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The Quantitation of Nimetazepam in Erimin-5 Tablets
and Powders by Reverse-Phase HPLC
Yong Kiong Chong, Muzaiyanah Mohd Kaprawi, and Kee Bian Chan*
Narcotics Section, Forensic Division
Department of Chemistry Malaysia
Jalan Sultan, 46661 Petaling Jaya
Malaysia
[email: kbchan -at- kimia.gov.my]
ABSTRACT: The sedative-hypnotic nimetazepam in “Erimin 5” tablets
and powders was quantitated by reverse phase HPLC. The selectivity, precision,
and accuracy of the procedure are presented.
KEYWORDS: Nimetazepam, Erimin-5, Benzodiazepines, HPLC, Forensic Chemistry
Figure 1: Structure of Nimetazepam
Introduction
Since its appearance in illicit
drug markets in Malaysia in the mid-1980’s,
the benzodiazepine nimetazepam (Figure 1) has become the most commonly
abused sedative in the country (midazolam and triazolam are the (distant)
second and third most abused sedatives). The popularity of nimetazepam
is due in part to its wide availability and relatively low price on the
local black markets, and in part due to its long activity. Most of the
abusers are believed to be heroin addicts, who use it as a substitute
for heroin when its availability is low. More recently, however, nimetazepam
has also been used as a sedative by methamphetamine abusers to help them
sleep after binging (in fact, the rise in nimetazepam abuse roughly parallels
the rise in methamphetamine abuse in Malaysia). The illicit use of nimetazepam
is continuing to increase, as shown by the number and size of seizures
made over the past few years. For example, a seizure of 310,000 tablets
was made in June 2002 at a residence near the capital city (Kuala Lumpur).
Tablet submissions to the Central Laboratory have been in the hundreds
of thousands for each of the three years 2002 - 2004. Similar abuse of
nimetazepam has been reported in neighboring countries.
The two primary forms of nimetazepam encountered in Malaysia are a commercial
product (Erimin-5 tablets in blister packs (see Photos 1 - 2)) or Erimin-5
counterfeits, and an orange colored powder that appears to be either
finely crushed tablets or the tablet mixture prior to tableting. Commercially
prepared tablets nominally weigh
about 170 mg and contain about 5 mg of nimetazepam each. However, as
noted above, many of the Erimin-5 tablets submitted to the Narcotics
Section appear to actually be counterfeit products that contain nimetazepam
and/or various other benzodiazepines, notably diazepam and nitrazepam,
in varying quantities.
Nimetazepam was added to the Malaysian Dangerous Drugs Act 1952 in May,
2001 and is currently the only benzodiazepine controlled in Malaysia.
The analysis of nimetazepam by a variety of techniques has been previously
reported (1-4), including by CE and CEC (5-7), Color Testing (8), FTIR
(9), GC (10-12), HPLC and HPLC/MS (13-18), TLC (17,19), and UV/Vis (20).
Herein, we report the quantitation of nimetazepam in seized tablets and
powders with reverse-phase HPLC, using an external standard method.
Photo 1 - Front and Back Views of a Erimin-5 Blister
Pack (Note: This is a Suspected Counterfeit)
Photo 2 - Closeup of an Erimin-5 Tablet (Front and Reverse)
Experimental
Chemicals
HPLC grade methanol and chloroform were purchased from Merck, while AR
grade orthophosphoric acid (84 %) was purchased from Ajax (Australia).
Nimetazepam (free-base) standard of 100 % purity was kindly provided
free of charge by Sumitomo Chemical Company (Tokyo, Japan). The following
benzodiazepines (as free bases) were obtained from the United Nations
Drug Control Programme (UNDCP) in Vienna (Austria): Nitrazepam, bromazepam,
tetrazepam, flunitrazepam, oxazepam, lorazepam, clorazepate dipotassium
(salt), diazepam, flurazepam, and medazepam. Unfortunately, midazolam
and triazolam standards were unavailable, and so were not run.
Instrumentation
A Hewlett Packard Series 1050 HPLC was used with the following parameters:
| Column |
C-18, 5 µm
particle size, 15 cm x 4.6 mm i.d. (from Alltech). |
| Detector: |
UV
at 265 nm. |
| Mobile
phase: |
Methanol:Water (50:65). The pH was adjusted to 4.0
with orthophosphoric acid (to a mixture of 500 mL of methanol and
650 mL of water was added one drop of orthophosphoric acid) (21). |
| Column
temperature: |
25° C
(ambient temperature). |
| Flow rate: |
1.5 mL/minutes. |
| Average Pressure: |
155 bar. |
| Injection: |
20 µL by Rheodyne
loop injector. |
| Attenuation: |
4 (Integrator). |
Standard Solutions for Linearity Study and Calibration
Standard solutions containing 0.020, 0.040, 0.080, 0.120, 0.160, 0.200
and 0.240 mg/mL of nimetazepam were prepared in a mixture of methanol/chloroform
(5:1) (note that the chloroform was added to better solubulize the
tablet materials, and had no adverse effects on the chromatography).
