key: cord-1007316-4c8x2bof
authors: Yan, Li-Jiao; Wang, Zhi-Jie; Fang, Min; Lan, Hui-Di; Moore, Michael; Willcox, Merlin; Trill, Jeanne; Hu, Xiao-Yang; Liu, Jian-Ping
title: Bupleuri radix for Acute Uncomplicated Respiratory Tract Infection: A Systematic Review of Randomized Controlled Trials
date: 2022-02-04
journal: Front Pharmacol
DOI: 10.3389/fphar.2021.787084
sha: a02920eae2ca75f3cd0ec432983a2bf4e6ca2987
doc_id: 1007316
cord_uid: 4c8x2bof

Objective: To evaluate the efficacy, clinical effectiveness, and safety of the Chinese herb Bupleuri radix for the treatment of acute uncomplicated respiratory tract infections (ARTIs). Methods: Four English and four Chinese databases were searched from their inception to June 2021. Randomized controlled trials (RCTs) assessing therapeutic effects of Bupleuri radix on ARTI were eligible for inclusion. The risk of bias for each trial was assessed using the Cochrane Risk of Bias Tool 2.0. RevMan 5.4 software was used for data analyses with effects estimated as risk ratios (RR) or mean differences (MD) with 95% confidence intervals (CI). The certainty of the evidence was assessed using the online GRADEpro tool. Results: Seven randomized trials involving 910 patients with acute upper respiratory tract infection (AURTI) were included. The review identified Bupleuri radix agents with four administration routes (oral, acupoint injection, intramuscular injection, nebulized inhalation). Bupleuri radix acupoint injection compared with placebo showed statistically significant effects in reducing fever resolution time (MD: −33.32 h, 95%CI: −35.71, −30.93), and in increasing the proportion of participants with fever resolved within 48 h from treatment onset (RR: 14, 95%CI: 1.96, 99.94). Bupleuri radix acupoint injection combined with usual care is more effective in reducing the temperature at day 1 from treatment onset (MD: −1.00°C, 95%CI: −1.19, −0.81) compared with usual care alone. Bupleuri radix pills showed similar antipyretic effects to acetaminophen. However, Bupleuri radix intramuscular injection plus vitamins failed to demonstrate an effect in reducing fever, when compared with ribavirin plus vitamins. It suggested that oral administration of Bupleuri radix solution for injections, pills, and Bupleuri radix decoction have a similar effect on improving global AURTI symptoms including two key symptoms (nasal discharge and cough), when compared with usual care alone. Only two trials reported whether or not there were any AEs and found no occurrence of adverse events in the herbal group. Conclusion: Low-certainty or very low-certainty evidence demonstrated that Bupleuri radix (solution for injections and pills) has an antipyretic effect on febrile patients with AURTI, but it has no effect on other AURTI symptoms. However, these findings need to be further confirmed by well-designed clinical trials with adequate sample sizes. Systematic review registration: (https://www.crd.york.ac.uk/prospero/#recordDetails), PROSPERO registration number: CRD42021234066.

Acute uncomplicated respiratory tract infections (ARTIs) involve both upper and lower airways; they include the common cold, influenza, otitis media, sinusitis, tonsillitis, laryngitis, pharyngitis, and bronchitis (Acute, 1998) . Symptoms include nasal congestion and discharge, sneezing, sore throat, cough, sputum production, shortness of breath, chest pain, earache, and fever (Acute, 1998) . Generally, typical common colds are self-limiting and last 7-10 days, whereas acute (rhino)sinusitis can last for up to 4 weeks (Acute, 1998) . On average, acute bronchitis takes 3 weeks to resolve (NICE, N.I.f.H.a.C.E, 2010) . ARTI is one of the most common reasons for primary care consultations. Treatments for ARTI are mainly symptomatic, and often include antipyretics, mucolytics, expectorants, decongestants, and educational interventions. Although ARTIs are predominantly viral infections and antibiotics show little benefit in symptom improvement for ARTI, antibiotics are frequently prescribed in primary care settings (Pouwels et al., 2018) . Antimicrobial resistance (AMR) is an evolving major global threat to public health (Limmathurotsakul et al., 2019) . The marginal benefit of antibiotics for ARTI is outweighed by increasing AMR and common adverse reactions leading to unnecessary increases in healthcare costs (Gonzales et al., 2001; Naylor et al., 2019) . However, many patients believe in antibiotics and want a prescription (Cabral et al., 2015) . Findings also suggest that many patients and doctors are willing to consider alternatives (Soilemezi et al., 2020; Willcox et al., 2020) . Research is warranted to explore other alternatives that may offer symptomatic relief and reduce unnecessary antibiotic prescribing for ARTI.

