This study aims to enhance the targeted delivery of a powerful antioxidant, ferulate (FA), by developing a controlled release formulation (CRF) based on the incorporation of layered double hydroxide and Tween-80 polymeric surfactant. The layered double hydroxide-ferulate (LDH-FA) synthesized by co-precipitation method was homogenously mixed with the Tween-80 coater under continuous stirring. The successful Tween-80 coating was verified with PXRD analysis and supported by FTIR. No changes in interlayer distance between LDH-FA (at 17.4 and 8.7 Å) and LDH-FA-T80 (at 17.6 and 8.6 Å) were observed in the PXRD pattern. TGA/DTG analysis demonstrated good thermal stability of LDH-FA-T80, with the ability to withstand extreme temperatures up to 460 °C. The association of Tween-80 with LDH-FA progressively sustained the release time of FA in each aqueous solution, with a release time of up to 440 min. For both LDH-FA and LDH-FA-T80, the release of FA is through dissolution and anion exchange release mechanism (regulated by pseudo-second-order kinetic model). The study's findings suggest practical applications of FA in the pharmaceutical industry by implying the retarding effect triggered by Tween-80, offering new insights for the application of CRF to enhance the therapeutic effect of FA.

[1] Sheikh Mohd Ghazali, S.A.I., Sarijo, S.H., and Hussein, M.Z., 2021, New synthesis of binate herbicide-interleaved anionic clay material: Synthesis, characterization and simultaneous controlled-release properties, J. Porous Mater., 28 (2), 495–505.

[2] Peralta, M.F., Mendieta, S.N., Scolari, I.R., Granero, G. E., and Crivello, M. E., 2021, Synthesis and release behavior of layered double hydroxides–carbamazepine composites, Sci. Rep., 11 (1), 20585.

[3] Rad, S., and Yazdi, E., 2021, Study of nano-dual organic-hydroxide drug delivery system for anticancer drugs, Medbiotech J., 5 (1), 22–27.

[4] Mohiuddin, I., Grover, A., Aulakh, J.S., Malik, A.K., Lee, S.S., Brown, R.J.C., and Kim, K.H., 2021, Starch-Mg/Al layered double hydroxide composites as an efficient solid phase extraction sorbent for non-steroidal anti-inflammatory drugs as environmental pollutants, J. Hazard. Mater., 401, 123782.

[5] Kura, A.U., Hussein-Al-Ali, S.H., Hussein, M.Z., and Fakurazi, S., 2014, Preparation of Tween 80-Zn/Al-levodopa-layered double hydroxides nanocomposite for drug delivery system, Sci. World J., 2014, 104246.

[6] Barkhordari, S., and Alizadeh, A., 2022, Fabrication of pH-sensitive chitosan/layered double hydroxide (LDH)/Fe₃O₄ nanocomposite hydrogel beads for controlled release of diclofenac, Polym. Bull., 79 (7), 5533–5548.

[7] Liu, Z., Lansley, A.B., Duong, T.N., Smart, J.D., and Pannala, A.S., 2022, Increasing cellular uptake and permeation of curcumin using a novel polymer-surfactant formulation, Biomolecules, 12 (12), 1739.

[8] Constantino, V.R.L., Figueiredo, M.P., Magri, V.R., Eulálio, D., Cunha, V.R.R., Alcântara, A.C.S., and Perotti, G.F., 2023, Biomaterials based on organic polymers and layered double hydroxides nanocomposites: Drug delivery and tissue engineering, Pharmaceutics, 15 (2), 413.

[9] Bozorgian, A., Aboosadi, Z.A., Mohammadi, A., Honarvar, B., and Azimi, A., 2020, Determination of CO₂ gas hydrates surface tension in the presence of non-ionic surfactants and TBAC, Rev. Roum. Chim., 65 (12), 1061–1065.

[10] Baek, S., Shin, D., Kim, G., Lee, A., Noh, J., Choi, B., Huh, S., Jeong, H., and Sung, Y., 2021, Influence of amphoteric and anionic surfactants on stability, surface tension, and thermal conductivity of Al₂O₃/water nanofluids, Case Stud. Therm. Eng., 25, 100995.

[11] Mandal, S., Banerjee, C., Ghosh, S., Kuchlyan, J., and Sarkar, N., 2013, Modulation of the photophysical properties of curcumin in non-ionic surfactant (Tween-20) forming micelles and niosomes: A comparative study of different microenvironments, J. Phys. Chem. B, 117 (23), 6957–6968.

[12] Ravichandran, V., Lee, M., Nguyen Cao, T.G., and Shim, M.S., 2021, Polysorbate-based drug formulations for brain-targeted drug delivery and anticancer therapy, Appl. Sci., 11 (19), 9336.

