[1] G. D. Tóth, Z. Molnár, G. Koplányi, B. Gyarmati, A. Szilágyi, G. Katona, A. Menyhárd, L. Poppe, B. Pukánszky, and D. Balogh-Weiser, “How could the physical properties of poly(vinyl alcohol) influence enzymatic activity? A Detailed Study on Nanofibrous Catalysts Incorporating a Lipase from Burkholderia cepacia,” CHEMCATCHEM, vol. 17, no. 5, 2025.
[2] G. Li, W. Jankowski, J. Kujawa, B. Yalcinkaya, F. Yalcinkaya, D. Balogh-Weiser, G. Tóth, F. Ender, N. Sepsik, and W. Kujawski, “Recent advances in the preparation and applications in separation processes of electrospun nanofiber-based materials,” JOURNAL OF ENVIRONMENTAL CHEMICAL ENGINEERING, vol. 13, no. 2, 2025.
[3] B. Kenéz, G. Koplányi, B. Decsi, Z. Molnár, P. Horváth, G. Katona, G. T. Balogh, and D. Balogh-Weiser, “Development of a Novel Human Serum Albumin-Based Tool for Effective Drug Discovery: The Investigation of Protein Quality and Immobilization,” JOURNAL OF MEDICINAL CHEMISTRY, vol. 68, no. 3, pp. 2840–2848, 2025.
[4] A. Vincze, E. Simon, G. Koplányi, J. G. Stankovits, D. Balogh-Weiser, B. Gyarmati, Z. Z. Nagy, and G. T. Balogh, “Toward a high-throughput in vitro model for estimating vitreous humor permeability of topically applied drugs,” SCIENTIFIC REPORTS, vol. 15, no. 1, 2025.
[5] M. Salamah, B. Volk, I. Lekli, I. Bak, A. Gyöngyösi, G. Kozma, Z. Kónya, Á. Szalenkó-Tőkés, Á. Kiricsi, L. Rovó, D. Balogh-Weiser, I. Zupkó, I. Csóka, G. Katona, and G. T. Balogh, “Preparation, and ex vivo and in vivo Characterization of Favipiravir-Loaded Aspasomes and Niosomes for Nose-to-Brain Administration,” INTERNATIONAL JOURNAL OF NANOMEDICINE, vol. 20, pp. 6489–6514, 2025.
[6] A. Csorba, G. Katona, M. Budai-Szűcs, D. Balogh-Weiser, P. Molnár, E. Maka, A. Kazsoki, M. Vajna, R. Zelkó, Z. Z. Nagy, and G. T. Balogh, “A Comparative Pharmacokinetic Study for Cysteamine-Containing Eye Drops as an Orphan Topical Therapy in Cystinosis,” INTERNATIONAL JOURNAL OF MOLECULAR SCIENCES, vol. 25, no. 3, 2024.
[7] Z. Molnár, G. Koplányi, R. Farkas, N. Péli, B. Kenéz, B. Decsi, G. Katona, G. T. Balogh, B. G. Vértessy, and D. Balogh-Weiser, “Immobilization of human tyrosine hydroxylase onto magnetic nanoparticles – A novel formulation of a therapeutic enzyme,” INTERNATIONAL JOURNAL OF BIOLOGICAL MACROMOLECULES, vol. 268, no. 2, 2024.
[8] N. Hegyesi, D. Balogh-Weiser, and B. Pukánszky, “Covalent immobilization of an enzyme on a layered silicate to catalyze the self-degradation of PCL,” POLYMER DEGRADATION AND STABILITY, vol. 229, 2024.
[9] G. Koplányi, E. Bell, Z. Molnár, G. Katona, P. L. Neumann, F. Ender, G. T. Balogh, P. Žnidaršič-Plazl, L. Poppe, and D. Balogh-Weiser, “Novel Approach for the Isolation and Immobilization of a Recombinant Transaminase,” CHEMBIOCHEM, vol. 24, no. 7, 2023.
[10] A. O. Imarah, F. M. W. G. Silva, N. Bataa, B. Decsi, D. Balogh-Weiser, and L. Poppe, “Magnetically agitated continuous-flow tube reactors with aspartate ammonia-lyase immobilized on magnetic nanoparticles,” REACTION CHEMISTRY & ENGINEERING, vol. 8, no. 6, pp. 1250–1259, 2023.