The Chinese herb Chai hu (Bupleuri radix) is derived from the dried roots of Bupleurum L. There are approximately 200 genera and 2,500 species in different regions and herbal markets (Huang et al., 2017) . Most notably the roots of Bupleurum chinense DC, Bupleurum scorzonerifolium Willd (China) , and Bupleurum falcatum L (Japan) are commonly used in Traditional Chinese Medicine (TCM) and Kampo medicine.

With a 2000-years medicinal history, Bupleuri radix is believed to be one of the most important herbal medicines in China. The earliest record of Bupleuri radix in China appeared in the Divine Farmer's Classic of Materia Medica (Han dynasty, 202 BC~220 AD) (Chen and Chen, 2004) . Since then, Bupleuri radix, as an ingredient alone (Fang and Zhang, 2003) and within particular formulations (such as Chaihuang granule (Zhu et al., 2017) ), has been widely used for the treatment of ARTIs in China, Japan, Korea, as well as other countries (Wyk and Wink, 2004; Klein et al., 2012; Yang et al., 2017) . Bupleuri radix is often processed into pieces for easy use, but since the 1940s, Bupleuri radix injection has been formulated using steam distillation of the volatile oils from the herb. This is for treating influenza, the common cold, and malaria. With more recent developments of TCM, other Bupleuri radix preparations have been developed, such as pills and nasal sprays.

There is encouraging evidence demonstrating the potential mechanism for the effects of Bupleuri radix for ARTI. The active constituents of Bupleuri radix comprise mainly triterpenoid saponins, flavonoids, and essential oil . They possess anti-inflammatory activity by inhibiting some inflammation-associated cytokines, proteins, and enzymes, and regulating inflammation-related signal pathways. For example, the crude polysaccharides (80 mg/kg) isolated from the roots of Bupleurum chinense DC. significantly attenuated lung injury by inhibiting the activity of myeloperoxidase (MPO), reducing the production of tumor necrosis factor-α (TNF-α) in the bronchoalveolar lavage fluid (BALF) and of NO in serum (Xie et al., 2012) . Bupleuri radix demonstrates antipyretic effects via adjustment of intracellular level of cyclic adenosine monophosphate (cAMP) and synthesis and exudation of arginine vasopressin (AVP). Bupleuri radix injection (5 ml/kg, 2.5 ml/kg, and 1.25 ml/kg) can significantly reduce the body temperature of rats (in the lipopolysaccharide fever model), and the dose-effect relationship is significant (Gao et al., 2012) . It has also been shown to be effective against human coronavirus and influenza A virus through interference in the early stage of viral replication, such as absorption and penetration, and attenuating aberrant pro-inflammatory cytokine production in vitro . The ethanol extract of Bupleurum chinense DC. exerted a remarkable bacteriostatic effect on the Gram-negative microorganism Helicobacter pylori in vitro (Gao et al., 2012) . The bioactive minimum inhibitory concentration (MIC) value was 60 μg/ml (Li et al., 2005) . However, the toxic effects of Bupleuri radix in clinical applications have been gradually reported, especially for the preparation of Bupleuri radix injection. It has been implicated in multiple cases of acute hepatitis both as an ingredient alone and within a particular formulation "Xiao-Chai-Hu-Tang" (also known as Syo-Saiko-To in Japanese) (Itoh et al., 1995) . A systematic review conducted in 2010 identified 203 ADR/AE cases in patients using Radix Bupleuri injection, such as anaphylactic shock, acute hepatitis, and acute hepatic necrosis, and for most intramuscular cases, ADR/AE happened within 30 min from injection (Kong et al., 2010) Bupleuri radix injection (Administration, S.F.a.D., 2012) in 2011, which require it not to exceed 60 μg furfural (one of the main harmful ingredients) per 1 ml of the product. So far, there is uncertainty about the safety of Bupleuri Radix injection which follows the new standards.

