Int J App Pharm, Vol 13, Issue 5, 2021, 252-256Original Article

MITRAGYNINE PERCENTAGES OF VARIOUS KRATOM VARIANTS SEIZED IN INDONESIA: A QUANTITATIVE ANALYSIS USING LIQUID CHROMATOGRAPHY-PHOTO DIODE ARRAY DETECTOR

TANTI^*, CHRISTIEN ANDRIYANI LALANGI, ERI ARFIYANI, WIDIANTI NINGTIAS, ERLANA NINDYA MAULIDA

Quality and Research Division, the Center of Narcotics Laboratory of National Narcotics Board (BNN) of the Republic of Indonesia
^*Email: tanti.puslabbnn@gmail.com

Received: 27 Apr 2021, Revised and Accepted: 19 Jun 2021

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ABSTRACT

Objective: This study details the determination of mitragynine in various kratom samples using the thin-layer chromatography (TLC) technique and validation of analytical methods for quantifying the concentration of mitragynine in various kratom samples using liquid chromatography with photodiode array detector (LC-PDA).

Methods: TLC technique using n-hexane: ethyl acetate: ammonia 25% (30: 15: 1 v/v/v) was applied to isolate mitragynine from kratom samples. Several interesting spots obtained were visualized under UV light at 254 nm. Samples were also prepared with organic solvent extraction directly prior to LC analysis (non-isolation method of preparation) to quantify the concentration of mitragynine. Mobile phases used were acetonitrile (MP A) and 0.1% formic acid in water (MP B). Samples and standards were run by gradient elution with a flow rate of 0.3 ml/min, detection using PDA detector at 254 nm.

Results: Mitragynine was successfully isolated from kratom samples in R_f 0.50 by TLC system applied. The validation of analytical methods for mitragynine passed the acceptance criteria as described by UNODC Guidance. The concentration of mitragynine in various kratom samples seized in Indonesia ranged from 0.37%-1.70% (%w/w).

Conclusion: Both TLC and LC analytical methods could be applied to determine and quantify the concentration of mitragynine in each examined sample, respectively.

Keywords: Kratom, Mitragynine, TLC technique, Validation, The concentration of mitragynine, LC, PDA detector

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© 2021 The Authors. Published by Innovare Academic Sciences Pvt Ltd. This is an open access article under the CC BY license (https://creativecommons.org/licenses/by/4.0/)
DOI: https://dx.doi.org/10.22159/ijap.2021v13i5.41910. Journal homepage: https://innovareacademics.in/journals/index.php/ijap

INTRODUCTION

Kratom (Mitragyna speciosa Korth.) is widely cultivated in Indonesia especially in Kalimantan region. The plants are known as ‘purik’ or ‘ketum’ in West Kalimantan, ‘kedamba/kedemba’ in East Kalimantan and ‘kayu sapat/sepat’ in Middle and South Kalimantan. Among the region, West Kalimantan is the largest center of kratom plants in Indonesia. Kratom plants grow abundantly along the Kapuas river in Kapuas Hulu district. Products of kratom cultivated in Indonesia, 90% in the form of kratom powders, are mostly exported to other countries. The society in Kalimantan traditionally used kratom to combat fatigue and enhance stamina by drinking the brewed fresh kratom leaves or powder, sometimes by adding other ingredients such as honey or oranges [1].

The increasing reports of emergency rooms, hospitalizations and deaths related to kratom (mis)use in Western countries have been reported by [2, 3] as associated with the active ingredients of M. speciosa, mitragynine and 7-hydroxy mitragynine. Mitragynine and 7-hydroxymitragynine have an affinity towards opioid receptors and exhibit antinociceptive activity. Despite being a minor component of M. speciosa, 7-hydroxymitragynine was reported to have 46 times greater potency than mitragynine [4, 5]. A growing number of kratom-related death reports were primarily in association with the abuse of other psychoactive substances. Mitragynine was reported in 27 cases as the cause of death and six of these case reports confirmed the presence of mitragynine and/or 7-hydroxy mitragynine solely as main autopsy findings [3].