[11] A. Csorba, G. Katona, M. Budai-Szűcs, D. Balogh-Weiser, A. M. Fadda, C. Caddeo, Á. I. Takács, P. Mátyus, G. T. Balogh, and Z. Z. Nagy, “Effect of liposomal formulation of ascorbic acid on corneal permeability,” SCIENTIFIC REPORTS, vol. 13, no. 1, 2023.
[12] A. Vincze, G. Dékány, R. Bicsak, A. Formanek, Y. Moreau, G. Koplányi, G. Takács, G. Katona, D. Balogh-Weiser, Á. Arany, and G. T. Balogh, “Natural Lipid Extracts as an Artificial Membrane for Drug Permeability Assay: In Vitro and In Silico Characterization,” PHARMACEUTICS, vol. 15, no. 3, 2023.
[13] D. Balogh-Weiser, A. Molnár, G. D. Tóth, G. Koplányi, J. Szemes, B. Decsi, G. Katona, M. Salamah, F. Ender, A. Kovács, S. Berkó, M. Budai-Szűcs, and G. T. Balogh, “Combined Nanofibrous Face Mask: Co-Formulation of Lipases and Antibiotic Agent by Electrospinning Technique,” PHARMACEUTICS, vol. 15, no. 4, 2023.
[14] G. D. Tóth, N. Kállai-Szabó, M. Lengyel, K. Süvegh, F. Ender, G. Katona, A. Kazsoki, R. Zelkó, I. Antal, G. T. Balogh, and D. Balogh-Weiser, “Nanoformulation of lipase from Porcine pancreas by electrospinning as a novel alternative for enzyme-based per os therapies,” JOURNAL OF MOLECULAR LIQUIDS, vol. 389, 2023.
[15] G. D. Tóth, G. Koplányi, B. Kenéz, and D. Balogh-Weiser, “Nanoformulation of Therapeutic Enzymes: A Short Review,” PERIODICA POLYTECHNICA-CHEMICAL ENGINEERING, vol. 67, no. 4, pp. 624–635, 2023.
[16] F. Nagy, E. Sánta-Bell, M. Jipa, G. Hornyánszky, A. Szilágyi, K. László, G. Katona, C. Paizs, L. Poppe, and D. Balogh-Weiser, “Cross-Linked Enzyme-Adhered Nanoparticles (CLEANs) for Continuous-Flow Bioproduction,” CHEMSUSCHEM, vol. 15, no. 2, 2022.
[17] P. Csuka, Z. Molnár, V. Tóth, A. O. Imarah, D. Balogh-Weiser, B. G. Vértessy, and L. Poppe, “Immobilization of the Aspartate Ammonia-Lyase from Pseudomonas fluorescens R124 on Magnetic Nanoparticles: Characterization and Kinetics,” CHEMBIOCHEM, vol. 23, no. 7, 2022.
[18] D. Balogh-Weiser, L. Poppe, B. Kenéz, B. Decsi, G. Koplányi, G. Katona, B. Gyarmati, F. Ender, and G. T. Balogh, “Novel biomimetic nanocomposite for investigation of drug metabolism,” JOURNAL OF MOLECULAR LIQUIDS, vol. 368, no. Part B, 2022.
[19] G. T. Balogh, B. Decsi, R. Krammer, B. Kenéz, F. Ender, T. Hergert, and D. Balogh-Weiser, “Effect of Binding Linkers on the Efficiency and Metabolite Profile of Biomimetic Reactions Catalyzed by Immobilized Metalloporphyrin,” METABOLITES, vol. 12, no. 12, p. 1269, 2022.
[20] A. O. Imarah, P. Csuka, N. Bataa, B. Decsi, E. Sánta-Bell, Z. Molnár, D. Balogh-Weiser, and L. Poppe, “Magnetically Agitated Nanoparticle-Based Batch Reactors for Biocatalysis with Immobilized Aspartate Ammonia-Lyase,” CATALYSTS, vol. 11, no. 4, 2021.
[21] G. D. Tóth, A. Kazsoki, B. Gyarmati, A. Szilágyi, G. Vasvári, G. Katona, L. Szente, R. Zelkó, L. Poppe, D. Balogh-Weiser, and G. T. Balogh, “Nanofibrous Formulation of Cyclodextrin Stabilized Lipases for Efficient Pancreatin Replacement Therapies,” PHARMACEUTICS, vol. 13, no. 7, 2021.
[22] K. Juhász, K. Lévay, L. Hegedűs, D. Balogh-Weiser, L. Pirault-Roy, and Z. Hell, “Application of supported lanthanum catalysts in the hydrogenation of nitriles,” REACTION KINETICS MECHANISMS AND CATALYSIS, vol. 133, no. 2, pp. 687–698, 2021.
