Systematic Evaluation of Toxicity of Aconite Based on Bibliometric Method

Aim Based on the bibliometric method, the toxicity of aconite is analyzed and evaluated. Methods Studies on the toxicity of aconite were retrieved from CNKI, CQVIP, Chinese Biomedical Literature Service System, and PubMed, ranging from January 1985 to November 2020. All those studies were formed into the Database of Literature of Toxicity of Aconite (DLTA). Studies on the toxicity of aconite were retrieved from CNKI, CQVIP, SinoMed, and PubMed, respectively. Collecting relevant information in DLTA, we analyzed the hotspots, factors and mechanism of aconite toxicity, and attenuation methods. Results A total of 445 studies on the toxicity of aconite have been collected. “Compatibility attenuation” and “Processing attenuation” have been the hotspots of aconite toxicity in recent years. Many studies support that the main toxic reactions of aconite are heart damage, liver toxicity, nephrotoxicity, and neurotoxicity. The toxic effect of aconite is related to the effect on the central nervous system. Exciting the vagus nerve reduces the autonomy of the sinus node and damages myocardial cells. The decoction time, dosage, and administration of aconite are the main factors of the toxicity of aconite. There are few studies about the effect of the origin of aconite and the specifications of the medicinal materials on toxicity. Therefore, it is impossible to analyze its relevance. At present, the commonly used methods to reduce the toxicity of aconite mainly include three methods: drug compatibility, processing, and decoction. The most common compatibility with aconite medicines includes licorice, dried ginger, ginseng, and ephedra. Black sliced aconite, steamed slices, and fried slices are less toxic than other processed products. Aconite decoction for more than 60 minutes can basically reach the safe range, and more than 2 hours of decoction may cause the loss of active ingredients. Conclusions The research on the mechanisms of aconite dosage-efficacy-toxicity, compatibility, processing, liver toxicity, and nephrotoxicity is still not comprehensive and in-depth. Researchers should perfect toxicity studies of aconite, remove the constraints that affect its clinical application, and promote the clinical use of aconite safely and reasonably.


Introduction
Aconite is a processed product of the lateral root of Aconitum carmichaelii Debx. and a plant of the Ranunculaceae family. It is an authentic medicinal material produced in Sichuan. It was first published in "Shennong's Classic of Materia Medica," which records its spicy, sweetness, hot property, and toxicity [1]. Aconite has a long history of application, and its clinical effect is remarkable. ere are 23 proven recipes based on aconite in "Treatise on Febrile and Miscellaneous Diseases" by Zhang Zhongjing, a famous doctor in the Eastern Han Dynasty. Aconite is known as the most important medicine for reviving yang for resuscitation and is respected as one of the "four dimensions of medicine" [2]. e diester alkaloid contained in aconite is its main active ingredient, which can be used for the treatment of heart failure, rheumatic heart disease, coronary heart disease, hypotension, shock, etc. However, aconite is a type of famous toxic Chinese medicine, and the diester alkaloid is a toxic ingredient. is results in higher toxicity to the cardiovascular system, nervous system, digestive system, liver, and kidney [3]. erefore, it is urgent to use the "doubleedged sword" safely and rationally and remove the constraints that affect its clinical application. Based on the bibliometric method, this paper combed the studies on the toxicity of aconite in recent decades and evaluated and analyzed the research hotspots of aconite. In addition, we summarized the toxicity of aconite and related factors.
e following words are used as keywords or subject terms for literature retrieval in CNKI: "附子 or 附片 or 盐附 子 or 白附片 or 黑附子 or 黑顺片 or 黑片 or 顺片 or 熟附 子 or 熟片 or 制附子 or 制附片 or 川附子 or 淡附子 or 淡 附片 or 炮附片 or 泥附子" with the publication years from 1985 to 2020. e following words are used as keywords or subject terms for literature retrieval in CQVIP : M � (附子 OR 附片 OR 盐附子 OR 白附片 OR 黑附子 OR 黑顺片 OR 黑片 OR 顺片 OR 熟附子 OR 熟片 OR 制附子 OR 制附片 OR 川附 子 OR 淡附子 OR 淡附片 OR 炮附片 OR 泥附子) AND (副作用 OR 毒 OR 不良反应 OR 毒效 OR 毒理 OR 毒副作 用 OR 不良事件 OR 毒 OR 安全性 OR 中毒).