[13] Nilsson, E.J., Lind, T.K., Scherer, D., Skansberger, T., Mortensen, K., Engblom, J., and Kocherbitov, V., 2020, Mechanisms of crystallisation in polysorbates and sorbitan esters, CrystEngComm, 22 (22), 3840–3853.

[14] Lima, E., Flores, J., Cruz, A.S., Leyva-Gómez, G., and Krötzsch, E., 2013, Controlled release of ferulic acid from a hybrid hydrotalcite and its application as an antioxidant for human fibroblasts, Microporous Mesoporous Mater., 181, 1–7.

[15] Sousa, R., da Silva, B.J.M., Dias, A.A., Meneses, C.C.F., Bentes, B.A., Silva, E.O., Remédios, C.M.R., Feio, W.P., Masson, O., Alves, C.N., Arruda, M.M.S.P., and Lameira, J., 2019, Ferulate anion intercalated into Zn/Al layered double hydroxide: A promising intercalation compound for inhibition of Leishmania (L.) amazonensis, J. Braz. Chem. Soc., 30 (6), 1178–1188.

[16] Long, T., Wu, Q., Wei, J., Tang, Y., He, Y.N., He, C.L., Chen, X., Yu, L., Yu, C.L., Law, B.Y.K., Wu, J.M., Qin, D.L., Wu, A.G., and Zhou, X.G., 2022, Ferulic acid exerts neuroprotective effects via autophagy induction in C. elegans and cellular models of Parkinson’s disease, Oxid. Med. Cell. Longevity, 2022, 372567.

[17] Sivakumar, S., Murali, R., Arathanaikotti, D., Gopinath, A., Senthilkumar, C., Kesavan, S., and Madhan, B., 2021, Ferulic acid loaded microspheres reinforced in 3D hybrid scaffold for antimicrobial wound dressing, Int. J. Biol. Macromol., 177, 463–473.

[18] Mancuso, A., Cristiano, M.C., Pandolfo, R., Greco, M., Fresta, M., and Paolino, D., 2021, Improvement of ferulic acid antioxidant activity by multiple emulsions: In vitro and in vivo evaluation, Nanomaterials, 11 (2), 425.

[19] Hwang, H.J., Lee, S.R., Yoon, J.G., Moon, H.R., Zhang, J., Park, E., Yoon, S.I., and Cho, J.A., 2022, Ferulic acid as a protective antioxidant of human intestinal epithelial cells, Antioxidants, 11 (8), 1448.

[20] Muda, Z., Hashim, N., Isa, I., and Ali, N.M., 2016, Preparation of layered material Zn/Al-layered double hydroxide-ferulate nanocomposites, Sainmatika, 13 (2), 35–47.

[21] Javid, A., Ahmadian, S., Saboury, A.A., Kalantar, S.M., and Rezaei-Zarchi, S., 2014, Novel biodegradable heparin-coated nanocomposite system for targeted drug delivery, RSC Adv., 4 (26), 13719–13728.

[22] Sharif, S.N.M., Hashim, N., Isa, I.M., Bakar, S.A., Saidin, M.I., Ahmad, M.S., Mamat, M., Hussein, M.Z., and Zainul, R., 2021, Polymeric nanocomposite-based herbicide of carboxymethyl cellulose coated-zinc/aluminium layered double hydroxide-quinclorac: A controlled release purpose for agrochemicals, J. Polym. Environ., 29 (6), 1817–1834.

[23] Khan, Y., Durrani, S.K., Siddique, M., and Mehmood, M., 2011, Hydrothermal synthesis of alpha Fe₂O₃ nanoparticles capped by Tween-80, Mater. Lett., 65 (14), 2224–2227.

[24] Dong, L., Gou, G., and Jiao, L., 2013, Characterization of a dextran–coated layered double hydroxide acetylsalicylic acid delivery system and its pharmacokinetics in rabbit, Acta Pharm. Sin. B, 3 (6), 400–407.

[25] Castro, D.C., Cavalcante, R.P., Jorge, J., Martines, M.A.U., Oliveira, L.C.S., Casagrande, G.A., and Machulek Jr., A., 2016, Synthesis and characterization of mesoporous Nb₂O₅ and its application for photocatalytic degradation of the herbicide methylviologen, J. Braz. Chem. Soc., 27 (2), 303–313.

[26] Wei, M., Guo, J., Shi, Z., Yuan, Q., Pu, M., Rao, G., and Duan, X., 2007, Preparation and characterization of L-cystine and L-cysteine intercalated layered double hydroxides, J. Mater. Sci., 42 (8), 2684–2689.

