Polyvinylidene fluoride (PVDF) membrane and its derivative have been investigated the permeation ability for creatinine and urea. The membrane was made by an inversion precipitation system in N,N-dimethyl acetamide (DMAc) and water as non-solvents. In this study, the modification of PVDF membrane permeability with PEG additives, CBT variations, and sulfonation was successfully carried out. The membrane solidification process was carried out on three variations of the coagulation bath temperature (CBT): 30, 45, and 60 °C. Eight types of membranes were characterized by using FT-IR and TGA/DSC, followed by the analysis of their porosity, hydrophilicity, water uptake, swelling degree, tensile strength, and permeability of creatinine and urea. The FT-IR spectra indicate that PVDF modification has been successfully carried out. The porosity, hydrophilicity, water uptake, and swelling degree values increase with the modification of functional groups. Furthermore, improvements in creatinine and urea permeability and clearances are achieved by increasing CBT and sulfonation in the PVDF/PEG membrane. The presence of sulfonate groups improves the membrane permeability through the interaction of intermolecular hydrogen with water and dialysate compounds. The existence of PEG as a porogen enhanced membrane porosity. Creatinine and urea clearance values increase from 0.29–0.58 and 6.38–20.63 mg/dL, respectively.

[1] Siahaan, P., Sasongko, N.A., Lusiana, R.A., Prasasty, V.D., and Martoprawiro, M.A., 2021, The Validation of molecular interaction among dimer chitosan with urea and creatinine using density functional theory: In application for hemodialysis membrane, Int. J. Biol. Macromol., 168, 339–349.

[2] Lusiana, R.A., Sangkota, V.D.A., Sasongko, N.A., Gunawan, G., Wijaya, A.R., Santosa, S.J., Siswanta, D., Mudasir, M., Abidin, M.N.Z., Mansur, S., and Othman, M.H.D., 2020, Permeability improvement of polyethersulfone-polyethylene glycol (PEG-PES) flat sheet type membranes by tripolyphosphate-crosslinked chitosan (TPP-CS) coating, Int. J. Biol. Macromol., 152, 633–644.

[3] Afsarian, Z., and Mansourpanah, Y., 2018, Surface and pore modification of tripolyphosphate-crosslinked chitosan/polyethersulfone composite nanofiltration membrane; Characterization and performance evaluation, Korean J. Chem. Eng., 35 (9), 1867–1877.

[4] Kaleekkal, N.J., Thanigaivelan, A., Tarun, M., and Mohan, D., 2015, A functional PES membrane for hemodialysis – Preparation, characterization and biocompatibility, Chin. J. Chem. Eng., 23 (7), 1236–1244.

[5] Matsuda, M., Yamamoto, K., Yakushiji, T., Fukuda, M., Miyasaka, T., and Sakai, K., 2008, Nanotechnological evaluation of protein adsorption on dialysis membrane surface hydrophilized with polyvinylpyrrolidone, J. Membr. Sci., 310 (1), 219–228.

[6] Zhao, X., and Liu, C., 2016, Irreversible fouling control of PVDF ultrafiltration membrane with “fouled surface” for mimetic sewage treatment, RSC Adv., 6 (96), 94184–94192.

[7] Zhang, Q., Lu, X., dan Zhao, L., 2014, Preparation of polyvinylidene fluoride (PVDF) hollow fiber hemodialysis membranes, Membranes, 4 (1), 81–95.

[8] Wang, X., Zhang, L., Sun, D., An, Q., and Chen, H., 2008, Effect of coagulation bath temperature on formation mechanism of poly(vinylidene fluoride) membrane, J. Apply. Polym. Sci., 110 (3), 1656–1663.

[9] hang, H., Lu, X., Liu, Z., Ma, Z., Wu, S., Li, Z., Kong, X., Liu, J., and Wu, C., 2018, The unidirectional regulatory role of coagulation bath temperature on cross-section radius of the PVDF hollow-fiber membrane, J. Membr. Sci., 550, 9–17.

[10] Fadaei, A., Salimi, A., and Mirzataheri, M, 2014, Structural elucidation of morphology and performance of the PVDF/PEG membrane, J. Polym. Res., 21 (9), 545.

[11] Farrokhzad, H., Kikhavani, T., Monnaie, F., Ashrafizadeh, S.N., Koeckelberghs, G., Van Gerven, T., and Van der Bruggen, B., 2015, Novel composite cation exchange fi lms based on sulfonated PVDF for electromembrane separations, J. Membr. Sci., 474, 167–174.

