Farmaka

Abstrak

Molecule Imprinting Polymer (MIP) merupakan salah satu pemisahan yang banyak digunakan, karena pada pemisahannya MIP telah mencetak molekul target sehingga bisa digunakan lebih efektif dan spesifik. Pada sintesis MIP diperlukan porogen sebagai suatu solven yang akan membantu membentuk pori pada polimer. Polaritas dari suatu porogen yang digunakan ini memiliki pengaruh pada MIP yang dibuat. Oleh  karena itu, dilakukan review dari artikel yang menggunakan suatu porogen yang lebih polar atau lebih non polar untuk melihat perbandingan hasil dari penggunaan porogen dengan perbedaan polaritas dan mengetahui bagaimana memilih porogen yang baik berdasarkan polaritasnya. Metode dilakukan dengan membandingkan hasil dari 20 artikel mengenai nilai %recoveries-nya, dimana 10 artikel menggunakan porogen yang lebih polar dan 10 artikel menggunakan porogen yang lebih non polar. Nilai %recoveries pada metode ruah dari penggunaan porogen polar lebih besar dibandingkan penggunaan porogen yang lebih non polar. Nilai %recoveries pada metode pengendapan dari penggunaan porogen polar lebih besar dibandingkan penggunaan porogen yang lebih non polar. Jadi penggunaan porogen yang lebih polar maupun yang lebih non polar bisa digunakan, disesuaikan dengan interaksi yang terbentuk antara monomer fungsional-template.

Kata Kunci: MIP, Porogen, Polaritas, Sintesis

Abdouss et al. 2012. Synthesis of molecularly imprinted polymer as a sorbent for solid phase extraction of citalopram from human serum and urine. J Mater Sci: Mater Med, vol. (23):1543–1552

Ansari, Saeedeh dan Azam Ghorbani. 2016. Molecularly imprinted polymers (mip) for selective solid phase extraction of celecoxib in urine samples followed by high performance liquid chromatography. Journal of Chemical Health Risks, vol. (7)(0).

Arabzadeh, N M. Abdouss. 2010. Synthesis and Characterization of Molecularly Imprinted Polymers for Selective Solid_Phase Extraction of Pseudoephedrine1. Colloid Journal, Vol. (4), pp. 446–455

Beyki, Tooraj; Mohammad Javad Asadollahzadeh. 2016. Selective removal of Dicamba from aqueous samples using molecularlyimprinted polymer nanospheres. J. Water Environ. Nanotechnol 1(1): 19-25.

Binsalom et al. 2016. Development of solid-phase extraction using molecularly imprinted polymer for the analysis of organophosphorus pesticides-(Chlorpyrifos) in aqueous solution. Journal of Chromatography and Separation Science, 7(6).

Chen, Jun et al. 2014. Atrazine molecular imprinted polymers: comparative analysis by far-infrared and ultraviolet induced polymerization. International Journal of Molecular Science 15:574-581.

Claude, Berengere., Cecile Viron-Lamy,b Karsten, Hauptc & Philippe Morin. 2009. Synthesis of a Molecularly Imprinted Polymer for the Solid-phase Extraction of Betulin and Betulinic Acid from Plane Bark. Phytochem. Anal. vol. (21), p. 180–185

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Javanbakht et al. 2012. Molecularly imprinted polymer based potentiometric sensor for the determination of hydroxyzine in tablets and biological fluids. Analytica chimica acta 612(1):65-74

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Mane, S. 2016. Effect of Porogens (Type and Amount) on Polymer Porosity: A Review. Canadian Chemical Transactions, vol. (4) (2), p. 210-225

Mane, S.; Ponrathnam, S.; Chavan, N. 2015. Role of interfacial tension of solvating diluents and hydrophilic-hydrophobic cross-linkers in hyper-cross-linked solid support. Ind. Eng. Chem. Res., 54, 6893–6901.

Moghaddam, Hamid Hashemi., Mahbobe, Asadian-Amiri & Siyamak, Bagheriyan. 2016. Synthesis of different types of salamthio molecularly imprinted polymers for separation and preconcentration of lead. Desalination and Water Treatment. p, 1-8

Mohajeria, Seyed Ahmad., Gholamreza, Karimib & Mehdi, Rajabnia Khansaria. 2010. Clozapine imprinted polymers: Synthesis, characterization and application for drug assay in human serum. Analytica Chimica Acta, Vol. (683) , p. 143–148

Neto et al. 2010. A Hemin-based molecularly imprinted polymer (MIP) grafted onto a glassy carbon electrode as a selective sensor for 4-Aminophenol amperometric. Elsevier sensors and Actuators B: Chemical Vol.152(2) : 220-225.

Nurhayati, T et al. 2016. Synthesis and study of guest-rebinding of mip based on MAA prepared using theophylline template. Journal of Physics: Conference Series 739:012127.

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Omidi, Fariborz et al. 2014. Application of molecular imprinted polymer nanoparticles as a selective solid phase extraction for preconcentration and trace solid phase extraction of Orghanophosphorus pesticides. Journal of Fundamental Sciences 6( 1):27-30.

Rahiminejad, M., S. J. Shahtaheri., M. R. Ganjal., Rahimi Forushani & Golbabaei. 2009. Molecularly Imprinted Solid Phase Extraction for Trace Analysis of Diazinon in Drinking Water. J. Environ. Health. Sci. Eng., Vol. (6) (2), pp. 97-106

Rao, K. V.; Haldar, R.; Kulkarni, C.; Maji, T. K.; George, S. J. 2010. Perylene based porous polyimides: tunable, high surface area with tetrahedral and pyramidal monomers. Chem. Mater, 24, 969–971.

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Seechamnanturakit, Vatcharee dan Roognapa Suedee. 2012. The synthesis and characterisation of retinol-molecularly imprinted polymers as a selective sorbent in solid-phase extraction. International Journal of Applied Science and Technology 2(7):81-93.

Song, Suquan et al. 2008. Development and application of molecularly imprinted polymers as solid-phase sorbents for Erythromycin extraction. Anal Bioanal Chem 390:2141–2150.

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Wang et al. 2017. Molecularly imprinted polymers for selective extraction of oblongifolin c from garcinia yunnanensis hu. Molecules, 22: 508.

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Zeng, Shaomei et al. 2015. Molecularly imprinted polymer for selective extraction and simultaneous determination of four tropane alkaloids from Przewalskia tangutica Maxim. fruit extracts using LC-MS/MS. Journal of Royal Society Chemistry Adv., 00:1-3.