[27] Mir, Z.M., Gomes, C., Bastos, A.C., Sampaio, R., Maia, F., Rocha, C., Tedim, J., Höche, D., Ferreira, M.G.S., and Zheludkevich, M.L., 2021, The stability and chloride entrapping capacity of ZnAl‒NO₂ LDH in high-alkaline/cementitious environment, Corros. Mater. Degrad., 2 (1), 78–99.

[28] Costa, D.G., Rocha, A.B., Souza, W.F., Chiaro, S.S.X., and Leitão, A.A., 2012, Comparative Structural, thermodynamic and electronic analyses of ZnAlAⁿ⁻ hydrotalcite-like compounds (Aⁿ⁻=Cl⁻, F⁻, Br⁻, OH⁻, CO₃²⁻ or NO₃⁻): An ab initio study, Appl. Clay Sci., 56, 16–22.

[29] Sheikh Mohd Ghazali, S.A.I., Hussein, M.Z., and Sarijo, S.H., 2013, 3,4-Dichlorophenoxyacetate interleaved into anionic clay for controlled release formulation of a new environmentally friendly agrochemical, Nanoscale Res. Lett., 8 (1), 362.

[30] Li, S., Shen, Y., Xiao, M., Liu, D., and Fan, L., 2015, Synthesis and controlled release properties of β-naphthoxyacetic acid intercalated Mg–Al layered double hydroxides nanohybrids, Arabian J. Chem., 12 (8), 2563–2571.

[31] Sarijo, S.H., Sheikh Mohd Ghazali, S.A.I., Hussein, M.Z., and Ahmad, A.H., 2015, Intercalation, physicochemical and controlled release studies of organic-inorganic–herbicide (2,4,5-tricholorphenoxy butyric acid) nanohybrid into hydrotalcite-like compounds, Mater. Today: Proc., 2 (1), 345–354.

[32] Sajid, M., Sajid Jillani, S.M., Baig, N., and Alhooshani, K., 2022, Layered double hydroxide-modified membranes for water treatment: Recent advances and prospects, Chemosphere, 287, 132140.

[33] Abniki, M., Moghimi, A., and Azizinejad, F., 2021, Synthesis of calcium-layered double hydroxide based nanohybrid for controlled release of an anti-inflammatory drug, J. Chin. Chem. Soc., 68 (2), 343–352.

[34] Kameshima, Y., Sasaki, H., Isobe, T., Nakajima, A., and Okada, K., 2009, Synthesis of composites of sodium oleate/Mg-Al-ascorbic acid-layered double hydroxides for drug delivery applications, Int. J. Pharm., 381 (1), 34–39.

[35] Hussein, M.Z., Hussein-Al-Ali, S., Zainal, Z., and Hakim, M., 2011, Development of antiproliferative nanohybrid compound with controlled release property using ellagic acid as the active agent, Int. J. Nanomedicine, 6, 1373–1383.

[36] Murtaza, G., Ahmad, M., and Shahnaz, G., 2010, Microencapsulation of diclofenac sodium by non-solvent addition technique, Trop. J. Pharm. Res., 9 (2), 187–195.

[37] Kovanda, F., Maryšková, Z., and Kovář, P., 2011, Intercalation of paracetamol into the hydrotalcite-like host, J. Solid State Chem., 184 (12), 3329–3335.

[38] Kong, X., Shi, S., Han, J., Zhu, F., Wei, M., and Duan, X., 2010, Preparation of Glycy-L-Tyrosine intercalated layered double hydroxide film and its in vitro release behavior, Chem. Eng. J., 157 (2-3), 598–604.

[39] Hashim, N., Muda, Z., Abdul Hamid, S., Md Isa, I., Kamari, A., Mohamed, A., Hussein, M.Z., and Abd Ghani, S., 2014, Characterization and controlled release formulation of agrochemical herbicides based on zinc-layered hydroxide-3-(4-methoxyphenyl) propionate nanocomposite, J. Phys. Chem. Sci., 1 (4), 1–6.

[40] Parello, M.L., Rojas, R., and Giacomelli, C.E., 2010, Dissolution kinetics and mechanism of Mg-Al layered double hydroxides: A simple approach to describe drug release in acid media, J. Colloid Interface Sci., 351 (1), 134–139.

[41] Chang, H., Li, C., Huang, R., Su, R., Qi, W., and He, Z., 2019, Amphiphilic hydrogels for biomedical applications, J. Mater. Chem. B, 7 (18), 2899–2910.

[42] Prabhakar, K., Afzal, S.M., Surender, G., and Kishan, V., 2013, Tween 80 containing lipid nanoemulsions for delivery of indinavir to brain, Acta Pharm. Sin. B, 3 (5), 345–353.