[12] Nishiyama, T., Sumihara, T., Sato, E., and Horibe, H., 2017, Effect of solvents on the crystal formation of poly (vinylidene fluoride) film prepared by a spin-coating process, Polym. J., 49 (3), 319–325.

[13] Roy, K.J., Anjali, T.V., and Sujith, A., 2017, Asymmetric membranes based on poly(vinyl chloride): Effect of molecular weight of additive and solvent power on the morphology and performance, J. Mater. Sci., 52 (10), 5708–5725.

[14] Nikooe, N., and Saljoughi, E., 2017, Preparation and characterization of novel PVDF nanofiltration membranes with hydrophilic property for filtration of dye aqueous solution, Appl. Surf. Sci., 413, 41–49.

[15] de Jesus Silva, A.J., Contreras, M.M., Nascimento, C.R., and da Costa, M.F., 2020, Kinetics of thermal degradation and lifetime study of poly(vinylidene fluoride) (PVDF) subjected to bioethanol fuel accelerated aging, Heliyon, 6 (7), e04573.

[16] Hu, Y., Yan, L., and Yue, B, 2020, Sulfonation mechanism of polysulfone in concentrated sulfuric acid for proton exchange membrane fuel cell applications, ACS Omega, 5 (22), 13219–13223

[17] Saljoughi, Amirilargani, M., and Mohammadi, T., 2010, Effect of PEG additive and coagulation bath temperature on the morphology, permeability and thermal/chemical stability of asymmetric CA membranes, Desalination, 262 (1) 72–78.

[18] Nasirian, D., Salahshoori, I., Sadeghi, M., Rashidi, N., and Hassanzadeganroudsari, M., 2019, Investigation of the gas permeability properties from polysulfone/polyethylene glycol composite membrane, Polym. Bull., 77 (10), 5529–5552.

[19] Mansur, S., Othman, M.H.D., Ismail, A.F., Sheikh Abdul Kadir, S.H., Goh, P.S., Hasbullah, H., Ng, B.C., Abdullah, M.S., Kamal, F., Abidin, M.N.Z., and Lusiana, R.A., 2019, Synthesis and characterisation of composite sulphonated polyurethane/polyethersulphone membrane for blood purification application, Mater. Sci. Eng., C, 99, 491–504.

[20] Boubakri, A., Bouchrit, R., Hafiane, A., and Bouguecha, S.A.T., 2015, Fluoride removal from aqueous solution by direct contact membrane distillation: Theoretical and experimental, Environ. Sci. Pollut. Res., 21 (17), 10493–10501.

[21] Syawaliah, Arahman, N., Mukramah, and Mulyati, S., 2017, Effects of PEG molecular weights on PVDF membrane for humic acid-fed ultrafiltration process, IOP Conf. Ser.: Mater. Sci. Eng., 180, 012129.

[22] Amirilargani, M., Saljoughi, E., Mohammadi, T., and Moghbeli, M.R., 2010, Effects of coagulation bath temperature and polyvinylpyrrolidone content on flat sheet asymmetric polyethersulfone membranes, Polym. Eng. Sci., 50 (5), 885–893.

[23] Lusiana, R.A., Sasongko, N.A., Sangkota, V.D.A., Prasetya, N.B.A., Siahaan, P., Kiswandono A.A., and Othman, M.H.D, In-Vitro study of polysulfone-polyethylene glycol/chitosan (PES-PSf/Cs) membrane for urea and creatinine permeation, J. Kim. Sains Apl., 23 (8), 283–289.

[24] Marino, T., Russo, F., and Figoli, A., 2018, The formation of polyvinylidene fluoride membranes with tailored properties via vapour/non-solvent induced phase separation, Membranes, 8 (3), 71.

[25] Hołda, A.K., and Vankelecom, I.F.J., 2015, Understanding and guiding the phase inversion process for synthesis of solvent resistant nanofiltration membranes, J. Appl. Polym. Sci., 132 (27), 42130.

[26] Amiji, M.M., 1995, Permeability and blood compatibility properties of chitosan-poly(ethylene oxide) blend membranes for haemodialysis, Biomaterials, 16 (8), 593–599.

[27] Amin, N., Mahmood, R., Asad, M.J., Zafar, M., and Raja, A.M., 2014, Evaluating urea and creatinine levels in chronic renal failure pre and post dialysis, J. Cardiovasc. Dis., 2 (2), 182–185.