This systematic review aims to evaluate the efficacy, clinical effectiveness, and safety of Bupleuri radix for the treatment of ARTI in randomized controlled trials (RCTs).

All RCTs were eligible for inclusion.

Trials with patients of any age, with either an ARTI diagnosis or symptoms of ARTI, were included. Diagnoses of ARTI included the common cold, influenza, rhinosinusitis, laryngitis, tonsillitis, pharyngitis, croup, acute otitis media, bronchitis, and acute exacerbations of chronic obstructive pulmonary disease (AECOPD). Symptoms of ARTI were defined as having symptoms such as cough, sore throat, fever, runny nose, and discolored sputum for less than 4 weeks (King et al., 2015) . We excluded any condition for which a specific therapy was recommended, such as streptococcal infections, pneumonia, diphtheria, tuberculosis, infections in immunocompromised, or any life-threatening condition. Also, studies restricted to patients with underlying chronic disease, such as asthma, or any other condition potentially impacting on the management and outcome of ARTI were not included.

Any form of preparation of Bupleuri radix, as monotherapy was included. Trials were included irrespective of the route of administration, e.g. oral, intramuscular injection or acupoint injection, or topical use. A preparation prescribed alone or as an adjunct treatment was only relevant if Bupleuri radix could be isolated as the intervention. Other treatments were permitted, such as additional symptomatic treatment, but this needed to follow national guidelines, and needed to be the same in both intervention and control groups. Bupleuri radix combined with other TCM therapies such as acupuncture were excluded.

No intervention, placebo; usual care such as antipyretics, antivirals, antibiotics, anti-inflammatories, steroids, or corticosteroids were included.

Primary outcomes: 1) Change in global symptoms, which is measured as time to complete resolution of global symptoms (in days) or the proportion of patients resolved at a predefined time. 2) Change in some key symptoms (e.g. fever, cough, and sore throat), which measured as time to complete resolution of symptoms (in days), or the proportion of patients with symptoms resolved at a predefined time. Secondary outcomes: 1) Need for antibiotics at follow-up. 2) Days off work or school.

3) Length of hospitalization. 4) Adverse events (AEs): These included any anaphylactic, allergic reactions, hypersensitivity reactions, or complications of taking Bupleuri radix. Information regarding AEs due to interactions of Bupleuri radix either as a monotherapy or in combination with other remedies, as well as potential interactions with medications for patients with comorbidities was collected.

We defined serious AEs according to the International Council on Harmonization of Technical Requirements for Registration of Pharmaceuticals for Human Use (ICH) guidelines as any event that leads to death, is life-threatening, requires hospitalization, or leads to persistent or significant disability, or leads to abnormal laboratory results such as liver or renal function tests (ICH, T.I.C.f.H., 1994). Search terms included "Bupleuri radix" AND "respiratory tract infection" AND "randomized controlled trials". Additional search terms and strategies in different languages with different databases are listed in the Supplementary Material search strategy.

No language restrictions were applied.

All titles and abstracts of studies retrieved from the electronic searches were reviewed by two authors (LJY and MF), who selected the relevant articles by title and abstract. Full-texts of each publication were independently reviewed by the two authors to determine their inclusion based on the criteria. Two authors (LJY and HDL) independently carried out data extraction using a pre-tested data extraction form. A third author (JPL) resolved disagreements between the two authors in consultation with them. For included trials, we abstracted the following data as recommended in the Cochrane Handbook for Systematic Reviews of Interventions: 1) General information: published or unpublished, author, country, publication language, publication year, journal citation; 2) Participants: inclusion and exclusion criteria, the total number enrolled and number in each comparison group, baseline characteristics, setting; 3) Interventions: details of interventions in all trial arms including type and dose of therapy, according to the CONSORT 2010 extension for reporting Chinese herbal medicine formulas (CHM) checklist (Cheng et al., 2017) ; 4) Risk of bias in trials (see Assessment of risk of bias in included studies); 5) Follow-up: length of followup, the reason for and the number of dropouts and withdrawals, method of analysis; 6) Outcome measures, as the mean and standard deviation (SD) for continuous outcomes, and the number of events for dichotomous outcomes; 7) Safety and adverse events.