Mitragynine belongs to indole-based alkaloid which is found as the major constituent of M. speciosa in Asian plants. The percentages of mitragynine are found in different levels depend on the age of the plants, the environment in where it is grown and how it is cultivated [3, 6]. Kratom leaves originated from Indonesia contained the highest level of mitragynine and alkaloid fraction related to mitragynine than those from Southern Thailand and Northern Malaysia [7]. Different varieties, according to the color of kratom leaf veins e. g. red or green kratom and geography are associated with the diversity of alkaloid distribution in each plant and thus impact to its effect on users [8, 9].

To date, kratom plants and/or its main alkaloids are uncategorized as scheduled drugs in Indonesia. The previous analysis of kratom in The Center of Narcotics Laboratory was limited to the qualitative analysis using gas chromatography-tandem mass spectrometer (GC-MS). Due to the abundance of kratom plants in Indonesia, an exploration in kratom research is necessary to enrich data related to kratom in Indonesia. In the present study, we isolated mitragynine from various kratom powders in each specific label using a simple TLC technique followed by GC-MS analysis for determining the isolated compounds. We also measured the concentration of mitragynine from each sample without an isolation step before a quantitative analysis using LC-PDA.

The aims of this study were to determine the major alkaloid of M. speciosa, mitragynine, in various kratom samples seized in Indonesia using TLC technique and to quantify the concentration of mitragynine in the examined samples using an analytical method of LC-PDA that have been completely validated according to the UNODC Guidance [10]. The methods can hopefully be applied for screening kratom products in the drug market.

MATERIALS AND METHODS

Materials

Chloroform, n-hexane, ethyl acetate, ammonia solution 25%, formic acid 98-100% and dichloromethane used were analytical grade. Acetonitrile, methanol and water used were chromatography grade. All solvents were purchased from Merck, Germany.

Samples

Samples analyzed in this study were six kinds of powders in transparent plastic bags with or without any specific labels. All samples were identified based on their physical characteristics such as: sample form, color and weight prior to further analysis. Description of each sample and sample identification are shown in table 1.

Table 1: Physical characterization of each sample including the pictures of sample packaging (with the specific labels) and a unique sample code describing each sample (A-F)

Sample code	Sample packaging with/without any specific labels	Form	Color	Net weight (g)
A		Fine powder	Olive green	12.9000
B		Fine powder	Olive green	14.6000
C		Fine powder	Olive green	13.6000
D		Fine powder	Army green	11.4000
E		Fine powder	Olive green	13.7000
F		Fine powder	Forest green	16.7119

Samples A–E were seized by BNN investigator on August 2019. Another case seized on October 2019 by BNN investigator was sample F. All samples were submitted to The Center of Narcotics Laboratory of BNN in Bogor, Indonesia, a few days after seized. Qualitative analysis using GC-MS was performed to all samples. Based on the result of analysis, samples A–F were found to contain mitragynine, an active alkaloid in kratom plant, so that called as kratom powders. Samples were subsequently transferred to the Research subdivision of The Center of Narcotics Laboratory of BNN for further analysis. This study began in early of 2020. Samples were kept in airtight vials and stored a refrigerator (5-6 °C) to avoid decomposition over the period of storage.

Instrumentation

Separation and determination of mitragynine in kratom powders were performed by TLC method on silica gel 60 F₂₅₄ 10x20 cm plates from Merck, Germany. CAMAG Linomat V was employed to spray varying amounts of extracted samples to the TLC plates. Spots of mitragynine were visualized under UV light at 254 nm using TLC Scanner from CAMAG, Switzerland.

