 50% experienced a decline in QoL compared to pre-surgery, and 1/3rd witnessed continuous deterioration even 6 months post-surgery [6].

Recent studies spotlight the role of herbal medicine (HM) in post-surgical gastric cancer treatment. In Taiwan in 2020, Wei-Tai Shih et al. explored HM's impact on the survival of patients with GC undergoing chemotherapy post-surgery. Prolonged HM treatment correlated with higher survival rates and reduced chemotherapy side effects [7]. Similarly, Japanese research on Rikkunshito, a traditional HM, demonstrated notable enhancements in post-proximal gastrectomy patients' quality of life and gastrointestinal function [8]. These studies underscore HM's potential to significantly augment recovery and enhance outcomes for post-surgical gastric cancer patients.

However, the landscape of HM in the context of post-surgical recovery in patients with GC remains incompletely explored. While previous systematic review studies have examined HM in conjunction with chemotherapy or other HM treatments like acupuncture and moxibustion after GC surgery, none have exclusively focused on HM post-surgery. This knowledge gap necessitates a systematic review and meta-analysis to assess the effectiveness and safety of HM in fortifying post-surgical recovery among patients with GC. Therefore, our study aims to comprehensively review the impact of HM alone on patients following GC surgery.

2. Methods

2.1. Objective and Strategy

This study aimed to systematically review the research literature, understand Korean Medicine and Western medicine GC treatments, and suggest directions for future clinical guidelines. The study protocol has been registered on PROSPERO with the registration number CRD42022354133.

A literature search was conducted for studies related to Korean Medicine GC treatment published until July 31, 2023, on search engines including Korean web databases KMBASE, KISS, OASIS, RISS, and ScienceOn and international web databases such as EMBASE, Medline, Pubmed, CNKI, and CiNii. The search of the PubMed database, which was searched in the corresponding database, yielded the search results provided in Table 1. This research solely focused on electronic searches. There were 16 papers that satisfied all the inclusion and exclusion conditions.

2.2. Selection of Studies

The collected research papers were organized using a literature management program (EndNote 20) and a spreadsheet program (Excel). The selection and analysis of documents were independently carried out by 2 researchers (SJP, KSD). In instances of disagreement, particularly during the full-text review stage of the final paper, the researchers resolved differences through a thorough discussion and arrived at a consensus on the ultimate selection.

2.3. Quality Assessment

To evaluate the literature's quality, the risk of bias in Randomized Controlled Trials (RCTs) was assessed using Cochrane’s Risk of Bias (RoB) tool. Two researchers (SJP, KSD) independently conducted the risk of bias assessment for the RCT literature. Discrepancies and agreements between evaluators were then analyzed through researcher meetings, where both researchers participated together.

Cochrane’s RoB tool for 25 quantitative papers comprises seven items covering aspects such as random allocation sequence generation, allocation sequence concealment, blinding of study participants and researchers, blinding of outcome evaluation, insufficient outcome data, selective reporting, and other biases. For one qualitative paper, Cochrane’s RoB tool is designed to assess bias risk with three response options: low, high, and uncertain. The tool was translated into Korean to minimize variations in evaluation criteria between evaluators. The overall results were meta-analyzed using Review Manager Software 5.4 (RevMan).

2.4. Data Analysis

Among the literature subjected to analysis, 25 papers presented the mean and standard deviation of outcome variables for the intervention group, where patients with GC were treated with gastrectomy and HM, and a control group without HM treatment. These papers were thoroughly reviewed using RevMan. If the number of included studies was over 10, meta-analysis publication bias was assessed using funnel plots.

In our research, we used the risk ratio (RR) along with its 95% confidence interval (CI) for the analysis of dichotomous data. For continuous data, we utilized mean differences (MD) with a 95% CI, especially when treatment outcomes were measured on an identical scale. In cases where units of measurement varied across studies, we employed the standardized mean difference (SMD) with a 95% CI to ensure a uniform assessment of effect sizes.

To gauge heterogeneity within the study, we calculated Higgins' I². A value of I² exceeding 50% was interpreted as a significant indicator of substantial heterogeneity. The selected evaluation indicators encompassed gastrointestinal recovery, nutritional markers, immune markers, inflammatory markers, quality of life, and adverse effects.

3. Results

3.1. Study Selection

Figure 1. PRISMA Flowchart. RCT: randomized controlled trial.

