Abstract
Cancer patients could combine herbal treatments with their chemotherapy. We consulted VigiBase, a WHO database of individual case safety reports (ICSRs) which archives reports of suspected Adverse Drug Reactions (ADRs) when herbal products are used in conjunction with anti-cancer treatment. We focused on the possible interactions between antineoplastic (L01 ATC class) or hormone antagonists (L02B ATC class) with 10 commonly used herbs (pineapple, green tea, cannabis, black cohosh, turmeric, echinacea, St John’s wort, milk thistle and ginger) to compare ADRs described in ICSRs with the literature. A total of 1057 ICSRs were extracted from the database but only 134 were complete enough (or did not concern too many therapeutic lines) to keep them for analysis. Finally, 51 rationalizable ICSRs could be explained, which led us to propose a pharmacokinetic or pharmacodynamic interaction mechanism. Reports concerned more frequently women and half of the rationalizable ICSRs involved Viscum album and Silybum marianum. 5% of the ADRs described could have been avoided if clinicians had had access to the published information. It is also important to note that in 8% of the cases, the ADRs observed were life threatening. Phytovigilance should thus be considered more by health care professionals to best treat cancer patients and for better integrative care.
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Introduction
Phytovigilance1 concerns domains from pharmacovigilance to nutrivigilance. In Europe, phytovigilance is supported by the European Medicinal Agency (EMA) at pharmacovigilance level and by the European Food Safety Agency (EFSA) at nutrivigilance level. Globally, WHO promotes the clinical value and relevance of information on VigiBase2,3. This database has archived Adverse Drug Reactions (ADRs) of over 20 million Individual Case Safety Reports (ICSRs). Phytovigilance is particularly relevant for a patient’s real life during chronic treatments, such as cancer chemotherapy. Given the distress induced by diagnosis and treatment, there is a growing consensus towards considering cancer patients and their treatments more holistically. In general, western health professionals tend to discourage the use of phytotherapy due to the lack of relevant data, especially when combining an herb with Anti-Cancer Drug (ACD). In this article, we have focused on ADRs of patients undergoing an Anti-Cancer Drug (ACD) therapy together with the intake of one of 10 common herbs reported in VigiBase. We carried out a careful analysis to compare data on herb-drug interactions from the literature with real clinical situations. The societal goal of this project is to strengthen the knowledge of medical staff and to allow a more open exchange between patients and health care professionals.
Methods
Study design
A data extraction of ICSRs from the entire WHO database was performed by the Belgian Human Pharmacovigilance Evaluation cell on 2020-01-12. ICSRs containing at least one ACD and one of 10 representative herbs were extracted using ATC codes L01 antineoplastic agents or L02B hormone antagonists and related agents in a cancer clinic situation and herbs using their Latin binomial name. The herbs concerned are pineapple—Ananas comosus (L.) Merr., green tea—Camelia sinensis (L.) Kuntze, cannabis—Cannabis sativa L., black cohosh—Cimicifuga racemosa (L.) Nutt., turmeric—Curcuma longa L., echinacea—Echinacea purpurea (L.) Moench, St John’s wort—Hypericum perforatum L., milk thistle—Silybum marianum (L.) Gaertn. and ginger—Zingiber officinale Roscoe.
The choice of these herbs was made based on the current practice of phytotherapy in Europe to our knowledge. For Curcuma longa, a second VigiBase extraction was done with “curcumin” key word as the active ingredient. Duplicate ICSRs found were, thus, only mentioned once.
Data curation
For each ICSR, the primary source country and reporter qualification were retrieved. The five categories of reporters’ qualifications were: physician, pharmacist, other health professional, consumer/non-health professional and unknown reporter qualification. Then a two-step data curation was carried out.