The risk of bias for each trial was assessed by using version 2 of the Cochrane tool for assessing the risk of bias in randomized trials (RoB 2) (Sterne et al., 2019) . It included assessment of the randomization process, deviations from intended interventions, missing outcome data, measurement of the outcome, and selection of the reported result. Any disagreements were resolved by discussion.

Statistical analyses were performed by using RevMan 5.4 (The Cochrane Collaboration, 2020). Dichotomous outcomes were expressed as risk ratio (RR) with 95% confidence interval (CI); Continuous data were presented as mean difference (MD) with 95% CI, or as standardized mean differences (SMDs) if outcomes were conceptually the same but measured in different ways in the different trials.

The individual participant was the unit of analysis. For multiple treatment groups, we separated the arms into different comparisons that met our inclusion criteria. For example, one trial (Song, 2020) was multi-armed comparing Bupleuri radix injection with different administration routes (acupoint injection and intramuscular injection) versus placebo (acupoint injection with saline solution), and usual care (intramuscular injection with ribavirin). They were separated into two comparison groups: acupoint injection with Bupleuri radix versus acupoint injection with saline solution; and intramuscular injection with Bupleuri radix versus intramuscular injection with ribavirin.

We contacted authors where data was missing or incomplete. Where standard deviation was not reported with means, it was calculated from the information reported such as confidence intervals (CI), p-values, or F-values. The number of participants whose data was available at baseline and the last follow-up and the rate of loss to follow-up were recorded.

We planned to assess between-study heterogeneity using the I 2 statistic which describes the percentage of variation across studies that is due to heterogeneity rather than chance. A rule of thumb for interpretation of this statistic suggests that I 2 > 30% represents moderate heterogeneity, I 2 > 50% represents substantial heterogeneity, and I 2 > 75% represents considerable heterogeneity (Higgins et al., 2020) . As high levels of heterogeneity were expected due to complexity in the form of Bupleurum (e.g. the various forms of preparation), a randomeffects model was utilized to pool the overall effects.

We conducted funnel plot tests for asymmetry to investigate potential reporting bias where this was feasible and there were sufficient studies under a single meta-analysis.

Where possible, the analyses were planned to be based on intention to treat (ITT) data on each outcome provided for every randomized participant from the individual trials. Where possible, for continuous outcomes, the end of treatment scores rather than change from baseline scores was extracted. Due to the expected variability in the populations and interventions of included trials, a generic inverse variance random-effects model was used to pool the data to incorporate heterogeneity.

We planned to conduct the following subgroup analyses for the primary outcome if there were sufficient trials:

• Adults (over 18) versus children • Bupleuri radix in different preparations, e.g. granule versus capsule • ARTI types regarding pathogen (bacterial or viral infection)

We planned to perform sensitivity analyses for the primary outcome to determine whether the conclusions were different if eligibility was restricted to trials with a low risk of overall bias.

Where substantial heterogeneity exists, sensitivity analysis was planned to be conducted to further investigate potential sources of heterogeneity.

In total 2,546 papers were identified, of which a total of 7 RCTs (Xu and Mao, 2001; Lv, 2010; Li et al., 2011; Cao, 2012; Gui et al., 2012; Huang, 2014; Song, 2020) Characteristics of excluded studies). The included trials were published between 2001 and 2020, and all were from China.

All included trials studied patients with clinically diagnosed acute upper respiratory tract infection (AURTI-see Table 1 ). One was on the common cold in patients aged 16-37 years old (Huang, 2014) , and the other six trials included children with fever without specifying the type of AURTI. One (Lv, 2010) (Wu and Hu, 1995) .

Another study (Cao, 2012) diagnosed AURTI where the patient had "WBC<10.0×10 9 /L, neutrophils<0.70, fever, nasal congestion (or nasal discharge, cough, or dry mouth) red tongue, and yellow coating on the tongue, no complications, and onset within 24 h". Others didn't specify the diagnostic criteria. Only four studies (Cao, 2012; Gui et al., 2012; Huang, 2014; Song, 2020 ) specified a threshold of less than 24 h-5.5 days from the onset of symptoms for acute disease. Two trials (Cao, 2012; Gui et al., 2012) recruited patients from outpatient clinics, one from both outpatient clinics and inpatient wards (Lv, 2010) , the remaining four did not specify the setting. Only two trials reported the source of funding (Lv, 2010; Huang, 2014) , and both of them received funding from the government. None of the included trials stated whether or not a conflict of interest existed. Comparisons were usual care or placebo. All trials involving usual care included some form of active intervention such as antibacterial drugs, antivirals, vitamins, or antipyretics.