3.2. Study Characteristics

This meta-analysis, finalized before 2023, collated data from 16 randomized controlled trials involving a total of 1,546 patients diagnosed with GC. These studies examined the efficacy and safety of HM interventions. While participants in the experimental groups were treated with HM, those in the control groups received standard care, placebos, or the established usual care protocols. The treatments spanned a range of durations, from 3 days to months. The study assessed gastrointestinal (GI) recovery, evaluated nutritional markers including TP (Total Protein), PA (Prealbumin), ALB (Albumin), and TRF (Transferrin), measured specific immune markers such as CD4+ and CD8+ cell counts, analyzed the inflammatory marker CRP, gauged participants' QoL using scales such as SF-36 and QLQ-C30, and recorded adverse effects as a measure of safety (Table 2).

3.3. Risk of Bias in Included Trials

In our review, based on the Cochrane bias risk assessment, we identified a significant risk of bias due to insufficient methodological explanations (Figure 2). Each study properly utilized random sequence generation [9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24]. However, 10 studies lacked clarity regarding allocation concealment, leading to an uncertain bias risk evaluation [9,10,17,18,19,20,21,22,23,24]. Aside from one study that implemented a placebo [14], there was a high risk of performance and detection bias in 15 trials, as only the experimental group was treated with HM [9,10,11,12,13,15,16,17,18,19,20,21,22,23,24]. Except for one study with a confirmed protocol registration [23], all other studies did not report their pre-registered plans, leading to an unclear risk of reporting bias. Fortunately, we deemed all studies to have minimal risk concerning attrition and other possible biases (Figure 3).

3.4. Gastrointestinal Recovery

3.4.1. Time to First Flatus (h)

In nine randomized controlled trials, the effect of HM on the time to first flatus after gastric cancer surgery was assessed [10,11,13,14,16,17,18,20,22]. The pooled results from these trials showed that patients who were treated with HM experienced a noticeable enhancement in the time to first flatus. This benefit was highlighted by an MD of -8.38 (95% CI [11.70, -5.06], I² = 84%, P < .00001, n = 838, Figure 4).

3.4.2. Time to First Bowel Movement (h)

Seven randomized controlled trials investigated the influence of HM on the first bowel movement as a parameter for GI recovery following gastric cancer surgery [10,11,13,16,18,20,22]. The consolidated data from these studies demonstrated a significant improvement for those patients who received HM treatment with MD -10.10 (95% CI [-16.52, -3.68], I² = 94%, P = .002, n = 696, Figure 5).

3.4.3. Time to Bowel Sounds Return (h)

Seven randomized controlled trials assessed the effect of HM on the time to bowel sounds return after gastric cancer surgery [10,11,14,16,17,18,20]. The synthesized results from these studies indicate a significant reduction in the time for bowel sounds to return in patients who received HM treatment. The consolidated data from these studies demonstrated that patients who received HM treatment showed a significant improvement in the time to bowel sounds return, as evidenced by an MD of -7.84 (95%CI [-12.07, -3.62], I² = 94%, P = .0003, n = 674, Figure 6).

3.5. Nutritional Markers

Several randomized controlled trials evaluated the influence of HM on various nutritional markers in post-gastric cancer surgery patients. The assessment encompassed markers like ALB, TRF, PA, and TP.

3.5.1. Albumin Levels

Six randomized controlled trials assessed the impact of HM on the nutritional markers, specifically ALB, in patients post-gastric cancer surgery [9,10,12,13,21,22]. An analysis of the combined data indicated that patients treated with HM exhibited a notable increase in ALB levels compared to the control group. The compiled results from these investigations indicated that patients administered with HM treatment exhibited a notable enhancement in ALB levels, supported by an MD of 1.83 (95% CI [0.76, 2.90], I² = 80%, P = .0008, n = 532, Table 3).

3.5.2. Transferrin Levels

The consolidated data from the selected studies indicated a variation in TRF levels in patients treated with HM [9,10,12]. This variation is emphasized by an SMD of 1.89 (95% CI [0.17, 3.96], I² = 98%, P = .07, n = 306, Table 3). However, there was substantial heterogeneity among the studies, and the results were not significant.

3.5.3. Prealbumin Levels

The compiled data from the studies showcased a pronounced improvement in PA levels in patients treated with HM [9,10], even though there was considerable heterogeneity among the studies, with an MD of 36.70 (95% CI [18.53, 54.87], I² = 83%, P < .0001, n = 216, Table 3).