Research Hotspots of Toxicity Literature of Aconite
ere were a total of 445 studies related to the toxicity of aconite in the DLTA. e annual number of publications on the toxicity of aconite from 1985 to 2020 was calculated, as shown in Figure 2. 2007 to 2015 is the peak period of the annual number of publications on the toxicity of aconite, and the annual number of publications has shown a downward trend since 2015.

Coword Analysis.
We performed clustering analysis through VOSviewer1.6.15 for coword analysis. Cluster analysis is a multivariate index statistical method that classifies multiple data according to the degree of distance relationship between objects [4]. All studies in DLTA were imported into VOSviewer for coword clustering analysis. ey were divided into eight groups with distinguished colors. e size of the node indicates the word frequency, and the number of connections among lines indicates its tightness. As shown in Figure 3, "aconite," "aconitine," "cardiomyocyte," "compatibility," "licorice," "poisoning," "processing," and "arrhythmia" are the words with the highest frequency. Combined with the coword analysis, the arrhythmia caused by aconite damage to myocardial cells is a common toxic reaction of aconite. us, the use of licorice or processing to reduce toxicity is a research hotspot in aconite (Table 1).

Toxicity Classification and Mechanism Analysis
3.2.1. Classification of Toxicity of Aconite. In Table 2, the toxic effects of aconite in DLTA include cardiac damage (including arrhythmia, atrial damage, ventricular toxicity, atrioventricular block, and Al-Syndrome), liver toxicity, renal toxicity, and neurotoxicity [9,13,14]. 180 studies mentioned the cardiac damage of aconite. us, the main 2 Evidence-Based Complementary and Alternative Medicine toxic effect of aconite is cardiotoxicity, and arrhythmia is more common in clinical practice.

Analysis of the Toxicity Mechanism of Aconite.
A total of 223 studies on the action mechanism of aconite were collected. e toxic action mechanism of aconite was extracted and classified. en, the statistical analysis was carried out. e toxic action mechanism of aconite that was reported only in one study was eliminated. e classification of its toxic mechanism is shown in Table 3. e toxic reaction mechanisms of aconite reported in many studies are as follows. (1) Aconite has the effect of initial excitement and then inhibition on the central nervous system and peripheral nerves. It mainly acts on the medulla oblongata, causing shock or respiratory depression due to bulbar paralysis, respiratory failure, hypoxic encephalopathy, and death in severe cases [7]. (2) Aconite can excite the vagus nerve, inhibit voltage-dependent sodium channels, increase the sodium ion permeability of nerve cells and myocardial cells, and cause arrhythmia [29].   Evidence-Based Complementary and Alternative Medicine myocardium and cause damage to myocardial cells [30]. (4) Aconite can adjust the activity of L-calcium channels to relatively prolong the repolarization, increase the calcium ion concentration, cause calcium ion overload in myocardial cells, and damage cardiomyocytes [31]. (5) Aconite can excite cholinergic nerves and inhibit cholinesterase activity, thereby inhibiting the heart [31]. From the statistical analysis of studies (Table S1), there are many studies on the action mechanism of aconite toxicity on the heart, with in-depth research and a broader perspective. ere are few studies on the action mechanism of aconite toxicity on the liver and kidney. However, these toxic reactions are common in clinical research. If there is no exact description of these toxicity mechanisms, it is impossible to avoid toxic side effects and conduct reasonable treatment.

Factors Analysis of Aconite Toxicity.
We analyzed the correlation between aconite toxicity and several factors, such as the origin, the specification, the decoction time, and the dosage of aconite. e bibliometric method was used to analyze the relationship between the origin of aconite, the specifications of medicinal materials, the decoction time, the dosage, and the toxicity of aconite.

e Origin of Aconite.
e sources of aconite medicinal materials in all studies of DLTA were analyzed, and the classification statistics were performed ( Figure 4). Most of the studies reported that the source of aconite is decoction pieces companies or hospitals. It is difficult to trace its source. erefore, it is impossible to evaluate the relationship between the aconite source and toxicity objectively. In DLTA, 55 studies reported that the aconite is from Jiangyou City, Sichuan. Jiangyou aconite is a well-known authentic medicinal material produced in Sichuan, where it has sophisticated and complicated root-repairing and tipping cultivation techniques [32]. It is a national product of geographic indication. e medicinal ingredients of Jiangyou aconite are more recognized by academia. erefore, the use of Jiangyou aconite not only ensures clinical safety but also improves the reliability of experimental results.