The first step aimed to select those with sufficient informative data available. Sufficient informative ICSRs include a minimum of at least one classified “suspected” or “interacting” anticancer drug with an herb and at least one ADRs. ICSRs containing too many therapeutic lines, conventional or not (> 5) were eliminated. In these cases, we are in polypharmacy (defined as regular use of at least five medications). Due to unspecific descriptions of the ADRs, and due the complexity of the pharmaceutical analyses in these cases, it seemed to us inappropriate to analyze these ICSRs. This is particularly the case with Cannabis sativa, which is often used to treat pain in palliative care situation concomitantly with many allopathic medications, or for Zingiber officinale, which is used in phyto-therapeutic complex formulas in traditional Asian medicine. ICSRs were not selected if only the term "drug interaction" was mentioned without indicating ADRs. Their main characteristics, i.e., suspected active ingredient, ADR (preferred term, in the Medical Dictionary for Regulation Activities—MedDRA) terminology, dechallenge, rechallenge and causality/seriousness of suspected and interacting drugs (when available) were gathered in Excel 2016 and we carried out an analysis of potential Herb-Drug Interactions (HDI).
For the second step, we worked on a rationalization of ADRs based on the literature. The potential pharmacokinetic (PK) and pharmacodynamic (PD) interactions of the suspected herbs and drugs were studied. For drugs, the Summary of Product Characteristics (SmPC) completed by Geneva University Hospital Cytochrome P450 tables4 or PubMed requests were used. For the herbs, monographs from EMA and from Stockley’s Herbal Medicines Interactions (2nd edition)5, reviews of clinical trials on clinicaltrial.gov, and a review of scientific publications using PubMed were consulted.
For each herb, a synthetic table was constructed indicating potential interactions between either OACDs (Oral ACDs) or PACDs (Parenteral ACDs) and the herbs, including the supposed natural secondary metabolites and mechanisms involved.
Scoring
The final selection of rationalizable ICSR were scored at 2 levels according to Table 1. These scores are mentioned in the last two columns of Tables 2, 3, 4, 5 and 6.
The first score concerns causality. The causality assessment found in the ICSRs were compared to literature review findings, and their concordance was rated using a gradation system with (*) or (**) where (**) is more robust than (*). (*) indicated that (i) there was a low degree of agreement between the causality assessment of the case (including when the ICSR was listed as "unlikely" in VigiBase) based on the literature or (ii) no causality assessment was found due to too many suspected interacting drug treatments or (iii) more than one route of administration was mentioned, which thus led to a complicated analysis of the interaction. (**) indicated that we agree with the causality assessment for at least one symptom. This causality score was indicated as “Concordance with ISCR conclusion” in Tables 2, 3, 4, 5 and 6.
The second score concerned clinical risk named “Level of Risk” in Tables 2, 3, 4, 5 and 6. We propose a comprehensive classification of risks based on an alpha-numeric gradation. The quality of the ADRs evidence was indicated by the numbers 0–4 and the seriousness of the potential ADRs by the letters A–F based on the classification system of De Smet6 (Table 1).
Consent for publication
The Global ICSR database VigiBase was used as a data source for this article. Information in VigiBase comes from a variety of sources, and the probability that the suspected adverse effect is drug-related is not the same in all cases. Information in this article does not represent the opinion of the UMC or the World Health Organization.
Results
Our analysis was based on ADRs reported in VigiBase when herbs were consumed at the same time as one or more drugs. Subsequently, 1057 ICSRs containing at least one ACD (Anti-Cancer Drugs in both ATC class L01 et L02B) and 1 of the 10 herbs chosen were extracted from the WHO database (Fig. 1).
Flow chart from the selection of the 1057 ICSRs from VigiBase (A). In the first step, 1057 ICSR have been selected with 933 ICRS implicated drugs in L01 ATC class and 28 L02B drugs. At (B) step only 134 ICSR were selected for further investigation because they include at least “suspected” or “interacting” drugs/herb interaction and at least one adverse reaction. The last step (C) consists in the rationalization of the possible ADR due to PK or PD described interactions in literature.
A macroscopic examination of the data shows that physicians reported the majority of ICSRs (56%). Pharmacists reported 8% of them, other health professionals 22%, consumers/non-health professionals 10%, leaving 4% with unknown reporter qualification (Fig. 2).
Dashboard with graphical representations of the geographical areas from which the declarations originate and the professional or consumer status of the declarants (draw with bing https://www.bing.com/).