3.5.4. Total Protein Levels

The gathered data from the included studies highlight a clear elevation of TP levels in patients who were administered HM [10,22]. This was demonstrated by an MD of 2.18 (95% CI [0.49, 3.86], I² = 0%, P = .01, n = 176, Table 3). Notably, the studies showed no heterogeneity, suggesting a consistent positive effect of HM on TP levels.

Table 3. Nutritional Markers of HM in Post-gastric Cancer Surgery Patients.

Nutritional markers	Studies	Participants	Effect Size [95%CI]	P value	Study ID references
ALB	6	532	MD 1.83, 95% CI [0.76, 2.90], I² = 80%	*** P = 0.0008	Chen 2020, Gao 2020, Liu 2016, Liu 2020, Sang 2020, Zou 2016
TRF	3	306	SMD 1.89, 95% CI [0.17, 3.96], I² = 98%	P = 0.07	Gao 2020, Liu 2020, Sang 2020
PA	2	216	MD 36.70, 95% CI [18.53, 54.87], I² = 83%	*** P < 0.0001	Gao 2020, Sang 2020
TP	2	176	MD 2.18, 95% CI [0.49, 3.86], I² = 0%	** P = 0.01	Gao 2020, Liu 2016

** p < 0.01; *** p < 0.001; HM, Herbal Medicine.

3.6. Immune Markers

3.6.1. CD3+ Levels

From the available studies on CD3+ levels in post-gastric cancer surgery patients [10,15,24], it was observed that HM had a notable effect on this immune marker. The consolidated data indicates that patients treated with HM exhibited a marked increase in CD3+ levels when compared to the control group. This observation was validated by an MD of 5.01 (95% CI [2.15, 7.87], I² = 88%, P = .0006, n = 311, Table 4).

3.6.2. CD4+ Levels

The aggregated results from the selected studies showed a significant variation in CD4+ levels in patients administered HM [9,10,15,16,24]. This variance is emphasized by an MD of 4.39 (95% CI [1.91, 6.87], I² = 94%, P = .0005, n = 487, Table 4). The findings suggest a beneficial effect of HM on CD4+ levels in the aforementioned patient group.

3.6.3. CD8+ Levels

The compiled data from the studies indicated no significant difference in CD8+ in patients treated with HM compared to the control [9,15,16]. The pooled findings showed an MD of -1.13 (95% CI [-4.28, 2.02], I² = 97%, P = .48, n = 293, Table 4), emphasizing the lack of significance and substantial heterogeneity among the studies.

3.6.4. CD4+/CD8+ Ratio

The aggregated data from the studies suggests that there was no statistically significant improvement in the CD4+/CD8+ ratio for patients treated with HM [9,10,15,16]. The pooled results show a MD of 0.49 (95% CI [0.01, 0.91], I² = 99%, P = .06, n = 389, Table 4). Despite the considerable heterogeneity among the studies, it is important to note that the results were not significant.

Table 4. Immune Markers of HM in Post-gastric Cancer Surgery Patients.

Immune markers	Studies	Participants	Effect Size [95%CI]	P value	Study ID references
CD3+	3	311	MD 5.01, 95% CI [2.15, 7.87], I² = 88%	*** P = 0.0006	Gao 2020, Liu 2018, Ma 2018
CD4+	4	487	MD 4.39, 95% CI [1.91, 6.87], I² = 94%	*** P = 0.0005	Gao 2020, Guo 2018, Liu 2018, Sang 2020
CD8+	3	293	MD -1.13, 95% CI [-4.28, 2.02], I² = 97%	P = 0.48	Guo 2018, Ma 2018, Sang 2020
CD4+/CD8+	3	389	MD 0.49, 95% CI [0.01, 0.91], I² = 99%	P = 0.06	Gao 2020, Guo 2018, Sang 2020

*** p < 0.001; HM, Herbal Medicine.

3.7. Inflammatory Markers

Two randomized controlled trials explored the potential effects of HM on inflammatory markers [10,13], specifically focusing on CRP levels in the context of medical interventions. The comprehensive data analysis indicates that there was no statistically significant difference in CRP levels for patients in the HM group compared to the control group with an MD of -7.55 (95% CI [-21.78, 6.67], I² = 98%, P = .30, n = 180, Figure 7).