Confirmatory analysis of mitragynine was carried out on GC-MS (EI) Agilent 7890B-5977B MSD. 1.0 µl of the isolated compound was injected according to the split mode, the column was HP-5 MS UI 30 m x 0.25 mm x 0.25 µm. The oven temperature program was set as follows: 50 °C as initial temperature with 50 °C/min to 200 °C (hold for 5 min), followed by 10 °C/min to 300 °C (hold for 10 min). The injector and flow rate was 250 °C and 1 ml/min, respectively. Total run time for each analysis was 40 min.

Quantitative analysis of mitragynine was performed by UPLC-PDA Aquity H+Class (Waters, Singapore). 0.5 µl of extracted samples were injected to LC, the column was Waters Acquity UPLC® BEH C18 2.1 x 100 mm, 1.7 µm (wide bore). Mobile phase (MP) was acetonitrile (MP A) and 0.1% formic acid in water (MP B). Separation was achieved using the following MP gradient as follows: 0–1 min at 80% B decreasing to 50% B in 2 min (hold 1 min), then increasing to 80% B in 4 min. Flow rate was set on 0.3 ml/min. Total run time needed for each injection was 8 min.

Sample preparation

There were two methods of preparation applied in this study, determination of mitragynine in kratom powders by isolation step and quantification of the mitragynine percentages without any isolation step (non-isolation method of preparation). Extraction of kratom powders was the very first step in both methods of preparation.

Isolation method of preparation

200 mg of homogenized samples were extracted with methanol: chloroform (80: 20) then vortexed for about 15 min followed by the filtration step. 1 ml of each of the filtered solutions was evaporated using N₂ gas. The residues were reconstituted with methanol prior to injection to GC-MS. It helped to understand the presence of mitragynine in the extracted samples before the isolation step was performed. To isolate mitragynine from kratom powders, varying amounts of extracted samples were sprayed on the TLC-activated plates. Spraying of the samples was repeated for 6 times in one plate to obtain 6 bands in starting line of the plates. Separation of mitragynine was achieved by n-hexane: ethyl acetate: ammonia 25% (30: 15: 1 v/v/v) [11]. Chamber was saturated for about 30 min at ambient temperature before the migration [12, 13]. Plates were dried at room temperature after the migration. Spots were visualized under UV light at 254 nm using a TLC scanner. Layers of spots of interest were cut out from the plates then homogenized and weighed in three replicates for about 100 mg to extract with methanol, followed by GC-MS analysis.

Non-isolation method of preparation

Method was modified from [14]. 12.5 mg of homogenized samples were extracted with water: methanol (80: 20) then vortexed and sonicated for 10-20 min. Extracted solutions were centrifuged under 6000 rpm. The supernatant of each sample was transferred to the 5 ml volumetric flask. Add methanol until the final volume was 5 ml. Extracted samples were filtered with PTFE filter prior to LC analysis. Extraction for all samples was carried out in three replicates.

Preparation of standard solutions and method validation

Validation of the analytical methods was carried out according to the UNODC Guidance [10]. Reference standard of mitragynine was purchased from Lipomed, Switzerland. A calibration curve of the standard solution was prepared by diluting subsequently the stock solution of mitragynine 100 µg/ml in methanol to six standard solutions in the range of 8.00–75.00 µg/ml, each one in six replicates. A linear regression line equation and correlation coefficient (r) were constructed using the mean of peak areas versus concentrations of six standard solutions.

Accuracy was determined by preparing to reference standard solutions at the low, middle and high concentrations from the range of calibration curve concentration. The limit of detection (LOD), limit of quantification (LOQ) and precision were determined by dissolving varying amounts of non-isolated sample in methanol to obtain a stock solution of mitragynine 200 µg/ml. LOD was measured by diluting stock solution until the lowest concentration that can be detected by the instrument. The peak of mitragynine should be identified in the sample which was shown by the similarity of both retention time and the wavelength to the standard. Repeatability and reproducibility conditions were measured to express the precision of the method. The specificity was investigated as well with AB-FUBINACA, a synthetic cannabinoid class, an example of controlled drugs from other groups.