The top three of countries reporting ADRs involving ACD and herbs (considering the number of inhabitants) are Germany, the Republic of Korea and the USA. There are more ICSR descriptions involving women (57%) than men (35%). Gender is not specified in 8% of ICSRs. Among retrieved ICSRs, cases involving Viscum album represented a substantial majority with 750/1057 ICSRs (71%). No ICSR was found for pineapple (Fig. 1), and no rationalized ICSR was possible on Echinacea.
The selection during the first step consisted of browsing the ICSRs manually to identify whether the description mentioned a suspected interaction or at least one adverse effect due to the association between the herb and the anticancer drug. After the first screening, only 134 ICSRs in VigiBase were complete enough to advance beyond the first step of selection. Noteworthy, around 600 ICSRs involved only Viscum album without any other medicine; 31/39 ICSRs involving Zingiber officinale were declared in Asia (either from the Republic of Korea or Japan in most cases) with more than 5 other herbs. In these cases, a relationship between one herb and the ACD is difficult to evaluate.
Only 51 ICSRs went on to the second step (Fig. 1). At this stage, the selection consisted of studying each ICSRs in detail and identifying whether an interaction mechanism could be identified based on the literature. In addition, the quality of the report does not seem to correlate with the professional status of the reporter (Fig. 2 and Table 1).
Among the remaining ICSRs, the predominant HDI was scored using two indicators, which are mentioned in the last columns of Tables 2, 3, 4, 5 and 6. Causability and clinical risk level were evaluated according to De Smet6. Causality assessments found in the ICSRs were compared to literature review findings; their concordance was rated using a gradation system. Clinical risk was evaluated considering (i) the quality of the evidence of the HDI considering peer reviewed publications; (ii) the seriousness of the resulting adverse reaction. In this article, a dichotomy was made between drugs given orally and parenterally (Tables 2, 3, 4, 5 and 6). The majority of the selected ICSRs concerned herb-OACDs interactions (29 ICSRs) and 22 ICSRs concerned PACDs. For all the herbs, tables described the rationalized interactions with the mechanism involved denoted in the central columns of said tables and the clinical adverse reaction observed.
Green tea—Camelia sinensis (L.) Kuntze
Even if Cochrane review7,8 concluded that there is insufficient data to make recommendation on cancer incidence or cancer mortality, patients often consume green tea. This meta-analysis focuses on the cancer prevention impact based on prospective, controlled intervention studies and observational studies.
Pre-clinical data indicates that green tea exhibits possible interaction with PACD as bortezomib and OACD as tamoxifen20,21. In VigiBase, 5 cases were identified involving 4 drugs. In CSa1, CSa2, Table 2A, (−)-epigallocatechin gallate (EGCG) seems to be the key metabolite suspected of interacting with a drug known to be a Pgp substrate as erlotinib.
In CSa2, the patient was treated with a commercial product named Polyphenon E, a food supplement standardized22,23 in EGCG—200 mg a day. In vitro and animal studies10,11,13 describe increased blood levels of Pgp substrate in the presence of pure EGCG, a Pgp inhibitor, at concentrations from 1 µM whereas human blood concentrations after green tea ingestion can reach 1 mM10. A well-documented case study also mentioned increased blood levels of tacrolimus, a Pgp substrate, after green tea ingestion12, thus supporting previous descriptions. To our knowledge, no clinical trial was performed to assess this HDI. In CSa3, green tea is described as being involved in the decrease in iron absorption, while anemia is a very common adverse effect of imatinib. Several clinical studies on green tea have shown a noticeable decrease of 37% (and up to 99%) in iron absorption among healthy volunteers or patients. This mechanism is explained by the complexation of non-heme iron by the phenolic compounds of green tea, including catechins. Ahmad Fuzi et al. showed that a delay between non-iron heme and tea intake could reduce this interaction14. Two clinical trials studied iron absorption in women drinking different kinds of teas, and both led to the same conclusion14,24. In the only case (CSa5) involving a PACD, methotrexate (MTX), the interaction could be explained by inhibition of the organic anion transporting polypeptide (OATP)1A2. Indeed, EGCG has been described as an inhibitor of OATP1A2-mediated substrate transport on healthy volunteers19, while MTX is a substrate of this transporter in animal models16. In CSa4, a supplement containing a green tea extract (named Mega Green Tea Extract—725 mg a day containing 45% EGCG) could have worsened the hepatotoxicity of anastrazole. Although the mechanism of green tea hepatotoxicity remains unclear, a major safety concern exists when green tea is associated with other hepatotoxic compounds, thus enhancing the risk15.