Quantitative Analysis of Samples
About 70 - 100 mg of homogenized tablet material was accurately
weighed into a 25 mL volumetric flask and made up to volume with a mixture
of methanol/chloroform (5:1). The sample solution was ultrasonicated
for 5 minutes and filtered through a 0.45 µm filter before injected
onto the column. Quantitation was by external standard and with reference
to the peak area of the 0.120 mg/mL nimetazepam standard.
Procedure for Standard Addition Method
(i) 350.80 mg of tablet material was weighed into a 100 mL volumetric
flask, made up to volume with methanol/chloroform (5:1), and ultrasonicated
for 5 minutes. (ii) 10 mL of the solution in (i) (i.e., equivalent
to 35.08 mg of tablet material) was pipetted into each of five 25 mL
volumetric flasks. (iii) The following aliquots of nimetazepam standard
stock solution (1.00 mg/mL) were pipetted into the solutions in (ii):
0, 1, 2, 3, and 4 mL. (iv) The solutions were made up to volume (i.e.,
25 mL) with methanol/chloroform (5:1). (v) The solutions were filtered
through a 0.45 µm filter and injected into the HPLC. (vi) A graph
of area versus concentration of nimetazepam (mg/mL) was plotted using
Excel and the native nimetazepam content calculated.
Results and Discussion
Selectivity
Identification of benzodiazepines is accomplished in this laboratory
by GC/MS. However, GC and GC/MS are problematic for quantitation of
nimetazepam and some related benzodiazepines due to thermal degradation
at injector port temperatures, and so HPLC was selected for quantitation.
Because of the wide diversity of chemical structures and solubility
characteristics among the benzodiazepines, no single HPLC method will
separate all of them. The specificity of the method presented herein
was defined in terms of the benzodiazepines typically found in Malaysia.
The identities and
retention times of these benzodiazepines using the presented methodology
are presented in Table 1.
Table 1: Retention Times of Benzodiazepines (HPLC)
| Benzodiazepine |
Retention Time (min) |
| Nitrazepam |
6.91 |
| Bromazepam |
7.62 |
| Tetrazepam |
7.80 |
| Flunitrazepam |
8.54 |
| Oxazepam |
8.55 |
| Lorazepam |
8.93 |
| Nimetazepam |
9.94 |
| Clorazepate dipotassium |
17.07 |
| Diazepam |
26.63 |
| Flurazepam |
NE |
| Medazepam |
NE |
Figure
2: HPLC of Nitrazepam and Nimetazepam Note: Slight variations in
Retention Times between Table 1 and Figure 2 are due to natural
variations over time; the order of elution was found to be consistent
from run to run. |
Of the selected
benzodiazepines, flunitrazepam, oxazepam, and lorazepam elute closest
to nimetazepam, and give partially overlapping
peaks. Thus, the presented HPLC method is not appropriate for samples
containing these compounds. Fortunately, however, experience has shown
that these three benzodiazepines are very rarely present in tablets or
powders containing nimetazepam. A few samples of “Erimin-5” tablets
have been found to contain diazepam instead of nimetazepam; however,
diazepam elutes much later than nimetazepam. A typical HPLC chromatogram
of a mixture of nitrazepam and nimetazepam is displayed in Figure
2.
Calibration Curve and Linearity
The calibration graph (Figure 3) for the analysis was found
to be linear from 0.020 mg/mL to 0.240 mg/mL. From linear
regression analysis, the correlation coefficient was better
than 0.99, and the percent difference between the known
concentration and the predicted concentration from the
regression equation was less than 5 %. In routine analyses
a single point calibration was used.
Precision
The precision of the method was assessed by 10 replicate
analyses of a homogenized sample of “Erimin 5” tablets.
Injections were all made in triplicate and quantitation was against the
0.120 mg/mL standard. The mean content of nimetazepam was found to be
3.1 % with a relative standard deviation of 4.4 %.
Figure
3: Calibration Curve of Nimetazepam
Accuracy
The accuracy of the method was assessed by analyzing two laboratory
prepared mixtures, and re-analysis of the sample which was used for the
precision study by the method of standard addition.
Analysis of Laboratory Prepared Mixtures
Owing to the limited supply of pure nimetazepam reference standards,
only two synthetic mixtures were prepared, simulating 5 mg/tablet
and 3 mg/tablet. Both the samples were prepared in lactose and contained
3.5 % and 1.7 % of nimetazepam, respectively. Replicate analyses (n
= 7) of these two mixtures were made and the results assessed using
the Student t-statistic:
For
both samples it was found that the t value did not exceed the critical
value derived by statistical analysis, showing that
there was no proven evidence of difference between the experimental
value and the theoretical value at 95 % confidence level.
Standard
Addition Method
The same nimetazepam tablet material which was used in the precision
study was re-analyzed using the standard addition method. From
the standard addition calibration graph (Figure
4) the amount of
nimetazepam
was found to be 3.1 %. This agreement with the precision study
mean value shows that there is no interference from the tablet excipient
materials, and thus to some extent shows that the method is accurate.
