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Sains Malaysiana 48(5)(2019): 1011–1018
http://dx.doi.org/10.17576/jsm-2019-4805-09
Development of an HPLC Method for Formic
Acid Analysis through Peak Exclusion Approach (Pembangunan Kaedah
HPLC bagi Analisis Asid Formik
melalui Pendekatan
Pengecualian Puncak) DANIYAL HASAN1,
IRAM
MAHMOOD2*,
ISHFAQ
AHMAD3,
FARAH
AZIZ4
& ISHAQ AHMAD5,6 1School of Chemical
and Materials Engineering, National University of Science and
Technology, Sector H-12, Islamabad, Pakistan 2Department of Industrial
Engineering, College of Engineering, King Khalid University, Abha 61413, Kingdom of Saudi Arabia 3Department of Mathematics
and Statistics, Faculty of Basic and Applied Sciences, International
Islamic University, Islamabad, Pakistan 4Department of Public
Health, Faculty of Applied Medical Sciences, King Khalid University
Khamis Mushait, Kingdom of Saudi
Arabia 5National Center for
Physics, Islamabad, 44000, Pakistan 6NPU-NCP Joint International
Research Center for Advanced Nanomaterials and Defects Engineering,
Northwestern Polytechnical University,
Xi’an 710072, China Diserahkan: 6 Februari 2019/Diterima: 7 Mac 2019 ABSTRACT High Performance Liquid Chromatography
(HPLC) is a chemical analysis technique
that gives both the quantitative and qualitative analysis of liquid
samples. A certain set of parameters, called HPLC method, are defined for analysis
of every discrete mixture. Often literature is not available or
specifically reported expensive HPLC apparatus is not available for every
set of mixtures. Present study concentrated on analysis of formic
acid from a mixture of methanol, formaldehyde and water. Formic
acid is a basic carboxylic acid that has growing industrial and
commercial uses, especially as a refrigerant. A C-18 column was
utilized for the analysis by optimizing the parameters like dimensions
of the stationary column, nature of mobile phase, flow rate of
mobile phase and wavelength of the ultraviolet detector. Comprehendible
and reproducible results for the analysis of formic acid were
obtained on 25 cm long C-18 stationary column, by tuning the combined
effect of water as mobile phase at a flow rate of 1 mL/min and
by excluding the unnecessary peaks at 250 nm wavelength of ultraviolet
detector, called peak exclusion approach. The calibration curve
was found to be linear over the range of 1.25 % v/v formic acid
solution in methanol up to 100 % pure formic acid. Limit of detection
(LOD) and limit of quantitation (LOQ)
were found to be 2.25 % and 6.83 %, respectively. Keywords: C-18 columns; calibration;
flow rate; formic acid; peak exclusion ABSTRAK
Kromatografi Cecair Prestasi Tinggi (HPLC)
adalah teknik
analisis kimia yang memberikan analisis kuantitatif dan kualitatif bagi sampel cecair. Satu set parameter yang dipanggil
kaedah HPLC ditakrifkan
untuk analisis
setiap campuran diskret. Selalunya, kajian kepustakawan tidak diperoleh atau dilaporkan secara khusus untuk
setiap set campuran
kerana radas HPLC yang
mahal. Kajian
terkini tertumpu kepada analisis asid formik daripada
campuran metanol,
formaldehid dan air. Asid formik adalah
asid karboksilik
asas yang digunakan secara meluas di dalam industri dan komersial, khususnya sebagai bahan penyejuk. Kolum C-18 telah digunakan untuk analisis dengan mengoptimumkan parameter seperti
dimensi kolum pegun,
jenis fasa
mudah alih, kadar
aliran fasa
mudah alih dan
panjang gelombang
pengesan ultraungu. Keputusan yang boleh difahami dan boleh
ulang untuk
analisis asid formik
telah diperoleh
pada 25 cm panjang kolum pegun C-18, oleh penalaan kesan
gabungan air sebagai
fasa bergerak pada
kadar aliran
1 mL/min dan tidak termasuk
puncak tak
perlu pada 250 nm panjang gelombang pengesan ultraungu, dikenali sebagai pendekatan pengecualian puncak. Lengkung tentukuran didapati linear ke atas julat
larutan asid
formik 1.25 % v/v dalam metanol sehingga 100 % asid formik tulen.