Cannabis—Cannabis sativa L.
For health care professionals, it is not appropriate to recommend cannabis for therapeutic use, even if the legislation concerning cannabis products is evolving. Cannabinoids are well known for their analgesic activities25. In Csb1-3 (Table 2B), we interpreted those cannabinoids as being the metabolites involved in the interaction. The concomitant administration of cannabinoids from Sativex with other CYP3A4 inhibitors leads to their increased blood levels in healthy human volunteers, suggesting that they could be CYP3A4 substrates26. Otherwise, Cannabidiol is described to inhibit CYP3A4 in vitro with IC50 of 11.7 µM in Human Liver Microsomes27 and Pgp from 5 µM on Caco-2 cells28. In vitro and animal studies have confirmed these pharmacokinetic characteristics of cannabinoids29, which could lead to increased blood levels of Pgp substrates, such as everolimus, nintendanib and palbociclib as described in Csb1 to Csb3 and to increased occurrence of adverse effects. Long-term Marijuana use is also known to cause CNS impairment5. Csb4 describes additive effects (dyspnea and cough) that could have been aggravated by cannabis30,31,32. In the literature, to our knowledge, only two case reports mention a fatal acute respiratory distress syndrome with calfilzomib33,34. If the literature seemed to indicate a relevance of the PD interaction between cannabis and calfilzomib; however, a dechallenge of carfilzomib in Csb4 was done without rapid recovery of the patient. This made uncertain the causality relationship between both products.
Black cohosh—Cimicifuga racemosa (L.) Nutt.
Although studies are inconsistent, some clinical evidence of estrogenic activity support the use of black cohosh to treat climacteric symptoms including hot flushes, sweating, sleep disorders and nervous irritability38. Despite alternative findings in publications concerning patient follow-ups39 as well as meta-analysis of randomized, double-blind, and controlled clinical trials40, a very recent case of hepatotoxicity in patients consuming black cohosh has been published41. Effectively in its latest assessment report 42, EMA mentioned black cohosh as a potentially hepatotoxic, based on European pharmacovigilance signals. For this reason, we decided to extract ICSRs from VigiBase including “Cimicifuga racemosa” and “hepatic disorders” (Standardized MedDRA Queries). 160 reports (data not shown) were found. This high number of ICSRs supported the EMA report. In CR1,2 (Table 3A), hepatotoxicity seemed to be due to OACDs and black cohosh additive adverse effects. Tsukamoto et al.43 showed that the triterpenes glycosides of black cohosh had a weak inhibitory effect on CYP3A4 while fingolimob (in CR1) is a substrate. This PK interaction could have increased the patient’s hepatotoxicity even if a meta-analysis demonstrated no evidence for hepatotoxicity40. Interestingly, in our selected cases, the same supplement was involved (Cimifemin—6.5 mg of dry extract—Ze 450), in case CR1, 2. This product was used in retrospective observational studies44,45 without particular adverse effects. As both reports took place in Switzerland at close dates in 2016/17, it can be reasonably assumed that a particular batch had possibly been incriminated. Unfortunately, herbal food supplements do not have the same regulatory obligation in terms of quality as phytomedicine.
Turmeric—Curcuma longa L.
Turmeric is mainly used to treat digestive disorders, but it has many more uses in traditional Chinese medicine and Ayurveda. Its active compounds are the curcuminoids (3–5%); however, products vary considerably in their chemical composition46. Despite thousands of studies, robust scientific evidence on the effectiveness of turmeric in humans is lacking. Due to the low bioavailability of curcuminoids, doses needed to get an inhibition of hepatic CYP3A4 are usually not reached, but curcuminoids could inhibit intestinal CYP3A447 and thus interact with OACD CYP3A4 substrates 4. It is the case in CL1-5 (Table 3B) and CL7-8. Appiah-Opong et al. showed that curcumin inhibits CYP3A4 in human recombinant microsome preparations (IC50 16.3 µM)48. Curcuminoids also inhibit Pgp (IC50 between 50 to 100 µM)47. In 2019, the British Committee on Toxicity of Chemicals in Food underscored the potential hepatotoxicity of curcumin on basis of in vitro and in vivo studies and case reports49.
