Enhanced Removal of Acetylsalicylic Acid Using Surfactant-Modified Natural Zeolites

Authors

  • Marvince John P. Araneta Laboratory of Materials, Department of Physical Sciences and Mathematics, College of Arts and Sciences, University of the Philippines Manila, Metro Manila 1000, Philippines
  • Ethan Angelo P. Gaw Laboratory of Materials, Department of Physical Sciences and Mathematics, College of Arts and Sciences, University of the Philippines Manila, Metro Manila 1000, Philippines
  • Christian Gabriel V. Seagan Department Chemistry, De La Salle University, Metro Manila 1004, Philippines
  • Mark Nathaniel E. Dolina Department Chemistry, De La Salle University, Metro Manila 1004, Philippines
  • Aldrin P. Bonto Department Chemistry, De La Salle University, Metro Manila 1004, Philippines
  • Earl Conan G. Casalme National Institute of Physics, University of the Philippines Diliman, Metro Manila 1101, Philippines
  • Arnel A. Salvador National Institute of Physics, University of the Philippines Diliman, Metro Manila 1101, Philippines
  • Julius Andrew P. Nuñez Laboratory of Materials, Department of Physical Sciences and Mathematics, College of Arts and Sciences, University of the Philippines Manila, Metro Manila 1000, Philippines

DOI:

https://doi.org/10.48048/tis.2025.8908

Keywords:

Hexadecyltrimethylammonium-bromide, Dioctadecyldimethylammonium-bromide (DODA), Philippine Natural Zeolites, Acetylsalicylic Acid, Adsorption, Hexadecyltrimethylammonium-bromide, Dioctadecyldimethylammonium-bromide, Philippine natural zeolites, Acetylsalicylic acid, Adsorption

Abstract

Widely consumed because of its analgesic properties, acetylsalicylic acid and its metabolites are considered as emerging contaminants identified in several regional water sources. Although sophisticated removal techniques such as microbial-degradation and electrochemical-membrane approaches are explored, the search for simpler adsorbent technologies remains popular. In this study, surfactant-modified natural zeolites were developed, characterized, and investigated for its adsorption performance for acetylsalicylic acid. Surfactant-modification using Hexadecyltrimethylammonium-bromide (HDTMA-Br) and Dioctadecyldimethylammonium-bromide (DODA-Br) at 100 and 200 % of the External Cation Exchange Capacity were employed. Zeolite samples were characterized for their thermal, crystallographic, morphological, and physicochemical properties. EDX data, FTIR spectra, and Zeta Potential data confirmed surfactant modification on the surface of the zeolite. XRD showed that modifications did not alter the crystallinity of the zeolites after modification. Batch adsorption experiments were carried out to examine adsorption isotherms in aqueous solutions at pH ≈ 7.5.  The linearity observed in Freundlich isotherm across all adsorbents suggests heterogenous surface adsorption sites of the base material. Bilayer-DODA-modified zeolites showed significantly promising sorption capacity for acetylsalicylic acid among all adsorbents due to anion exchange, electrostatic interaction, and hydrophobic interaction. This suggests the role of the bilayer and longer carbon chains in influencing adsorbent’s affinity towards acetylsalicylic acid.

HIGHLIGHTS

  • Successful Surfactant modification of Philippine Natural Zeolites.
  • Enhanced sorption of Acetylsalicylic Acid.
  • Exploration of One-tailed and Two-tailed cationic surfactants for monolayer and bilayer modification.

GRAPHICAL ABSTRACT

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References

TAD Beek, F Weber, A Bergmann, S Hickmann, I Ebert, A Hein and A Kuster. Pharmaceuticals in the environment--global occurrences and perspectives. Environmental Toxicology and Chemistry 2016; 35(4), 823-835.

D Smiljanic, BD Gennaro, F Izzo, A Langella, A Dakovic, C Germinario, GE Rottinghaus, M Spasojevic and M Mercurio. Removal of emerging contaminants from water by zeolite-rich composites: A first approach aiming at diclofenac and ketoprofen. Microporous and Mesoporous Materials 2020; 298, 110057.

D Smiljanic, BD Gennaro, A Dakovic, B Galzerano, C Germinario, F Izzo, GE Rottinghaus and A Langella. Removal of non-steroidal anti-inflammatory drugs from water by zeolite-rich composites: The interference of inorganic anions on the ibuprofen and naproxen adsorption. Journal of Environmental Management 2021; 286, 112168.

M Parolini. Toxicity of the non-steroidal anti-inflammatory drugs (NSAIDs) acetylsalicylic acid, paracetamol, diclofenac, ibuprofen and naproxen towards freshwater invertebrates: A Review. Science of The Total Environment 2020; 740, 140043.