[23] C. A. Gal, L. E. Barabas, J. H. Bartha-Vari, M. E. Moisa, D. Balogh-Weiser, L. C. Bencze, L. Poppe, C. Paizs, and M. I. Tosa, “Lipase on carbon nanotube – An active, selective, stable and easy to optimize nanobiocatalyst for kinetic resolutions,” REACTION CHEMISTRY & ENGINEERING, vol. 6, no. 12, pp. 2391–2399, 2021.
[24] G. Koplányi, E. Sánta-Bell, Z. Molnár, G. D. Tóth, M. Józó, A. Szilágyi, F. Ender, B. Pukánszky, B. G. Vértessy, L. Poppe, and D. Balogh-Weiser, “Entrapment of Phenylalanine Ammonia-Lyase in Nanofibrous Polylactic Acid Matrices by Emulsion Electrospinning,” CATALYSTS, vol. 11, no. 10, 2021.
[25] A. Kazsoki, A. Farkas, D. Balogh-Weiser, E. Mancuso, P. K. Sharma, D. A. Lamprou, and R. Zelkó, “Formulation and Complex Morphological Characterization of Core-Shell Fibrous Mats for Chronic Wound Healing,” ACTA PHARMACEUTICA HUNGARICA, vol. 91, no. 3–4, pp. 247–248, 2021.
[26] L. Nagy-Győr, E. Farkas, M. Lăcătuș, G. Tóth, D. Incze, G. Hornyánszky, V. Bódai, C. Paizs, L. Poppe, and D. Balogh-Weiser, “Conservation of the biocatalytic activity of whole yeast cells by supported sol-gel entrapment for efficient acyloin condensation,” PERIODICA POLYTECHNICA-CHEMICAL ENGINEERING, vol. 64, no. 2, pp. 153–161, 2020.
[27] A. Kazsoki, A. Farkas, D. Balogh-Weiser, E. Mancuso, P. K. Sharma, D. A. Lamprou, and R. Zelkó, “Novel combination of non-invasive morphological and solid-state characterisation of drug-loaded core-shell electrospun fibres,” INTERNATIONAL JOURNAL OF PHARMACEUTICS, vol. 587, 2020.
[28] N. Hegyesi, E. Hodosi, P. Polyak, G. Faludi, D. Balogh-Weiser, and B. Pukanszky, “Controlled degradation of poly-epsilon-caprolactone for resorbable scaffolds,” COLLOIDS AND SURFACES B: BIOINTERFACES, vol. 186, 2020.
[29] F. Nagy, I. Gyujto, G. Tasnádi, B. Barna, D. Balogh-Weiser, K. Faber, L. Poppe, and M. Hall, “Design and application of a bi-functional redox biocatalyst through covalent co-immobilization of ene-reductase and glucose dehydrogenase,” JOURNAL OF BIOTECHNOLOGY, vol. 323, pp. 246–253, 2020.
[30] B.-W. Diána, D. Balázs, K. Réka, D. Gergő, E. Ferenc, M. János, B. Róbert, G. Benjámin, S. András, T. Róbert, P. Csaba, P. László, and T. B. György, “Magnetic Nanoparticles with Dual Surface Functions—Efficient Carriers for Metalloporphyrin-Catalyzed Drug Metabolite Synthesis in Batch and Continuous-Flow Reactors,” NANOMATERIALS, vol. 10, no. 12, 2020.
[31] T. Pardy, R. Joemaa, F. Ender, T. Rang, K. Hegedus, and D. Balogh-Weiser, “Polymer Nanofiber Deposition in Lab-on-a-Chip Devices by Electrospinning,” in Proceedings of the Biennial Baltic Electronics Conference, BEC, 2020, pp. 1–4.
[32] E. Krisch, D. Balogh-Weiser, J. Klimkó, B. Gyarmati, K. László, L. Poppe, and A. Szilágyi, “Composite beads of silica gel, alginate and poly(aspartic acid) for the immobilization of enzymes,” EXPRESS POLYMER LETTERS, vol. 13, no. 6, pp. 512–523, 2019.
[33] R. Szűcs, D. Balogh-Weiser, E. Sánta-Bell, E. Tóth-Szeles, T. Varga, Z. Kónya, L. Poppe, and I. Lagzi, “Green synthesis and in-situ immobilization of gold nanoparticles and their application for the reduction of p-nitrophenol in continuous-flow mode,” RSC ADVANCES, vol. 9, no. 16, pp. 9193–9197, 2019.