Aconite Medicinal Material Specifications.
In DLTA, the extracted specifications of aconite medicinal materials include aconite, black aconite/sliced aconite, cooked aconite, prepared aconite, and prescriptions and medicines containing aconite (Table S2). e classification statistics are shown in Table 4 ( Figure 5). Huang and Wang [32] summarized the specifications of aconite medicinal materials, including two kinds of aconite and 18 kinds of sliced aconite based on the systematic literature survey, real estate survey, and expert consultation. However, most of the specifications of medicinal materials, such as Linjiang slice, Yangfu slice, Yinfu slice, Liuye slice, and Gugu slice, have gradually disappeared and lost due to various reasons. erefore, we have not made a statistical analysis on the specifications of medicinal materials with smaller yields.

Decoction Time of Aconite.
is study analyzed the decoction time of aconite in various studies (Table S3), as shown in Table 5 ( Figure 6). e preparation method with decoction time of half an hour or one hour has been widely used. Too short decoction time [47] of aconite or no decoction [48] in the prescription is the common cause of toxicity.
Scholars generally believe that a decoction time of less than 30 minutes is likely to cause clinical toxic events. e decoction time should be extended as the dose of aconite increases. However, most clinicians rely on their own experience about the corresponding relationship between dosage and decoction time, and there is no standard for it.
is is one of the reasons for the prone to poisoning reaction when using large doses of aconite [49]. Usually, when the dosage of aconite is less than 30 g, it can be decocted for half an hour. When the dosage is 40∼70 g, it should be decocted for 1 h. If the dosage is more than 70 g, it should be decocted for more than 2 h [50].

Clinical Dosage of Aconite.
e current textbooks and pharmacopeias stipulate that the common dosage of aconite is 3-15 g/d [51], and aconite is not suitable for long-term use. However, 16 reports mentioned that patients still have poisoning reactions even after reasonably taking aconite and its medicine preparations at normal doses [52], especially the toxicity caused by Aconite Lizhong Pills [38,53]. e textbooks and pharmacopeias stipulate that the usual amount of aconite is 3-15 g/d [54], which is not suitable for long-term use. However, 16 articles mentioned that patients still had toxic reactions when taking aconite and its medicine preparations at normal doses reasonably [55], especially the toxicity caused by Aconite Lizhong Pills [56,57]. ere are also many cases of overdose or long-term use in clinical practice. Daily doses exceeding 50 g are very common ( Figure 7, Table 6). Ultralarge doses of aconite are mostly used to treat intractable diseases such as rheumatoid arthritis and heart block. Although overdose use will increase the probability of aconite poisoning, doctors will mostly reduce toxicity by extending the decoction time and compatibility of medicinal materials. erefore, the clinical use of aconite does not have strict limits on the dose, and the dose distribution range is relatively wide. ere are individual differences in the dose of aconite in clinical application. Even if it is taken according to the instructions or pharmacopeia methods, toxic reactions may still occur. e clinical dose of aconite is positively correlated with toxicity. e use of overdose can also be recognized by doctors in the context of measuring the risk-benefit ratio for some difficult and miscellaneous diseases. e results of the classification are shown in Table S4.