Treatment duration in the included clinical trials ranged from 3 to 7 days.

One trial (Lv, 2010) was multi-armed comparing Bupleuri radix injection with acupoint injection and intramuscular injection versus placebo (acupoint injection with saline solution), and usual care. All others were two-arm parallel trials, of which one (Cao, 2012) used Bupleuri radix injection solution taken orally, one (Gui et al., 2012) used inhaled nebulized Bupleuri radix solution, one (Xu and Mao, 2001) used Bupleuri radix injection for intramuscular injection, two (Li et al., 2011 ; Song, 2020) used oral pills, one (Huang, 2014 ) used a decoction of Bupleuri radix pieces. Included trials seldom reported manufacturing or quality control details (see Table 2 ). The reported outcome measures included change in global symptoms (Li et al., 2011; Cao, 2012; Huang, 2014; Song, 2020) and relief of symptoms including nasal discharge (Gui et al., 2012) , cough (Gui et al., 2012) , and fever (Xu and Mao, 2001; Lv, 2010; Gui et al., 2012; Song, 2020) . These were defined as time to complete resolution of the symptom, the severity of symptoms, or the number of patients resolved at a pre-defined time. One trial (Lv, 2010) reported the definition of global symptom resolution based on the "Guiding principles of clinical research on the treatment of children with exogenous fever by new Chinese medicine" (Medicine, 1994) . Three trials that assessed global symptoms improvement, used selfdefined criteria. Only two (Li et al., 2011; Gui et al., 2012) trials reported any information about adverse events. No trials reported antibiotic usage, length of hospitalization, and days off work or school. All the outcomes were measured during treatment or at the completion of treatment.

All the studies which reported the change in fever had "some concerns" in their risk of overall bias. All were described as "randomized," one (Li et al., 2011) used the lottery method, randomly divided the participants into two groups according to odd and even numbers. Others did not report the method of random sequence generation or provided information on allocation concealment. Only one trial compared Bupleuri radix with placebo (Lv, 2010) , there is a possibility that participants were aware of their assigned intervention during the trial, and there was no information about whether or not researchers were blinded. Researchers and participants in six trials (Xu and Mao, 2001; Lv, 2010; Li et al., 2011; Cao, 2012; Huang, 2014; Song, 2020) were likely aware of participants' assigned intervention during the trial, as they assessed two interventions that were different in dosage, or form of preparation, or two types of interventions, or compared Bupleuri radix plus usual care versus usual care, without any blinding information given. No included trials reported any losses to follow-up; thus all were judged as low risk of bias in deviations from the intended intervention and missing outcome data. No trial provided sufficient information to determine whether blinding of outcome assessment was achieved. It was, therefore, assumed that assessors may be aware of the intervention received by study participants. Thus, there are "some concerns" regarding the measurement of the outcome. No trial had a protocol available, accordingly, there were "some concerns" of the risk of bias in the selection of the reported result (see Figure 2) .

All the studies which reported changes in global symptoms or nasal discharge and cough, had a high risk of overall bias, as all outcome measures were at risk of bias due to lack of blinding in the assessors (see Figure 3 ).

The included trials featured four comparison groups: Bupleuri radix plus Vitamins versus placebo plus Vitamins (Lv, 2010) , Bupleuri radix plus usual care versus usual care (Xu and Mao, 2001; Cao, 2012; Gui et al., 2012) , Bupleuri radix versus usual care (Huang, 2014; Song, 2020) , Bupleuri radix plus usual care versus symptomatic treatment plus usual care (Lv, 2010; Li et al., 2011) . Not all subgroup analyses were conducted due to insufficient data. One trial (Lv, 2010) , including 150 children with AURTI and fever, reported a statistically significant effect in favor of Bupleuri radix acupoint injection plus vitamins compared to placebo plus vitamins. The intervention shortened fever clearance time (FCT), defined as the time between the onset of treatment and sustained resolution of fever, i.e. the return of temperature to normal (<37.5°C) without recurrence during the same illness (MD: −33.32 h, 95%CI: −35.71, −30.93). It also improved the chance of fever resolution within 48 h (RR:14.00, 95%CI: 1.96, 99.94).