Figure 4: Standard Addition Calibration Curve
Acknowledgments
The
authors would like to thank Dr. Yoji Sakito, Manager, Corporate Planning & Coordination
Office, Sumitomo Chemical Company Ltd, Tokyo, Japan for the nimetazepam
reference standard used in this study.
References
-
Recommended
Methods for Testing Benzodiazepine Derivatives under International
Control; Manual for Use by National Narcotic Laboratories;
United Nations, New York: 1988.
-
Scholermann
K, Schutz H. Screening and detection of nimetazepam and its
chief metabolites. Beitr Gerichtl Med. 1990;48:657.
-
Nimetazepam.
http://chrom.tutms.tut.ac.jp/JINNO/DRUGDATA/33nimetazepam.html
-
Terry Mills
III, J. Conrad Roberson, H. Horton McCurdy, and William H.
Wall. Instrumental Data for Drug Analysis, 2nd Ed., Vol. 5, pp. 306
- 307; Elsevier, New York: 1987.
-
Jinno K, Sawada H, Catabay AP, Watanabe H, Haji-Sabli NB, Pesek
JJ, Matyska MT. Comparison of separation behavior of benzodiazepines
in packed capillary chromatography and open-tubular capillary
electrochromatography. J. Chrom. A 2000;887(1-2):479-487.
-
Jinno K, Han
Y, Sawada H, Taniguchi M. Capillary electrophoretic separation
of toxic drugs using a polyacrylamide-coated capillary. Chromatographia
1997;46(5/6):309-314.
-
Jinno K, Han
Y, Nakamura M. Analysis of anxiolytic drugs by capillary electrophoresis
with bare and coated capillaries. J. Capillary Electrophor.
1996;3(3):139-145.
-
Koga S, Fuchi K, Irikado T. Color testing of benzodiazepine
type psychotropic drugs using Zimmermann’s reagent. Kanzei
Chuo Bunsekishoho 2000;40:67-71.
-
Hida M, Mitsui
T. Rapid searching method of tablet samples by micro-FTIR.
J. Health Sci. 1999;45(4):226-231.
-
Hida M, Mitsui
T, Ohtani H, Tsuge S. Determination of benzodiazepines in tablets
by thermal desorption gas chromatography. J. Pharm. Biomed.
Anal. 1999;20(3):419-426.
-
Shimano M,
Inoue Y, Yoko M, Matsuzaki R, Inde S, Yagasaki K. Qualitative
analysis of psychotropic drugs by capillary gas chromatography
using NPD. Kanzei Chuo Bunsekishoho 1995;34:87-92.
-
Kurazono K,
Matuzaki R, Nagai M, Inde S, Yagasaki K. Analysis of psychotropic
drugs by gas chromatography. Kanzei Chuo Bunsekishoho 1994;33:49-53.
-
Lim WJL, Lee TK, Mangudi M, Selvi TS. A study of “Erimin
5" tablets seized in Singapore. ANZFSS 17th International
Symposium on the Forensic Sciences 2004 (Abstract of Presentation).
-
Sato K, Mizuno
Y, Kobayashi K, Sano T, Taguchi T, Shimizu T, Lee X-P, Katsumata
Y. Capillary high-performance liquid chromatography/fast-atom
bombardment-mass spectrometry of 26 benzodiazepines. Jpn.
J. Forensic Toxicol. 2000;18(1):32-38.
-
Catabay A,
Taniguchi M, Jinno K, Pesek JJ, Williamsen E. Separation of
1,4-benzodiazepines and analogs using cholesteryl-10-undecenoate
bonded phase in microcolumn liquid chromatography. J. Chromatogr.
Sci. 1998;36(3):111-118.
-
Akieda T, Inoma
S. The analysis of psychotropic substances by high performance
liquid chromatography (HPLC) and high performance liquid
chromatography-mass spectrometry (HPLC-MS). II. Kanzei Chuo
Bunsekishoho 1995;34:65-86.
-
Fujimura T,
Akieda T, Inoma S. Analysis of psychotropic drugs by high performance
liquid chromatography and thin layer chromatography.
Kanzei Chuo Bunsekishoho 1994;33:65-74.
-
Shimamine M,
Masunari T, Nakahara Y. Identification of drugs of abuse by
diode array detection. I. Screening test and identification
of benzodiazepines by HPLC-DAD with ICOS software. Eisei
Shikensho Hokoku 1993;111:47-56.
-
Schutz H, Rumpf
E. TLC screening of 1,4-benzodiazepines. Adli Tip Dergisi (Turkey)
1990;6(1-2):3-8.
-
Singh V, Shukla
SK, Mahanwal JS. Detection and determination of benzodiazepines
by derivative UV spectroscopy. Part II. Indian J. Forensic
Sci. 1990;4(2):89-102.
-
Kozu T. HPLC
determination of nitrazepam and its metabolites in human urine.
J. Chromatogr. 1984;310:213-218.
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