Other
Factors. In addition, the factors affecting the toxicity of aconite are shown in Table 7 ( Figure 8). (1) Druginduced side effects or unidentified reason for toxicity: some studies did not clearly explain the cause of poisoning, or the poisoning reaction still occurred without the occurrence of poisoning incentives [63]. (2) Improper processing: for example, the black aconite used excessive bile water in the process [64], causing damage to yang and diarrhea in patients, which are completely unrelated to the symptoms of aconite. "Short decoction time" is also the main cause of poisoning in patients [47]. (3) Drug accumulation [61,65]: if the patient does not follow the doctor's prescription or take an overlong course of treatment, it may cause poisoning. (4) Aconite medicated with wine or food [62,66]: six reports in DLTA mentioned that patients took medicinal liquor or medicine containing aconite, which caused toxic reactions. (5) Mistaken eating or self-prescribing [67,68]: these mostly occur in rural areas and early times. With the improvement of public health awareness, mistaken eating has become rare. e results of the classification are shown in Table S5.

Analysis of Detoxification Methods of Aconite.
rough the literature survey, it is found that the commonly used ways to reduce the toxicity of aconite mainly include three methods: drug compatibility, processing, and decoction.

Drug Compatibility.
In DLTA, we collected the results and causes of the effects of compatible medicinal materials on the toxicity of aconite and analyzed them statistically, as shown in Table 8. e most commonly compatible drugs with aconite are Glycyrrhiza uralensis Fisch, Zingiber officinale Roscoe, Panax ginseng C. A. Meyer, and Ephedra sinica Stapf, etc. e toxicity studies of the compatibility of other drugs with aconite are few. e chemical reaction between aconite and codecocting drugs can reduce toxicity by compatibility, thereby changing the structure of diester alkaloids and converting them into compounds with weaker toxicity [87], or improving enzyme activity to increase the metabolism of aconite [88].

Processing Method.
A total of 38 studies on the processing of aconite were collected in this study, and information analysis was performed (Table 9). Studies have shown that because of its high toxicity, raw aconite is rarely taken directly. Most of the processed products of aconite are used clinically. Aconite processing products have many specifications. In recent years, techniques such as puffing and dry heat baking have been introduced in the processing of aconite and have good effects of reducing toxicity  (55) Sichuang (23) Bozhou, Anhui (14) Guangdong (Medicinal slices factory) (11) Shaanxi (8) Chengdu University of TCM (6) Henan (5) Beijing (3) Tianjin (2) Hubei (2) Shanxi (2) Beijing University of TCM (2) Yuxian, Henan (  e toxicity action mechanism of aconite Occurrence Reference e effect on various nerve fiber endings and the central nervous system is initial excitement and then inhibition (the effect of the central nervous system may be related to the promotion of the release of β-endorphin by aconite) 42 Han et al. [10] Exciting the vagus nerve reduces the autonomy of the sinus node 40 Li [15] Inhibiting voltage-dependent sodium channels, increasing the sodium ion permeability of nerve cells and myocardial cells, and causing arrhythmia 27 Sheng et al. [5] Inhibiting the acid cycle of myocardial tricarboxylic and the acidification of oxidative phosphorylation of the respiratory chain, causing myocardial cell damage and necrosis to release myocardial enzymes 19 Strzelecki et al. [16] Adjusting L-calcium channel activity to relatively prolong repolarization, increasing calcium ion concentration, and causing calcium ion overload in cardiac myocytes 12 Zhou et al. [17] Exciting cholinergic nerves, inhibiting cholinesterase activity 11 Wang et al. [18] Inhibiting the vasomotor center 10 Zhang [19] Inhibiting the Na-K-ATPase activity of the myocardial cell membrane, leading to a large amount of depletion of myocardial high-energy phosphate bonds, and causing damage to myocardial cells 9 Sun et al. [20] Causing damage to peripheral nerve Evidence-Based Complementary and Alternative Medicine 7 [99,100]. Based on the results of various studies, the toxicity of black sliced aconite, steamed aconite slice, and cooked aconite slice are weaker than that of other processed products of aconite. In addition, although the safety of aconite is guaranteed, the medicine materials for disease treatment decrease due to overprocessing. Many experimental data supported this view [101,102]. Only reasonable processing can both reduce the toxicity of raw aconite and give full play to the efficacy. us, it is urgent to establish scientific standards of aconite processing. We studied the control of the toxic components of aconite for the safety of the medication and the better curative effect. erefore, we maintain a balance between toxicity and effect.