[34] N. Flóra, G. Imre, T. Gábor, B. Bence, B.-W. Diana, H. Mélanie, F. Kurt, and P. László, “Covalent co-immobilization of ene-reductases with glucose dehydrogenase and their application in asymmetric bioreduction,” in BIOTRANS 14th International symposium on Biocatalysis and Biotransformations, 2019, pp. 366–366.
[35] B. Decsi, R. Krammer, K. Hegedűs, F. Ender, B. Gyarmati, A. Szilágyi, R. Tőtős, G. Katona, C. Paizs, G. T. Balogh, L. Poppe, and D. Balogh-Weiser, “Liver-on-a-Chip‒Magnetic nanoparticle bound synthetic metalloporphyrin-catalyzed biomimetic oxidation of a drug in a magnechip reactor,” MICROMACHINES, vol. 10, no. 10, 2019.
[36] E. Sánta-Bell, Z. Molnár, A. Varga, F. Nagy, G. Hornyánszky, C. Paizs, D. Balogh-Weiser, and L. Poppe, “‘Fishing and hunting’– Selective immobilization of a recombinant phenylalanine ammonia-lyase from fermentation media,” MOLECULES, vol. 24, no. 22, 2019.
[37] L. Nagy-Győr, M. A. Lacatus, D. Balogh-Weiser, P. Csuka, V. Bódai, B. Erdélyi, Z. Molnár, G. Hornyanszky, C. Paizs, and L. Poppe, “How to Turn Yeast Cells into a Sustainable and Switchable Biocatalyst? On-Demand Catalysis of Ketone Bioreduction or Acyloin Condensation,” ACS SUSTAINABLE CHEMISTRY & ENGINEERING, vol. 7, no. 24, pp. 19375–19383, 2019.
[38] A. Vincze, D. Balogh-Weiser, B. Gyarmati, and A. Szilágyi, “Rifampicin poliaszpartamid nanoszálas formulájának előállítása szemészeti alkalmazásra.” 2019.
[39] D. Balogh-Weiser, C. Németh, F. Ender, B. Gyarmati, A. Szilágyi, and L. Poppe, “Electrospun nanofibers for entrapment of biomolecules,” in Electrospinning Method Used to Create Functional Nanocomposites Films, 2018, pp. 135–147.
[40] F. Nagy, G. Tasnádi, D. Balogh Weiser, E. Bell, M. Hall, K. Faber, and L. Poppe, “Smart nanoparticles for selective immobilization of acid phosphatases,” CHEMCATCHEM, vol. 10, no. 16, pp. 3490–3499, 2018.
[41] F. Tamás, I. Gergő, D. Balázs, B. Zoltán, I. T. György, K. József, B.-W. Diána, G. István, H. Péter, and T. B. György, “Biomimetic synthesis of drug metabolites in batch and continuous‐flow reactors,” CHEMISTRY-A EUROPEAN JOURNAL, vol. 24, no. 37, pp. 9385–9392, 2018.
[42] D. Balogh-Weiser, “Enzimrögzítési módszerek nanostrukturált rendszerekben,” MAGYAR KÉMIAI FOLYÓIRAT – KÉMIAI KÖZLEMÉNYEK (1997-), vol. 124, no. 1–2, pp. 49–55, 2018.
[43] N. Adányi, Á. G. Nagy, B. Takács, I. Szendrő, G. Szakacs, R. Szűcs, E. Tóth-Szeles, I. Lagzi, D. Weiser, V. Bódai, P. Sátorhelyi, and B. Erdélyi, “Sensitivity enhancement for mycotoxin determination by optical waveguide lightmode spectroscopy using gold nanoparticles of different size and origin,” FOOD CHEMISTRY, vol. 267, pp. 10–14, 2018.
[44] L. Nagy-Győr, E. Abaházi, V. Bódai, P. Sátorhelyi, B. Erdélyi, D. Balogh-Weiser, C. Paizs, G. Hornyánszky, and L. Poppe, “Co-immobilized whole-cells with ω-transaminase and ketoreductase activity for continuous-flow cascade reaction,” CHEMBIOCHEM, vol. 19, no. 17, pp. 1845–1848, 2018.