3.8. Quality of Life Assessments

3.8.1. SF-36 Score

Based on the studies assessing the SF-36 score, which evaluates general health status and QoL, there was no statistically significant enhancement in scores for patients treated with HM compared to the control group [12,17]. Although the data showed a mean difference of 11.33 favoring HM, the wide confidence interval (95% CI [3.50, 26.17]) and a high heterogeneity (I² = 96%) suggest variability among studies. The P-value of 13 indicates that the results were not statistically significant (Table 5).

3.8.2. WHOQOL-BREF Score

The aggregated results from the studies regarding the WHOQOL-BREF score, an essential tool to measure QoL across various dimensions, revealed significant enhancements in scores for patients administered HM [9]. This is substantiated by an MD of 6.54 (95% CI [5.42, 7.66], P < .00001, n = 60, Table 5). This confirms the positive effects of HM on patients' QoL as measured by the WHOQOL-BREF.

3.8.3. QLQ-C30 Score

With regards to the QLQ-C30 score, which is specifically designed to assess the QoL in cancer patients, the combined results from the included studies indicated a remarkable difference in scores between the HM group and the control [19]. The pooled findings revealed an MD of 18.04 (95% CI [15.87, 20.21], P < .00001, n = 60, Table 5). The results unequivocally favor the HM group, suggesting its efficacy in enhancing the QoL in patients post-gastric cancer surgery.

Table 5. Quality of Life Assessments of HM in Post-gastric Cancer Surgery Patients.

Quality of Life Assessment	Studies	Participants	Effect Size [95%CI]	P value	Study ID references
SF-36	2	172	MD 11.33, 95% CI [3.50, 26.17], I² = 96%	P = 0.13	Ge 2018, Liu 2020
WHOQOL-BREF	1	120	MD 6.54, 95% CI [5.42, 7.66]	*** P < 0.00001	Sang 2020
QLQ-C30	1	120	MD 18.04, 95% CI [15.87, 20.21]	*** P < 0.00001	He 2017

*** p < 0.001; HM, Herbal Medicine.

3.9. Safety

3.9.1. Incidence of Adverse Effects

The safety profile of HM was evaluated based on the incidence of adverse effects and the pooled data from various studies suggests that HM is associated with a reduced risk of adverse effects when compared to the control [12,15,16,18,19,20,21]. The cumulative findings yield an RR of 0.48 with a 95% CI ranging from 0.31 to 0.74. This indicates that patients undergoing HM treatment are approximately half as likely to experience adverse effects as those in the control group (Figure 8).

Notably, the analysis revealed a consistently low heterogeneity among the studies with an I² value of 0%, signifying minimal variability in the results across different studies. The statistical significance of these findings is further emphasized by a P-value of .0009, suggesting a strong association between HM and a reduced risk of adverse effects.

4. Discussion

In the realm of post-surgical care for patients with GC, the management of GI recovery and nutrition plays a pivotal role in improving survival rates and QoL [25,26]. The postoperative hurdles faced by these patients, such as impaired GI function and nutritional deficiencies, profoundly impact their recovery and overall prognosis. This underscores the necessity for innovative and effective treatment approaches [27,28]. In this context, the exploration of alternative treatments, particularly HM, emerges as a promising solution. Prior studies indicate that herbal treatments have the potential to significantly enhance GI function, nutritional status, and immune function, while potentially mitigating complications associated with gastric cancer surgery [29,30]. This study was undertaken to systematically investigate the efficacy of HM in addressing these challenges and assess its impact on the recovery of patients with early GC. The focus areas include GI recovery, nutrition, immune response, and overall QoL. Through the exploration of these critical aspects, the study aims to provide valuable insights into postoperative care for GC, contributing to the existing body of knowledge and investigating alternative therapies that could markedly improve patient outcomes.

Our study evaluated HM's effects on patients with early GC in detail, focusing on GI recovery, nutrition, immune response, and overall QoL. In the GI recovery assessment, we observed significant improvements in patients treated with HM, particularly in the time to first flatus (P < .00001), time to first bowel movement (P = .002), and time to bowel sounds return (P = .0003), compared to the control group. This improvement is crucial as it directly impacts the overall health and recovery speed post-surgery [31].

Nutritionally, our study found significant improvements in ALB, PA, and TP levels among patients with early GC treated with HM, with ALB levels (P = .0008) and PA levels (P < .0001) improving markedly, and TP levels also showing significant enhancements (P = .01). Although the results for TRF were not statistically significant, these overall findings underscore the potential of HM in enhancing the postoperative nutritional status in patients with GC. Proper nutrition is essential for the healing and well-being of post-surgical patients [32].