RESULTS AND DISCUSSION

Optimization of LC method

For the best result of analysis, both isocratic and gradient elution were compared in this study. To evaluate the performance of both elution techniques, the reference standard of mitragynine was analyzed using a mobile phase of acetonitrile: formic acid 0.1% in water and the flow rate was 0.3 ml/min. With PDA detection at 254 nm, mitragynine was detected too early in 0.968 min by isocratic elution. A better separation was achieved by gradient elution where the peak of mitragynine was confirmed at 3.162 min. Henceforward, the gradient elution was applied in the quantitative analysis of mitragynine using LC-PDA.

Analytical method of validation

A calibration curve was linear over the concentration range from 8.00–75.00 µg/ml with the regression line equation of y = 8379.6490x-775.6190. Limit of detection value was 0.4721 µg/ml. All tested validation parameters satisfied the acceptance criteria as validation requirements. Results of method validation are summarized in table 2.

Isolation method of preparation

Extraction and isolation of mitragynine from kratom leaves could be the most important step prior to any analysis scheme because of the complexity of plant chemical constituents [15]. Isolation of mitragynine was performed on all examined samples. Preliminary identification using GC-MS confirmed the presence of mitragynine in each of extracted samples. Fig. 1 shows the result of separation by TLC technique under the TLC Scanner from sample F as representative. All samples exhibited similar profile of TLC chromatogram to F. Several layers of spots of interest were cut out from the plates to perform GC analysis. Upon the previous study of [11], the spots at R_f 0.50 were suspected to be mitragynine.

As the result of this study, mitragynine was successfully isolated from the spot at R_f 0.50 by a developed TLC system. GC analysis showed that isolation of kratom powders resulted in a single peak of mitragynine, and thus differs from the multi peaks of extracted sample chromatograms before the isolation (fig. 2 (B1-C1)). Peaks of mitragynine in extracted and isolated samples have a similar retention time to the standard of mitragynine, 33.407 min (fig. 2 (A1)).

Table 2: Summary of analytical method validation of mitragynine in kratom powders using LC-PDA

Parameters	Results
Linearity and working range	r = 0.999
LOQ (µg/ml)	0.9782
Precision under repeatability and reproducibility conditions (%RSD)	Intra-day = 1.67; Inter-day = 1.62 *)
Accuracy (%RSD)	1.64 *)
Recovery (%)	99.57
Specificity/Selectivity	30.15
Uncertainty	0.47

^*%RSD for the lower concentration

Fig. 1: TLC chromatogram of the extracted sample F under 254 nm wavelength, spots no. 2–6 were replicated to spot no. 1 in equal volume of each spot

In the right panel, fig. 2 (A2–C2) details the MS spectra of the reference standard of mitragynine, an extracted and isolated compound of sample F, respectively. Mitragynine had fragmentation ion at m/z 214.1 (as base peak) followed by m/z 397.2, a similar finding to the previous study by [16]. Other fragment ions obtained were m/z 186.1, m/z 199.1, m/z 269.1, m/z 281.1 and m/z 383.2.

Non-isolation method of preparation

A simple preparation was applied to the samples A–F to do a quantitative analysis using LC-PDA. Extract samples in water: methanol (80: 20) were directly injected to the instrument without any isolation steps before. LC analysis of the samples exhibited a multi-peak on the resulting chromatogram, indicated that there were several compounds detected other than mitragynine. Therefore, the reference standard of mitragynine was used to identify the peak of mitragynine in kratom samples. Mitragynine was identified at approximately 3.117 min and 3.097-3.107 min in the standard and samples, respectively. There was a very slight retention time shift between standard and samples. It probably due to the column overloaded or changes in the mobile phase for each analysis [17]. However, the differences of retention time between standard and samples were less than 2% and thus meet the criteria of acceptance as described by [10]. Furthermore, all samples were confirmed as mitragynine by the similarity of the maximum wavelength (λ_max) to the reference standard of mitragynine which was 222.3 nm (fig. 3). Two other peaks at retention time of±3.15 min and±3.21 min in samples A–F have the maximum wavelength (λ_max) at 222.3 nm. However, the first peak of each sample, which was the highest peak, was supposed to be mitragynine when compared to the standard.