Had pengesanan (LOD)
dan had pengiraaan (LOQ)
masing-masing ialah
2.25% dan 6.83%. Kata kunci: Asid
formik; kadar
aliran; kolum C-18; penentukuran; pengecualian puncak RUJUKAN Ettre, L. 1993. Nomenclature for chromatography
(IUPAC Recommendations 1993). Pure and Applied Chemistry 65(4):
819-872. Godin,
J.P., Hau, J., Fay, L.B. & Hopfgartner,
G. 2005. Isotope ratio monitoring of small molecules and macromolecules
by liquid chromatography coupled to isotope ratio mass spectrometry.
Rapid Communications in Mass Spectrometry 19(18): 2689-2698.
Hostettmann, K.M., Hostettmann, M. & Marston, A. 1998. Preparative Chromatography
Techniques Applications in Natural Product Isolation. 2nd
ed. Berlin Heidelberg: Springer Berlin Heidelberg. Heuer, V., Elvert,
M., Tille, S., Krummen,
M., Mollar, X.P., Hmelo,
L.R. & Hinrichs, K.U. 2006. Online
δ13C analysis of volatile fatty acids in sediment/porewater
systems by liquid chromatography-isotope ratio mass spectrometry.
Limnol. Oceanogr. Methods 4:
346-357. Krummen, M., Hilkert, A.W., Juchelka, D., Duhr, A., Schlüter, H.J. & Pesch, R. 2004. A new concept for isotope ratio monitoring
liquid chromatography/mass spectrometry. Rapid Commun.
Mass Spectrom. 18(19): 2260-2266.
Lee,
X., Zhang, L., Huang, D., An, N., Yang, F., Jiang, W. & Fang,
B. 2013. Analysis of the stable carbon isotope composition of
formic and acetic acids. Analytical Biochemistry 436(2):
178-186. Levigne, S., Thomas, M.,
Ralet, M.C., Quemener, B. &
Thibault, J.F. 2002. Determination of the degrees of methylation
and acetylation of pectins using a C18
column and internal standards. Food Hydrocolloids 16(6):
547-550. McMurry, J. 2011. Organic
Chemistry: With Biological Applications. 2nd ed. Belmont,
CA: Brooks/Cole. p. 395. McNaught, A.D. & Wilkinson,
A. 1997. Compendium of Chemical Terminology. IUPAC Recommendations.
2nd ed. USA: Blackwell Science. Morrison,
F.A. 2014. Obtaining Uncertainty Measures on Slope and Intercept
of a Least Squares Fit with Excel’s LINEST. Houghton, Michigan,
USA Department of Chemical Engineering, Michigan Technological
University. p. 25. Mubeen, A.K., Sinha, S.,
Parashar, V. & Khandekar,
N. 2011. A validated NP-HPLC method for the determination of formic
acid in pharmaceutical excipient imidurea.
International Journal of Pharmaceutical and Biomedical Research
2(3): 140-144. Shrivastava, A. & Gupta, V. 2011. Methods
for the determination of limit of detection and limit of quantitation
of the analytical methods. Chronicles of Young Scientists 2(1):
21-25. Tagami, K. & Uchida, S. 2008. Online
stable carbon isotope ratio measurement in formic acid, acetic
acid, methanol and ethanol in water by high performance liquid
chromatography-isotope ratio mass spectrometry. Analytica
Chimica Acta 614(2): 165-172.
Taylor, T. 2015. Important aspects
of UV detection for HPLC. LCGC North America 33(11): 870.
*Pengarang untuk surat-menyurat; email: irahmad@kku.edu.sa
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