One trial (Cao, 2012) including 109 children with AURTI showed no difference between oral administration of Bupleuri radix solution for injections plus vitamins, versus vitamins alone, in global symptom resolution rate within 3 days from treatment onset (RR:1.42, 95%CI: 0.73, 2.76). Another trial (Gui et al., 2012) including 108 infants with AURTI used nebulized inhalation of Bupleuri radix solution for injections plus nebulized ribavirin compared with nebulized ribavirin alone. It showed an equivalent effect in relieving the symptom of nasal discharge and cough. However, it showed significant treatment effects for temperature reduction. A third trial (Xu and Mao, 2001) , including 140 children with ARTI and fever, assessed the change of temperature with time from treatment onset, and demonstrated intramuscular injection of Bupleuri radix injection plus oral acetaminophen when compared with oral acetaminophen alone had larger effects on temperature reduction. See Table 3 .

One trial (Huang, 2014) including 80 adults with the common cold, showed the effect of Bupleuri radix decoction on cure rate (no symptom or sign of AURTI, normal laboratory checks) after 7 days of continuous treatment was no different to ribavirin. Another trial (Song, 2020) including 100 AURTI children with fever, showed that Bupleuri radix pills when compared with acetaminophen had an inferior effect on temperature reduction at 30 min from treatment onset, but there wasn't a statistically significant effect at 60 min or 120 min from treatment onset. After 3 days of treatment, the pills demonstrated a higher global symptom resolution rate. See Table 4 .

Bupleuri radix Plus Usual Care Versus Symptomatic Treatment Plus Usual Care (2 Trials)

One trial (Lv, 2010) including 103 children with AURTI and fever reported no significant difference in Fever Clearance Time FCT (MD: 0.99h, 95%CI: −6.31, 4.33) and the chance of fever resolution within 48 h (RR: 0.78, 95%CI: 0.22, 2.76), when comparing Bupleuri radix injection (intramuscular injection) plus vitamins with ribavirin plus vitamins. The other trial (Li et al., 2011) including 120 children with AURTI and fever compared Bupleuri radix pills plus usual care (antibacterial and antiviral drugs) with acetaminophen plus usual care, also had a similar result on improving the symptom of fever, regarding the temperature at 30 min from treatment onset (MD: −0.03°C, 95%CI: −0.14, 0.08), the temperature at 1st hour (MD: 0.05°C, 95%CI: −0.12, 0.22), the temperature at 2nd h (MD: −0.04°C, 95%CI: −0.16, 0.08). Moreover, Bupleuri radix pills plus usual care also failed to show a statistically significant effect on global symptom 

Only two trials reported the occurrence of AEs; one of which (Gui et al., 2012) reported that there were no AEs in either the intervention or control groups. The other one (Li et al., 2011) reported 2 cases had skin rash, 2 cases sweated profusely in the control group. The other trials did not report whether or not there were any AEs.

All outcomes were evaluated as low-certainty or very lowcertainty using the GRADE system approach. The details of the certainty of the available evidence can be found in Supplementary Tables. The certainty of the evidence was downgraded mainly due to the following reasons: 1) Risk of bias (high risk of detection bias and/or attrition bias); and 2) imprecision (small sample size or only one trial was included).

Seven randomized trials involving 910 patients with AURTI were included in this review, with no language restrictions. The review identified three Bupleuri radix preparations (Bupleuri radix solution for injections, pills, decoction) with four administration routes: oral, acupoint injection, intramuscular injection, and nebulized inhalation. There were no trials that evaluated the effectiveness and safety of Bupleuri radix injection, with the administration routes of oral, acupoint injection, intramuscular injection, and nebulized inhalation, according to the Ministry of Health 2011 standards. Bupleuri radix acupoint injection demonstrated a statistically significant effect in reducing fever when compared with placebo, measured by both fever clearance time (Song, 2020) . Included trials also suggested that oral administration of Bupleuri radix solution for injections, pills, and Bupleuri radix decoction have a similar effect on improving global AURTI symptoms and two key symptoms (nasal discharge and cough), when compared with usual care. Some usual care involved in the included trials were not usual care in the UK and many other countries, such as nebulized ribavirin is not usual care for the common cold. However, in China, they were usual care as some form of active intervention at the time of trials conducted. To facilitate the sorting of the results, they were all named "usual care". Only two trials reported on the occurrence of adverse events; they did not record any adverse events in the intervention groups.