Fig. 2: Left panel, (A1) GC chromatogram of 100 µg/ml standard of mitragynine; overlayed GC chromatogram of (B1) extracted samples A–F in methanol: chloroform (80: 20) and (C1) isolated compound of samples A–F by TLC system at Rf 0.50. Right panel: MS fragment spectra of mitragynine of (A2) 100 µg/ml standard; (B2) extracted sample F as representative; (C2) isolated compound of sample F as representative

Fig. 3: LC chromatogram and PDA UV/Vis spectrum of mitragynine in (a) Reference standard of mitragynine 50 µg/ml and (b) samples A–F

The concentration of mitragynine in each sample was measured by plotting the mean areas of mitragynine to the calibration curve of y = 8379.6490x-775.6190. Weight by weight percentage (%w/w) of mitragynine was calculated with the following formula. Results of the analysis were shown in table 3.

Table 3: Quantitative analysis of mitragynine in various kratom powders

Samples	Quantity of mitragynine (µg/ml)	Quantity of mitragynine (%w/w)
A	20.6842±0.47	0.83
B	14.2177±0.47	0.57
C	15.1779±0.47	0.61
D	31.3860±0.47	1.25
E	9.2859±0.47	0.37
F	42.4476±0.47	1.70

The concentration of mitragynine in samples A–F ranged from 0.37%-1.70% (table 3). In this study, kratom sample in the transparent plastic bag without any specific label (sample F) had the highest mitragynine concentration among others, followed by ‘Green’ kratom label (sample D). The lowest concentration of mitragynine was detected in the product of ‘Yellow’ label (sample E). The data show that kratom variants have an influence on the distribution of alkaloids in kratom plants, in this case was mitragynine. All samples have a lower concentration of mitragynine than kratom powders studied by [5]. Nowadays, sales of kratom products in many different types of kratom strains are very massive on the internet with no guarantee of the products purity as well as the concentration of mitragynine nor other alkaloids present in the products. The prices of each product are different to each other depends on the strains or varieties of kratom. The differences in the concentration of mitragynine are likely having an impact on the quality and potency though the effects of kratom used are relying on the dosage and also the administration of kratom consumption whether it is used solely or in combination with other psychoactive drugs.

CONCLUSION

In this study, extraction of methanol: chloroform (80: 20) was established prior to isolation of mitragynine from various kratom powders by TLC system. Mitragynine was detected from the layer of spots at R_f 0.50 in confirmatory analysis using GC-MS. For quantitative analysis, gradient elution was chosen for LC separation. The analytical method of LC-PDA was linear at the concentration range of 8.00–75.00 µg/ml with r = 0.999. Other validation parameters tested satisfied the requirements and thus valid for measuring the actual concentration of mitragynine in kratom samples. The concentration of mitragynine in various kratom variants seized in Indonesia varied from 0.37%-1.70% (%w/w).

ACKNOWLEDGEMENT

The authors would like to acknowledge the Center of Narcotics Laboratory of BNN, Republic of Indonesia for facilitating this study and for the BNN investigators who submitted kratom samples to our Lab.

FUNDING

Nil

AUTHORS CONTRIBUTIONS

T and CAL developed the concept of the study and supervised the study. EA performed the method validation. WN conducted the study including sample preparation, sample isolation and quantitative analysis. EA and WN analyzed and interpreted the data. ENM contributed in writing the manuscript. All authors agreed to the final version of this manuscript.

CONFLICTS OF INTERESTS

The authors have no conflicts of interest.

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