In CL6, hepatotoxicity could be due to a PD interaction of MTX and turmeric. In this case, a 39-year-old woman was also consuming linseed oil, but no elements were found in the literature indicating hepatoxicity for this product.
St John’s wort—Hypericum perforatum L.
Considerable clinical data, including Cochrane reviews50,51,52,53,54,55,56, have shown that St John’s wort is superior to placebo and is as effective as synthetic antidepressants in treating certain types of depression. Nonetheless, there is a high potential of interactions with other medicines. St John’s wort is a strong CYP3A4 inducer via one of its constituents, hyperforin4. In HP1, 2 (Table 4), OACDs are CYP3A4 substrates, and this leads to PK interactions and thus a loss of any chance of recovery.
In HP1, the risk may have been greater because of the brief induction power of hyperforin on Pgp4. Hypericin, the other major constituent of St John’s wort can induce photosensitivity after UV exposure and generation of reactive oxygen species57. Hypericin and temozolomide9 share this adverse effect, which can explain the radiation-induced optic neuropathy observed in case report associated with HP358.
Milk thistle—Silybum marianum (L.) Gaertn.
Traditionally milk thistle is used to relieve the symptoms associated with the overindulgence of food and drink, including indigestion. Data to support its use to treat liver disease are mixed59. In vitro and animal studies have shown that silymarin or a mixture of milk thistle flavolignans, inhibits CYP3A4 and Pgp60,61. In animal model, CYP3A4 was also significantly downregulated compared to the control group with big amounts of silybin62.
Interactions in SM1-7 and SM13 (Table 5) probably involve the CYP3A4.
For SM8, potential interactions between silymarin (including silibin) and ACDs on OATP-B1, a liver specific uptake transporter, might be concerned. Wang et al. showed in vitro inhibitory power of flavolignans on OATP-B1 at 50 µM on HeLa cells63 while Fried et al., in a randomized clinical trial, observed blood concentrations of 2.1 µM of silybin-A after administration of 3 capsules of Legalon 140 mg a day64. This suggests a likelihood of PK interactions in present ICSRs that might have contributed to increasing the rare cutaneous side effect of ACD65. In SM12, describing abdominal pain with co-administration of Legalon with Vincristine and MTX, PK interaction with CYP3A4, PgP and OATP-B1 could be incriminated. Potential interactions in SM9-11 could be explained by the effects of OACDs and milk thistle compounds on CYP2C9. Silibin A and B have shown inhibitory properties on CYP2C9 with IC50 of 8.2 to 18 µM and on recombinant CYP2C9 with IC50 of 2.4 to 19 µM depending on the genotypes66. A recent case report supports this hypothesis67.
In the majority of ICSR (12/13), the phytomedicine Legalon is suspected to interact. Legalon is a formulation of silymarin containing 108.2 mg Silymarin standardized on silibinin9. The robust chemical quality helps healthcare providers to argue potentially pharmacokinetic interactions.
Mistletoe—Viscum album (L.)
In central Europe, European mistletoe preparations are not only among the most common types of treatments used in integrative medicine but also have been among the most prescribed cancer treatments in Germany in 2010. The dense literature on medical uses of mistletoe often gives indications that it improves the patient’s quality of life, but this is not considered conclusive yet70,71. While it may seem paradoxical that cytotoxic metabolites72 from mistletoe (as they kill cancer cells in vitro, down-regulate genes involved in tumor progression, malignancy, and cell migration and invasion) simultaneously helps the patients' well-being, some argue that Mistletoe increases the immune activity73,74,75. The second point that raises questions about these therapeutics comes from the specific products used. As demonstrated by our group, mistletoe extracts have different chemical compositions depending on the brand name and the host trees. This could be related to the manufacturing process using fermentation or not; Abnoba viscum is unfermented and the others are fermented75,76,77. 8 ICSRs are linked to Abnoba viscum products, 3 Helixor, 1 Iscador and 1 unknown (Table 6A). A multicentric observational study from Steele et al.77 in Germany shows that it is difficult to draw strong conclusions due to large variations in exposure frequencies of different preparation types. In our study, VA1-6 detailed hematological toxicity mostly due to concomitant use of Abnoba products, VA7-9 involved gastro-intestinal, VA10-13 cutaneous disorders and VA11-12 general disorders. Mistletoe extracts are to be considered in an original way, all cases might involve PD mechanisms and all implicated PACD except in VA13 which concerns anastrazole. Data involving cytochromes and modification of metabolization78,79,80,81,82 were scarce but often reassuring.