There were no high-quality trials of Bupleuri radix for ARTI, and the quality of reporting was poor for all trials. None of the included trials were blinded; reporting indicated that the outcomes could have been influenced by a lack of blinding, and consequently were rated at a high risk of bias. There were no diagnostic or inclusion/exclusion criteria provided in most of the studies. This may have impacted the homogeneity of participants included in the trials, and the severity of symptoms. This makes the trials difficult to replicate. As a natural product, the source of herb and the production method (plant extraction and whether the product is standardized) determine the proportion of constituents and resulting dose, thus influencing the effectiveness and safety of Bupleuri radix. This review identified three Bupleuri radix preparations, but most of them did not provide manufacturing details to ensure the quality and consistency of the products. The quality of evidence using GRADE was low for feverrelated outcomes and very low for other symptom-related outcomes.

This is the first systematic review evaluating the effects of Bupleuri radix on ARTI. The Cochrane methodology was followed and a protocol of this systematic review was registered and published online. We searched for RCTs using a broad search of different databases without language restrictions. Although we performed a broad search for ARTI in both children and adults, only trials involving AURTI qualified for inclusion. There were no trials on acute lower respiratory tract infections such as acute bronchitis. As all authors running the searches are Chinese, there may be a bias in that studies published in Chinese or Chinese journals, may have been more likely to be identified than articles in other non-English languages, even though language restrictions were not applied.

Contemporary experimental research suggests that Bupleuri radix acts on various targets and pathways to produce significant antiviral effects on ARTI, but it is usually used with other herbals such as Scutellariae Radix, which are reported to be effective in improving the AURTI symptoms, such as fever and cough (Li and Deng, 2018; Wei et al., 2021) . However, this review only included Bupleuri radix as a single herb and it failed to detect a statistically significant effect on global symptom resolution rate and some respiratory symptoms including cough and nasal discharge. Moreover, Bupleuri radix has been reported to exhibit mild to a severe adverse drug reaction or adverse events (ADR/AE) such as anaphylactic shock, acute hepatitis, and acute hepatic necrosis (Kong et al., 2010) . However, the studies included in this review reported no side effects. Due to the relatively small number of studies combined with the short duration of treatment included in this review, we cannot draw any conclusions about the safety of Bupleuri radix.

Future well-designed trials evaluating effectiveness and safety of Bupleuri radix for AURTI and reported according to the CONSORT checklist (Schulz et al., 2010) are vital. The potential for antibiotic sparing should also be studied in future trials. Concerning the assessment of safety, other data sources may be necessary to complement our findings.

This review shows that Bupleuri radix may have a superior antipyretic effect on febrile adults or children who suffer from AURTI compared with placebo and usual care. However, fever management in AURTI with antipyretic drugs remains a common practice. There is currently insufficient evidence to recommend a change in practice.

Low-certainty or very low-certainty evidence demonstrated that Bupleuri radix pill and solution for injections may have an antipyretic effect on febrile patients who suffer from AURTI, but it failed to show effects on other AURTI symptoms. However, the quality of included trials was generally low as many were poorly designed and inadequately blinded. Insufficient adverse event data was available to comment on its safety. Therefore, we could not draw more firm conclusions.

The original contributions presented in the study are included in the article/Supplementary Material, further inquiries can be directed to the corresponding authors.

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Conflict of Interest: The authors declare that the research was conducted in the

JPL, XYH, and LJY conceived and designed the review. LJY, MF, and HDL were responsible for the searching, screening, and selection of studies. HDL and LJY participated in the data extraction. Z-JW and LJY were responsible for the risk of bias assessment. LJY performed the statistical analysis. LJY drafted the manuscript. MF completed the PRISMA checklist. JPL, MM, MW, JT, and XYH were involved in critically revising the manuscript. All authors have contributed to and approved the manuscript, including the authorship list. 

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fphar.2021.787084/ full#supplementary-material