Decoction Time.
e diester alkaloids in aconite, such as aconitine, hypaconitine, and neoaconitine, are both effective and toxic components [3]. e diester alkaloids can be hydrolyzed by heating or have a lipid exchange reaction with fatty acids to generate fat base and reduce its content, thereby reducing toxicity. erefore, the pyrolysis reaction caused by aconite heating is also one of the effective ways of aconite detoxification [103].
rough literature surveys (Table 10), it was found that aconitum decoction for more than 60 minutes reached the safe range, and more than 2 hours of decoction may cause the loss of effective components. e toxicity of aconite is closely related to the decocting time, which is a direct factor for the toxicity of aconite.

Discussion
Based on the bibliometric method, this study evaluated the publication trend and research hotspots of aconite toxicity in the past 35 years. In addition, this paper analyzed the      Drug-induced side effects or unspecified (38) Improper processing (10) Accumulation (8) Aconite medicated with wine/food (6) Eating disorders/autonomous diseases (6)  ① Glycyrrhizic acid and glycyrrhetinic acid in licorice can neutralize with the aconite alkaloids in aconite, and the flavonoids in licorice can also combine with aconitum alkaloids to form a precipitate, both of which can delay or reduce the absorption of toxic alkaloids such as aconitine. ② Glycyrrhizic acid in the gastrointestinal tract can be converted into glycyrrhetinic acid and flavonoids. Licorice flavonoids contain multiple hydroxyl groups, which can combine with alkaloids in aconite to form ester alkaloid precipitation, reduce the content of toxic alkaloids.
Yang et al. [69] Dried ginger 11 Reduce toxicity e chemical components in dried ginger can convert the more toxic diester alkaloids in aconite into less toxic ester alkaloids and can antagonize the central inhibitory effect of aconitine, thereby achieving the purpose of detoxification Yue et al. [70] Ginseng 8 Reduce toxicity Ginsenosides in ginseng can increase the SOD activity of cardiomyocytes, reduce MDA content and LDH release rate, and can inhibit the apoptosis of aconite on cardiomyocytes and effectively inhibit its toxic effects.
Wang et al. [27] Pinellia 6 Toxic increase/ decrease ① e compatibility of aconite with qing pinellia, pinellia ginger, and raw pinellia can inhibit the hydrolysis reaction of the alkaloids in aconite, resulting in a significant increase in the content of diester alkaloids. ② e compatibility of aconite and pinellia ternata is attenuated and can make the toxicity more toxic. Large diester alkaloids are transformed into less toxic monoester alkaloids. ③ Compatibility of aconite and pinellia can inhibit CYP1A2 and CYP3A1 enzyme activity, inhibit drug metabolism, and enhance the toxicity.
Huang [71] Jin et al. [72] Ephedra and Fuzi licorice soup 5 Reduce toxicity It can significantly reduce the content of diester alkaloids, and the codecocting effect of the three is the best. Wang and Wan [73]  After the two are compatible, the content of monoester alkaloids-benzoyl neoaconitine and benzoyl hypoaconitine is reduced, thereby generating a new ester alkaloid-8linoleoyl-14-benzoyl hypoaconitine and 8-linoleyl-14benzoyl aconitine reduces the toxicity.
Pi et al. [74] Rhubarb 4 Reduce toxicity During the decoction, the tannins and aconite alkaloids contained in rhubarb produce aconitine salt of tannic acid that is not absorbed by the intestine, thereby reducing the toxicity of aconite, and the content of aconitine decreases as the dose of rhubarb increases. ose are linearly related, and its attenuation effect also increases with the increasing dose of rhubarb.
Wang et al. [75] Fritillaria Zhejiang/ Fritillaria Chuan 4 Toxic increase/ decrease ① After codecoction of aconite and fritillaria, the content of aconitine, hypoaconitine, and neoaconitine increased significantly, and the dissolution rate of toxic components of aconitine increased. ② After the compatibility of aconite and fritillaria cirrhosa, the amount of the three diester alkaloids aconitine, mesaconitine, and hypoaconitine was significantly reduced or undetectable, and the toxicity was reduced.