K Swiacka, A Michnowska, J Maculewicz, M Caban and K Smolarz. Toxic effects of NSAIDs in non-target species: A review from the perspective of the aquatic environment. Environmental Pollution 2021; 273, 115891.

J Choi and WS Shin. Removal of salicylic and ibuprofen by hexadecyltrimethylammonium-modified montmorillonite and zeolite. Minerals 2020; 10(10), 898.

D Smiljanic, A Dakovic, M Obradovic, M Ozegovic, F Izzo, C Germinario and BD Gennaro. Application of surfactant modified natural zeolites for the removal of salicylic acid-a contaminant of emerging concern. Materials 2021; 14(24), 7728.

S Aydin, ME Aydin and A Ulvi. Monitoring the release of anti-inflammatory and analgesic pharmaceuticals in the receiving environment. Environmental Science and Pollution Research 2019; 26(36), 36887-36902.

D Smiljanic, A Dakovic, M Obradovic, M Ozegovic, M Markovic, GE Rottinghaus and BD Gennaro. Influence of the type and the amount of surfactant in phillipsite on adsorption of diclofenac sodium. Catalysts 2022; 13(1), 71.

F Izzo, M Mercurio, BD Gennaro, P Aprea, P Cappelletti, A Dakovic, C Germinario, C Grifa, D Smiljanic and A Langella. Surface modified natural zeolites (SMNZs) as nanocomposite versatile materials for health and environment. Colloids and Surfaces B: Biointerfaces 2019; 182, 110380.

BD Gennaro, P Aprea, B Liguori, B Galzerano, A Peluso and D Caputo. Zeolite-rich composite materials for environmental remediation: arsenic removal from water. Applied Sciences 2020; 10(19), 6939.

E Perez-Botella, S Valencia and F Rey. Zeolites in adsorption processes: State of the art and future prospects. Chemical Reviews 2022; 122(24), 17647-17695.

PJ Reeve and HJ Fallowfield. Natural and surfactant modified zeolites: A review of their applications for water remediation with a focus on surfactant desorption and toxicity towards microorganisms. Journal of Environmental Management 2018; 205, 253-261.

D Bhardwaj, M Sharma, P Sharma and R Tomar. Synthesis and surfactant modification of clinoptilolite and montmorillonite for the removal of nitrate and preparation of slow release nitrogen fertilizer. Journal of Hazardous Materials 2012; 227-228, 292-300.

T Lohar, A Kumbhar, A Patil, S Kamat and R Salunkhe. Synthesis and characterization of new quaternary ammonium surfactant [C18-Dabco] [Br] and its catalytic application in the synthesis of spirocarbocycles under ultrasonic condition. Research on Chemical Intermediates 2019; 45(3), 1639-1651.

R Nodehi, H Shayesteh and AR Kelishami. Enhanced adsorption of congo red using cationic surfactant functionalized zeolite particles. Microchemical Journal 2020; 153, 104281.

RE Apreutesei, C Catrinescu and C Teodosiu. Surfactant-modified natural zeolites for environmental applications in water purification. Environmental Engineering and Management Journal 2008; 7(2), 149-161.

A Torabian, H Kazemian, L Seifi, GN Bidhendi, AA Azimi and SK Ghadiri. Removal of petroleum aromatic hydrocarbons by surfactant‐modified natural zeolite: The effect of surfactant. CLEAN - Soil, Air, Water 2010; 38(1), 77-83.

M Davila-Estrada, JJ Ramirez-Garcia, MC Diaz-Nava and M Solache-Rios. Sorption of 17α-ethinylestradiol by surfactant-modified zeolite-rich tuff from aqueous solutions. Water Air & Soil Pollut 2016; 227(5), 157.

G Wang, Y Miao, Z Sun and S Zheng. Simultaneous adsorption of aflatoxin b1 and zearalenone by mono- and di-alkyl cationic surfactants modified montmorillonites. Journal of Colloid and Interface Science 2018; 511, 67-76.

SL Hailu, BU Nair, M Redi-Abshiro, I Diaz and M Tessema. Preparation and characterization of cationic surfactant modified zeolite adsorbent material for adsorption of organic and inorganic industrial pollutants. Journal of Environmental Chemical Engineering 2017; 5(4), 3319-3329.

J Shi, Z Yang, H Dai, X Lu, L Peng, X Tan, L Shi and R Fahim. Preparation and application of modified zeolites as adsorbents in wastewater treatment. Water Science & Technology 2018; 2017(3), 621-635.