In terms of immune response, patients with early GC treated with HM showed significant improvements in immune markers, with CD3+ levels (P = .0006) and CD4+ levels (P = .0005) improving significantly. However, CD8+ levels and the CD4+/CD8+ ratio did not show significant changes. indicating a complex and varied impact of HM on the immune system post-surgery. CD4, another T cell surface protein, is mainly used to identify helper T cells. Helper T cells play a role in regulating the immune response by providing instructions to other immune cells. CD8, a surface protein predominantly expressed on cytotoxic T cells, is involved in the direct destruction of infected or abnormal cells. CD8 T cells contribute to immune defense by exerting cytotoxic effects. The CD4/CD8 ratio indicates the relative numbers of helper T cells and cytotoxic T cells. In a healthy immune state, this ratio is balanced. An abnormal ratio may indicate immune dysfunction [33]. These findings suggest that while HM may enhance certain immune functions in patients with early GC, its effects on different immune markers can vary.

In assessing the QoL of patients with early GC treated with HM, our study showed mixed results. The SF-36 assessment, involving 172 participants, indicated a non-significant improvement in QoL (P = .13), while the WHOQOL-BREF and QLQ-C30 assessments, each with 120 participants, demonstrated significant enhancements in QoL (both with P < .00001). This suggests that HM may have a substantial positive impact on certain QoL aspects in patients with early GC, although the effects vary based on the measurement tool.

In the safety evaluation, the pooled data from eight studies, encompassing a total of 631 participants, revealed an RR of 0.48 with a 95% CI [0.31, 0.74]. This significant result (P = .0009) indicates that patients in the HM group were less likely to experience adverse events compared to those in the control group. The analysis showed no heterogeneity (I² = 0%), suggesting consistent findings across the included studies. This evidence underscores the potential of HM as a safer alternative in the postoperative management of patients with GC, with a reduced risk of adverse effects.

Given that most studies involved a usual care control group compared to the HM treatment group, there are inherent limitations. Furthermore, the unknown efficacy and safety profiles when HM is used in combination with other drugs highlight the need for additional research. To address these challenges, future investigations should focus on reducing heterogeneity through the development of standardized preparations. Additionally, the establishment of a core outcome set is imperative to ensure consistent outcome indicators.

Through this study, we have affirmed the effectiveness of HM treatment in the recovery process following early GC surgery. The significant impact of HM treatment on improving patients' GI function and QoL should be noted. We posit that HM treatment could serve as a viable alternative for the recovery of patients with GC in clinical practice. However, it is crucial to acknowledge the presence of high heterogeneity in the RCTs due to diverse target groups and variations in prescribed HMs.

5. Conclusions

This study substantiates the effectiveness of herbal medicine in enhancing recovery after GC surgery. HM exhibits significant positive effects on improving patients' bowel function and overall quality of life. Our findings indicate that incorporating postoperative HM treatment for patients with GC could be a practical consideration in clinical practice.

Nevertheless, as highlighted earlier, it is crucial to recognize that variations in subjects and prescriptions contribute to considerable heterogeneity. Therefore, we recommend the implementation of long-term clinical trials or follow-ups with rigorous criteria. This aims to observe lasting effects and also to evaluate potential side effects, providing a comprehensive understanding of the enduring impact of herbal medicine treatment in the context of patient recovery after GC surgery. Additional research is deemed essential.

Author Contributions

S.D. Kim and S.J. Pyo are co-first authors and contributed equally to the study design and the drafting of the manuscript. S.D. Kim contributed to the statistical design and analysis. D.H. Kim contributed to the review & editing of the manuscript. H.S. Yoo and S.J. Park conceived the concept of the study and are supervising its implementation. All of the authors have read and approved the final manuscript.

Funding

This study was supported by the Korean Health Industry Development Institutes (KHIDI) funded by the Ministry of Health & Welfare, Republic of Korea (No. HI19C1046 and HF20C0204).

Data Availability Statement

All data generated or analyzed during this study are included in this published article.

Acknowledgments

We would also like to thank Editage (www.editage.co.kr) for English language editing.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

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Figure 2. Risk of Bias Graph with included trials.

Figure 3. Risk of Bias Summary with included trials.

Figure 4. Effect of Herbal Medicine on Time to First Flatus Post-Gastric Cancer Surgery.