Sun et al. [78]
Astragalus 2 Reduce toxicity ① Compatible with astragalus can reduce the 6 alkaloids of aconite to varying degrees (benzoyl hypoaconitine BHA, benzoyl neoaconitine BMA, benzoyl aconitine BAC, hypoaconitine HA, new aconitine MA, aconitine AC) plasma concentration. ② Astragalus inhibits the absorption of aconite alkaloids that may be related to the expression of astragalus-induced efflux transporter. ③ Astragalus promotes the clearance of aconite that may be related to the induction of corresponding metabolic enzymes (CYP3A4, CYP3A4, astragalus, CYP1A1, CYP2E1); activity is related.
Liu et al. [79] Zhang et al. [80] Lou et al. [81] White Peony 1 Reduce toxicity e diester-type alkaloids in aconite react with the chemical components in the white peony root, so that hypoaconitine, which is not easily hydrolyzed, generates lipid alkaloids. e lipid exchange reaction leads to a decrease in the content of hypoaconitine, thereby achieving attenuation.
Yue et al. [70] Guizhi 1 Reduce toxicity e compatibility of Aconite with Guizhi can reduce the total alkaloids and ester alkaloids of aconite, thereby reducing the poisonousness of aconite, and may be able to guide aconite to dispel cold and relieve pain and warm meridians and improve the pulse.
Ye et al. [82] Cinnamon 1 Unknown e compatibility of aconite with cinnamon can promote the dissolution of the effective components of aconite and can better guide the aconite to play the role of warming yang and igniting fire. Subacute toxicity experiments in mice show that the toxicity of aconite and Trichosanthes is less than that of aconite single decoction.
Yang et al. [85] Evidence-Based Complementary and Alternative Medicine  Fried sliced aconite Compared with other processed aconite products, fried sliced aconite has a lower content of diester alkaloids, the highest content of monoester alkaloids, and the lowest content of ephedra alkaloids Toxicity: fried sliced aconite < black sliced aconite, danfupian, baifupian, paofupian Qiu [95] Raw aconite, prepared aconite Raw aconite has a better effect than processed aconite on Rhubarb aconite decoction Rhubarb aconite decoction using raw aconite has a better therapeutic effect and is safe to use Guo [96] Black sliced aconite, fried sliced aconite, steamed sliced aconite e maximum tolerated amount of fried sliced aconite is 170 g kg −1 , that of steamed sliced aconite is 268 g kg −1 , and the LD 50 of Heishunian is 138.13 g Toxicity: steamed sliced aconite < fried sliced aconite < black sliced aconite Zhang et al. [97] Danba preparation Among different salted products, aconite with 40% and 45% concentration of danba preparation has lower toxicity, and the former one also has an obvious neuroprotective effect 40% danba should be used for salted aconite Liu [98] common toxic reactions, toxic mechanisms, factors, and commonly used detoxification methods of aconite. is can provide a useful reference for clinical rational use of aconite and related research on its toxicity. Since the beginning of 1985, there have been research reports on the toxicity of aconite. e decoction time, dosage, and mode of administration of aconite are the main factors affecting the toxicity of aconite. ere are few studies on the effect of the origin of aconite and the specifications of medicinal materials on toxicity, so it is impossible to analyze their relevance. At present, the commonly used methods to reduce the toxicity of aconite include three methods: drug compatibility, concoction, and decoction. e most common drugs compatible with aconite are licorice, dried ginger, ginseng, and ephedra. Black sliced aconite, steamed slices, and fried slices are less toxic than other processed products. Aconite decoction for more than 60 minutes can basically reach the safe range, and more than 2 hours of decoction may cause the loss of active ingredients.
One problem is that the number of studies on the toxicity of aconite has declined in recent years. However, the toxicity of aconite has not been fully revealed. More experimental data and research are needed to confirm and answer: (1) overdose use of aconite (exceeding the pharmacopeia recommendation) is common, but there are few studies on the relationship between quantity and toxicity effect of aconite. When clinical use is caused, there is no uniform reference standard for indication dose, which could easily cause toxic reactions. (2) e reasonable decoction time of aconite is 30 minutes to 1 hour. is has been supported by many studies. However, there are also 2-4 hours of decoction cases in clinical practice, especially