H Tran, P Viet and H Chao. Surfactant modified zeolite as amphiphilic and dual-electronic adsorbent for removal of cationic and oxyanionic metal ions and organic compounds. Ecotoxicology and Environmental Safety 2018; 147, 55-63.

BD Gennaro, L Catalanotti, RS Bowman and M Mercurio. Anion exchange selectivity of surfactant modified clinoptilolite-rich tuff for environmental remediation. Journal of Colloid and Interface Science 2014; 430, 178-183.

P Cappelletti, A Colella, A Langella, M Mercurio, L Catalanotti, V Monetti and BD Gennaro. Use of surface modified natural zeolite (SMNZ) in pharmaceutical preparations part 1. mineralogical and technological characterization of some industrial zeolite-rich rocks. Microporous and Mesoporous Materials 2017; 250, 232-244.

F Izzo, A Langella, BD Gennaro, C Germinario, C Grifa, C Rispoli and M Mercurio. Chabazite from campanian ignimbrite tuff as a potential and sustainable remediation agent for the removal of emerging contaminants from water. Sustainability 2022; 14(2), 725.

W Lutz. Zeolite Y: Synthesis, modification, and properties-a case revisited. Advances in Materials Science and Engineering 2014; 2014, 724248.

RS Bowman. Applications of surfactant-modified zeolites to environmental remediation. Microporous and Mesoporous Materials 2003; 61(1-3), 43-56.

F Morante-Carballo, N Montalvan-Burbano, P Carrion-Mero and N Espinoza-Santos. Cation exchange of natural zeolites: Worldwide research. Sustainability 2021; 13(14), 7751.

V Jovanovic, V Dondur, L Damjanovic, J Zakrzewska and Tomasevic-Canovic. Improved materials for environmental application: surfactant-modified zeolites. Maaterials Science Forun 2006; 518, 223-228.

N Mirzaei, M Hadi, M Gholami, RF Fard and MS Aminabad. Sorption of acid dye by surfactant modificated natural zeolites. Journal of the Taiwan Institute of Chemical Engineers 2016; 59, 186-194.

S Beninati, D Semeraro and M Mastragostino. Adsorption of paracetamol and acetylsalicylic acid onto commercial activated carbons. Adsorption Science & Technology 2008; 26(9), 721-734.

S Wang and Y Peng. Natural zeolites as effective adsorbents in water and wastewater treatment. Chemical Engineering Journal 2010; 156(1), 11-24.

D Krajisnik, M Milojevic, A Malenovic, A Dakovic, S Ibric, S Savic, V Dondur, S Matijasevic, A Radulovic, R Daniels and J Milic. Cationic surfactants-modified natural zeolites: Improvement of the excipients functionality. Drug Development and Industrial Pharmacy 2010; 36(10), 1215-1224.

D Bhardwaj, P Sharma, M Sharma and R Tomar. Surfactant modified tectosilicates and phyllosilicates for 2,4-D removal and slow release formulation. RSC Advances 2014; 4(9), 4504-4514.

BD Gennaro, M Mercurio, P Cappelletti, L Catalanotti, A Dakovic, AD Bonis, C Grifa, F Izzo, M Krakovic, V Monetti aand A Langella. Use of surface modified natural zeolite (smnz) in pharmaceutical preparations. part 2. a new approach for a fast functionalization of zeolite-rich carriers. Microporous and Mesoporous Materials 2016; 235, 42-49.

T Bajda and Z Kłapyta. Sorption of chromate by clinoptilolite modified with alkylammonium surfactants. Mineralogia 2006; 37(2), 93-98.

E Olegario, CM Pelicano, JC Felizco and H Mendoza. Thermal stability and heavy metal (As 5+, Cu 2+, Ni 2+, Pb 2+ and Zn 2+ ) Ions uptake of the natural zeolites from the philippines. Materials Research Express 2019; 6(8), 085204.

H Aloulou, A Ghorbel, W Aloulou, RB Amar and S Khemakhem. Removal of fluoride ions (F−) from aqueous solutions using modified turkish zeolite with quaternary ammonium. Environmental Technology 2021; 42(9), 1353-1365.

R Leyva-Ramos, A Jacobo-Azuara, PE Diaz-Flores, RM Guerrero-Coronado, J Mendoza-Barron and MS Berber-Mendoza. Adsorption of chromium(VI) from an aqueous solution on a surfactant-modified zeolite. Colloids and Surfaces A: Physicochemical and Engineering Aspects 2008; 330(1), 35-41.

D Krajisnik, A Dakovic, M Milojevic, A Malenovic, M Kragovic, DB Bogdanovic, V Dondur and J Milic. Properties of diclofenac sodium sorption onto natural zeolite modified with cetylpyridinium chloride. Colloids and Surfaces B: Biointerfaces 2011; 83(1), 165-172.