Ginger—Zingiber officinale Roscoe
Ginger is one of the most widely used herbal medicine and has a history of traditional use around the world. There is scientific evidence to support its use as antiemetic and for digestive complaints including chemotherapy-induced nausea and vomiting 84,85.
In cases ZO1,2 and ZO3 (Table 6B), potential interactions are certainly due to CYP3A4 for all of them and Pgp for ZO2,3. Tyrosine Kinase Inhibitors (TKI) involved in these cases are substrates of CYP3A4, Pgp or both. 6-gingerol is known to inhibit CYP3A4 and Pgp at blood concentrations from respectively 60 and 100 µM in vitro85, while 8-gingerol displays an IC50 of 8.7 µM on CYP3A4 in vitro86. Recent case reports seem to support these experimental data87,88 describing hepatic damages. Indeed, Bilgi et al. have published a cumulative hepatotoxicity with imatinib due to a PK interaction where ginseng inhibits CYP3A487 while Revol et al. have demonstrated that crizotinib promotes severe hepatic cytolysis after the combination of ginger intake with this drug88. Again, the inhibition of CYP3A4 and Pgp was pointed.
Discussion
Pharmacovigilance is a critical component of facilitating a clinician’s decision to alter or discontinue a patient’s therapy, including natural therapies. However, the increase in self-administration of OACD, requiring fewer clinical visits than PACD, may potentially lead to under-reporting of ADRs. Under-reporting is a setback in the early detection and assessment of safety problems. Significantly, only 1057 ICSR involving one of the ten most common herbs and one or more drugs from L01 and/or L02B ATC class were retrieved. Only 15 countries have reported more than 15 ICSRs. Our analysis is qualitative, not quantitative. We have chosen 10 plants based on our knowledge of consumption in Europe. From ICSRs reviewed, we sought to rationalize them consulting literature from clinical studies to in vitro data. The first factor that led us to reject the ICSR for interpretation was the presence of too many drugs or herbs (≥ 3). This was particularly the case for herbs involved in traditional Asiatic medicine. The second factor for excluding an ICSR was because it was not detailed enough, or the ADR was not clear. ICSRs were also excluded when the quality of the declaration was not sufficient for our interpretation (NB: the quality of the ADR description is not linked to the professional status of the declarants), thus leading finally to 51 ICSRs. It is noteworthy to mention that process of exclusion leads probably to underestimation of the number of herb-drug interactions but was necessary to ascertain the causality of the interaction.
The major risks associated with the use of herbal products and ACD are HDI. It is particularly undesirable in cancer management because of the narrow dose–effect relationship and toxicity of chemotherapeutic agents. Different ADRs have been observed in VigiBase, but the most common ones are liver or hematological toxicities and nausea. A particular interest was given to OACD for 2 main reasons. First, from a global/public health approach, OACD development is responsible for increasing health cost expenditures89. The economic sustainability of this care should not be thwarted by inappropriate complementary therapeutic habits. Secondly, in a more patient-centered approach, OACD not only implies greater autonomy and responsibility for their own care, but also raises adherence challenges90. However, patients are often not sufficiently educated about the potential risks of the simultaneous uses of different medications91. In these circumstances, the herb-OACD interaction risk is mathematically greater including (a) ADRs (due to an increase of AUC) and (b) risk for recurrence and mortality with no ADR observed but a decrease in ACD plasmatic concentrations due to the interaction. Twenty-nine declarations concerned OACD (vs. 22 PACD), and 31 involved PK interaction (vs. 19 PD & 1 both). The notations concerning mistletoe are original and imply only PD interactions and a large majority of PACDs.