Figure 5. Time to First Bowel Movement.

Figure 6. Time to Bowel Sounds.

Figure 7. CRP Levels.

Figure 8. Comparative Risk of Adverse Effects.

Table 1. Search Strategy.

No.	Search terms
#1	gastric cancer[Mesh]
#2	gastric cancer[tiab]
#3	#1 or #2
#4	endoscopic submucosal dissection[Mesh]
#5	endoscopic submucosal dissection[tiab]
#6	#4 or #5
#7	#3 and #6
#8	acupuncture [Mesh]
#9	acupuncture therapy [Mesh]
#10	auriculotherapy [Mesh]
#11	acupuncture [tiab] or auriculotherapy [tiab] or electroacupuncture [tiab] or electro-acupuncture [tiab]
#12	acupunct[tw] or acupress[tw] or acupoint[tw] or electroacupunct[tw] or electro-acupunct[tw] or auriculotherap[tw] or auriculoacupunct*[tw]
#13	#8 or #9 or #10 or #11 or #12
#14	randomized controlled trials [pt]
#15	controlled clinical trial [pt]
#16	randomized [tiab]
#17	placebo [tiab]
#18	RCT [tiab] or (random* [tiab] AND allocat* [tiab]) or (random* [tiab] AND assign * [tiab])
#19	trial [tiab]
#20	group [tiab]
#21	#14 or #15 or #16 or #17 or #18 or #19 or #20
#22	animals [mh] NOT humans [mh]
#23	#21 NOT #22
#24	#7 and #13 and #23

Table 2. Characteristics of Included Trials.

Study	Sample size	Intervention	Control	Duration	Outcome measures
Sang 2020 [9]	120	Ba Zhen Decoction + Usual care	Usual care	2 weeks	TRF, PA, ALB, CD4+, CD8+, CD4+/CD8+, QoL
Gao 2020 [10]	96	Bu Qi Formula + Usual care	Usual care	1 week	GI Functions, CD3+, CD4+, CD4+/CD8+, CRP, TP, PA, ALB, TRF
Ji 2020 [11]	200	Da Cheng Qi Decoction + MCD	MCD	3 days	GI Functions
Liu 2020 [12]	90	Qixue Shuangbu Formula + Usual care	Usual care	15 days	SF-36, ALB, TRF, AEs
Chen 2020 [13]	84	Zishao Liujunzi Decoction + ERAS	ERAS + Usual care	1 week	GI Functions, ALB, CRP
Lü 2018 [14]	60	Jianpi Liqi Formula + Usual care	Placebo + Usual care	4 days	GI Functions
Ma 2018 [15]	117	Fuyuan Formula	Usual care	1 week	CD3+, CD4+, CD8+, CD4+/CD8+, AEs
Guo 2018 [16]	56	Shenqi Yizhu Decoction + Usual care	Usual care	10 days	GI Functions, CD4+, CD8+, CD4+/CD8+, AEs
Ge 2018 [17]	82	Renshen Dahuang Decoction + Usual care	Usual care	1 week	GI Functions, SF36
Ye 2018 [18]	80	Tongfu Huoxue Decoction + Usual care + Glutamine	Usual care + Glutamine	1 week	GI Functions, AEs
He 2017 [19]	120	Dialectical treatment + Usual care	Usual care	2 weeks	QLQ-C30, AEs
Pan 2016 [20]	100	Sini Tongli Decoction + Usual care	Usual care	1 week	GI Functions, AEs
Zou 2016 [21]	68	Jianpi Tongfu Formula + Usual care	Usual care	1 week	GI Functions, ALB, AEs
Liu 2016 [22]	80	Shengyang Yiwei Decoction + ERAS	ERAS	1 week	GI Functions, ALB, TP
Akamaru 2015 [23]	100	Daikenchuto extract powder	Usual Care	3 months	GI Functions, GSRS
Liu 2018 [24]	93	Xiaoai Decoction	Usual care	3 months	CD3+, CD4+

GI: Gastrointestinal; ERAS: Enhanced Recovery After Surgery; MCD: Mosapride citrate dihydrate; GSRS: Gastrointestinal Symptom Rating Scale; TRF: Transferrin; PA: Prealbumin (Transthyretin); ALB: Albumin; QoL: Quality of Life; CRP: C-reactive Protein; TP: Total Protein; AEs: Adverse Events.

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