H Guan, E Bestland, C Zhu, H Zhu, D Albertsdottir, J Hutson, CT Simmons, M Ginic-Markovic, X Tao and AV Ellis. Variation in performance of surfactant loading and resulting nitrate removal among four selected natural zeolites. Journal of Hazardous Materials 2010; 183(1-3), 616-621.

AJR Capistrano, RJD Labadan, JEB Viernes, EM Aragua, RN Palac and RO Arazo. Ibuprofen removal using activated carbon from acid-modified acacia sawdust. Energy Ecology Environment 2023; 8, 101-112.

MM Hussein, KM Khader and SM Musleh. Characterization of raw zeolite and surfactant-modified zeolite and their use in removal of selected organic pollutants from water. International Journal of Chemical Sciences 2014; 12(3), 815-844.

EJ Sullivan, WJ Carey and RS Bowman. Thermodynamics of cationic surfactant sorption onto natural clinoptilolite. Journal of Colloid and Interface Science 1998; 206(2), 369-380.

S Bhattacharjee. DLS and zeta potential - what they are and what they are not? Journal of Controlled Release 2016; 235, 337-351.

P Sennett and JP Oliver. Colloidal dispersion electrokinetic effects and the concept of zeta potential. Industrial & Engineering Chemistry 1965; 57(8), 32-50.

A Al-Mamoori, M Alsalbokh, S Lawson, AA Rownaghi and F Rezaei. Development of bismuth-mordenite adsorbents for iodine capture from off-gas streams. Chemical Engineering Journal 2020; 391, 123583.

FS Wanyonyi, F Orata, GK Mutua, MO Odey, S Zamisa, SE Ogbodo, F Maingi and A Pembere. Application of south african heulandite (HEU) zeolite for the adsorption and removal of Pb2+ and Cd2+ ions from aqueous water solution: experimental and computational study. Heliyon 2024; 10(14), e34657.

FK Mostafapour, M Yilmaz, AH Mahvi, A Younesi, F Ganji and D Balarak. Adsorptive removal of tetracycline from aqueous solution by surfactant-modified zeolite: Equilibrium, kinetics and thermodynamics. Desalination and Water Treatment 2022; 247, 216-228.

N Patdhanagul, T Srithanratana, K Rangsriwatananon and S Hengrasmee. Ethylene adsorption on cationic surfactant modified zeolite NaY. Microporous and Mesoporous Materials 2010; 131(1-3), 97-102.

P Hałas, D Kołodyńska, A Płaza, M Gęca and Z Hubicki. Modified fly ash and zeolites as an effective adsorbent for metal ions from aqueous solution. Adsorption Science & Technology 2017; 35(5-6), 519-533.

M Dmvila-Estrada, JJ Ramirez-Garcia, MJ Solache-Rios and JL Gallegos-Perez. Kinetic and equilibrium sorption studies of ceftriaxone and paracetamol by surfactant-modified zeolite. Water Air Soil & Pollution 2018; 229(4), 123.

N Ayawei, AN Ebelegi and D Wankasi. Modelling and interpretation of adsorption isotherms. Journal of Chemistry 2017; 2017(1), 3039817.

H Li, Z Fu, L Yang, C Yan, L Chen, J Huang and Y Liu. Synthesis and adsorption property of hydrophilic–hydrophobic macroporous crosslinked poly(methyl acryloyl diethylenetriamine)/poly(divinylbenzene) (PMADETA/PDVB) interpenetrating polymer networks (IPNs). RSC Advances 2015; 5(34), 26616-26624.

M Essandoh, B Kunwar, CU Pittman, D Mohan and T Mlsna. Sorptive removal of salicylic acid and ibuprofen from aqueous solutions using pine wood fast pyrolysis biochar. Chemical Engineering Journal 2015; 265, 219-227.

K Mphahlele, MS Onyango and SD Mhlanga. Adsorption of aspirin and paracetamol from aqueous solution using Fe/N-CNT/β-Cyclodextrin nanocomopsites synthesized via a benign microwave assisted method. Journal of Environmental Chemical Engineering 2015; 3(4), 2619-2630.

S Wong, Y Lee, N Ngadi, IM Inuwa and NB Mohamed. Synthesis of activated carbon from spent tea leaves for aspirin removal. Chinese Journal of Chemical Engineering 2018; 26(5), 1003-1011.

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Published

2024-12-20

Issue

Vol. 22 No. 2 (2025): Trends in Sciences, Volume 22, Number 2, February 2025

Section

Research Articles

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