The most common mechanism of HDI is PK with the herbal-mediated inhibition and/or induction of drug-metabolizing enzymes and/or transport proteins leading to the alteration of the body concentration of the active drug. Most mechanistic research published has focused on in vitro experiments. Extrapolating in vitro findings to predict clinical relevance is not trivial.
On the contrary, only 11 clinically relevant herb-drug interaction studies have been published at this time92.
In our opinion, the main limitation of this article comes from the lack of knowledge about the herb’s galenic form (herb powder, aqueous extract, hydro-alcoholic, essential oil or other food supplements form). So, it is difficult to rationalize/interpret the molecule(s) involved in the interaction. In general, no indication of the posology or herb treatment duration is present. Therefore, among other things, we conscientiously estimated the interaction using a 2 score indexes. In our study based on “real-life” patient ADRs, we sought to rationalize the ICSRs observed according to the literature to score the causality (using 1 or 2 *) and the clinical risk of encountering interactions (using alpha-numeric quotation). With this quotation, the highest risk was observed in interactions between cannabis or St. John's wort and TKIs when drug levels in plasma were decreased (or the tumor marker was increased), thus leading to a bigger risk of death.
Nevertheless, 5% of the 1057 ICSRs (51 cases) declared in VigiBase are rationalizable (or 40% of the 134 selected ICSRs as interpretable) by careful analysis of the literature. Moreover, 20% of those ICSRs (51 cases) were related to ADRs with a duration over 7 days and in 8% of the cases, the life risk was engaged due to HDIs. The highest number of ICSRs was observed with Milk thistle (Table 5). 25 of the ICSRs (about 50%) described in our tables involve protein kinase inhibitors. The 2 most represented NCIs in Table 5 (Milk Thistle) are gefitinib and sorafenib. It is important to note that the typology of ADRs is completely different with injected mistletoe with pharmacodynamic mechanisms.
The health care community has a great need for appropriate phytovigilance for the use of herb supplements. The importance of phytovigilance in oncology must be highlighted to improve safety and to offer cancer patients an improved quality of life during such a critical period of their lives. Lastly, we were surprised by the low total number of ICSRs. We thus strongly encourage more strenuous and detailed reporting and declarations of adverse events even in the context of herb-drug interactions. Risk minimization measures would be needed. In this purpose, health professionals should be informed about risks of interactions to reduce the occurrence of HDI. Various research groups are working on the subject. The NCCIH from NIH provides herbal monographs to enable clinicians to make informed choices (https://www.nccih.nih.gov/health/herbsataglance). Others are publishing combining computational, experimental and clinical approaches to better manage the use of plants93,94.
We are also working in this direction in order to produce a database available online and always up to date using machine learning (with HEDRINE for Herb Drug Interaction databasE at www.hedrine.ulb.be).
Data availability
The data that support the findings of this study are available from F. Souard, but restrictions apply to the availability of these data, which were used under license for the current study, and so are not publicly available. Data are however available from the authors upon reasonable request and with permission of J. Hamdani.
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Acknowledgements
F.S., S.P., V.M., C.D.V., A.S.L. thank the Belgian Human Pharmacovigilance Evaluation cell. F.S. thanks P.V.A. for facilitating the interview with the pharmacovigilance team. A very special thanks to Kelsey Hull for the English correction of this article.
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Designed Research: All authors. Contributed Analytical Tools (VigiBase requests): C.L., J.H. Analyzed Data: F.S., S.P., A.S.L. Performed Research (bibliographical research, selection and evaluation of articles, their final selection): F.S., S.P., A.S.L. Wrote Manuscript: F.S., S.P., A.S.L. Careful rereading of the manuscript: All authors.
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Pochet, S., Lechon, AS., Lescrainier, C. et al. Herb-anticancer drug interactions in real life based on VigiBase, the WHO global database. Sci Rep 12, 14178 (2022). https://doi.org/10.1038/s41598-022-17704-z
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DOI: https://doi.org/10.1038/s41598-022-17704-z
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