in the case of large-dose use. Although long-term decoction reduces the incidence of toxic reactions, does the effect of aconite change after long-term decoction? ere are too few research data. e decoction time of large-dose aconite lacks a reference standard. (3) Although there are many studies about the processing and compatibility of aconite, there is a large convergence, the processing method is rarely innovative, and the compatibility research is mostly concentrated on several drugs such as licorice, and the compatibility evaluation with other drugs is less, leading to the lack of precise evidence to guide doctors when prescribing drugs in the clinic, and it is also easy to cause toxic events. (4) More and more reports show that aconite can cause adverse reactions such as kidney and liver damage, but the mechanism of its hepatotoxicity and nephrotoxicity is less. e exact toxicity mechanism needs further study. e researchers should be committed to improve the research of toxicity of aconite, remove the constraints for application, and promote the safe and e toxicity of aconite decoction for 60 minutes is relatively low, and the pharmacological activity is the strongest; when the decoction exceeds 105 minutes, the animals in each group behave normally without death Kao and Zhang [104] Clinical safety experiment Nausea, vomiting, dizziness, salivation, and other adverse reactions e normal dose decoction time should be controlled within 1-2 h; but if the dose is more than 200 g, an additional 1 h decoction time should be added Liang et al. [105] HPLC content determination Aconitine, neoaconitine, hypoaconitine Both the 0 min and 30 min water decoctions of aconite are toxic, but the 60 min toxicity is not significant, and it can basically be defined as nontoxic Sun et al. [106] HPLC and UV methods Neoaconitine, hypoaconitine, aconitine, benzoyl neoaconitine, benzoyl hypoaconitine, benzoyl aconitine After 0.5 h of decoction, the content of diester alkaloids basically disappeared. After 1 h of decoction, the content of monoester alkaloids and total alkaloids reached the maximum Gong et al. [107] HPLC content determination Aconitine, hypoaconitine, neoaconitine, benzoyl neoaconitine, benzoyl hypoaconitine, benzoyl aconitine After decoction of black sliced aconite for 3.5 hours, the content of monoester alkaloids gradually disappeared Lin et al. [108] HPLC content determination 13 kinds of alkaloids including aconitine, neoaconitine and hypoaconitine After decoction of shengfu tablets for 2-4 hours, the content of diester alkaloids is already very low, which can ensure the safety of clinical medication Zhang et al. [109] HPLC content determination Neoaconitine, hypoaconitine, aconitine, benzoyl neoaconitine, benzoyl hypoaconitine, benzoyl aconitine e diester alkaloids in raw aconite are extremely unstable in water decoction. Hypoaconitine was detected within 0.5 h of decoction Chen et al. [110] HPLC content determination Aconitum alkaloids After decocting the aconite in water for 30 minutes, the content of aconitine and hypoaconitine became 10.5% and 41.9% of the peak value, respectively, and aconitine was completely undetectable; after the aconite microwave heating for 150s, the content of aconitine, neoaconitine, and hypoaconitine was 59.2%, 41.4%, and 86.6% of the peak value, respectively Sui et al. [111] HPLC and UV methods Total alkaloids, ester alkaloids, polysaccharide components, diester alkaloid components e best decocting time is within 1 hour Yu et al. [112] Evidence-Based Complementary and Alternative Medicine 13 reasonable use of aconite in the clinic. Researchers should improve various toxicity studies of aconite, remove the constraints that affect its clinical application, and promote the rational use of aconite.

Conflicts of Interest
ere are no conflicts of interest.

Authors' Contributions
Diyao Wu took charge of guiding the experiments and paper writing. Tielong Xu, Qian Chen, Yaling Wang, Hongfu Chen, and Zhengdong Huang wrote the manuscript and finished data mining research. Meiying Ao and Lihua Chen completed the experimental design and execution.
Acknowledgments is study was supported by National Basic Research Program of China (No. 2019YFC1604905) and National Natural Science Foundation (No. 81760717). Table S1: the classification of the toxicity action mechanism of aconite and the number of studies. Figure S2: the number of studies of various specifications of aconite in DLTA. Table  S3: the number of studies of decoction time in the DLTA. Table S4: the number of studies on different dosages of aconite in DLTA.