[45] A. Kazsoki, P. Szabó, A. Domján, A. Balázs, T. Bozó, M. Kellermayer, A. Farkas, D. Balogh-Weiser, B. Pinke, A. Darcsi, S. Béni, J. Madarász, L. Szente, and R. Zelkó, “Microstructural distinction of electrospun nanofibrous drug delivery systems formulated with different excipients,” MOLECULAR PHARMACEUTICS, vol. 15, no. 9, pp. 4214–4225, 2018.
[46] N. Hegyesi, K. Hodosi, P. Polyak, D. Balogh-Weiser, and B. Pukanszky, “Halloysite support for an enzyme and its use for the controlled enzymatic degradation of PCL,” BASIC & CLINICAL PHARMACOLOGY & TOXICOLOGY, vol. 124, pp. 3–3, 2018.
[47] F. Nagy, A. Szilágyi, G. T. Balogh, D. Balogh-Weiser, and L. Poppe, Cross-linked enzyme-adhered nanoparticles and their applications. 2018.
[48] D. Weiser, Z. Boros, J. Nagy, G. Hornyánszky, E. Bell, P. Sátorhelyi, and L. Poppe, “SynBiocat: Protein Purification, Immobilization and Continuous-flow Processes,” in Biocatalysis: An Industrial Perspective, 2018, pp. 397–430.
[49] F. Ender, D. Weiser, A. Vitéz, G. Sallai, M. Németh, and L. Poppe, “In-situ measurement of magnetic nanoparticle quantity in a microfluidic device,” MICROSYSTEM TECHNOLOGIES, vol. 23, no. 9, pp. 3979–3990, 2017.
[50] D. Weiser, F. Nagy, G. Bánóczi, M. Oláh, A. Farkas, A. Szilágyi, K. László, Á. Gellért, G. Marosi, S. Kemény, and L. Poppe, “Immobilization engineering – How to design advanced sol-gel systems for biocatalysis?,” GREEN CHEMISTRY, vol. 19, no. 16, pp. 3927–3937, 2017.
[51] Á. György Nagy, I. Szendrő, G. Szakacs, R. Szűcs, E. Tóth-Szeles, I. Lagzi, P. Sátorhelyi, D. Weiser, B. Erdélyi, and N. Adányi, “Comparative study on the effect of bio-gold nanoparticles for sensor senzitization by using OWLS and QCM-I detection,” in XIXth EuroFoodChem Conference, 2017, p. 195.
[52] F. Ender, W. Diána, B. Nagy, L. C. Bencze, C. Paizs, P. Pálovics, and L. Poppe, “Microfluidic multiple cell chip reactor filled with enzyme-coated magnetic nanoparticles,” JOURNAL OF FLOW CHEMISTRY, vol. 6, no. 1, pp. 43–52, 2016.
[53] P. L. Sóti, D. Weiser, T. Vigh, Z. K. Nagy, L. Poppe, and G. Marosi, “Electrospun polylactic acid and polyvinyl alcohol fibers as efficient and stable nanomaterials for immobilization of lipases,” BIOPROCESS AND BIOSYSTEMS ENGINEERING, vol. 39, no. 3, pp. 449–459, 2016.
[54] P. Falus, L. Cerioli, G. Bajnóczi, Z. Boros, D. Weiser, J. Nagy, D. Tessaro, S. Servi, and L. Poppe, “A Continuous-Flow Cascade Reactor System for Subtilisin A-Catalyzed Dynamic Kinetic Resolution of N-tert-Butyloxycarbonylphenylalanine Ethyl Thioester with Benzylamine,” ADVANCED SYNTHESIS & CATALYSIS, vol. 358, no. 10, pp. 1608–1617, 2016.
[55] F. Ender, D. Weiser, and L. Poppe, “Microfluidic multiple cell chip reactor filled with enzyme-coated magnetic nanoparticles,” in Lab-on-a-Chip Fabrication and Application, 2016, pp. 157–178.
[56] D. Weiser, P. L. Sóti, G. Bánóczi, V. Bódai, B. Kiss, Á. Gellért, Z. K. Nagy, B. Koczka, A. Szilágyi, G. Marosi, and L. Poppe, “Bioimprinted lipases in PVA nanofibers as efficient immobilized biocatalysts,” TETRAHEDRON, vol. 72, no. 46, pp. 7335–7342, 2016.
[57] S. Gihaz, D. Weiser, A. Dror, P. Sátorhelyi, M. Jerabek-Willemsen, L. Poppe, and A. Fishman, “Creating an efficient methanol-stable biocatalyst by protein and immobilization engineering–steps towards efficient biosynthesis of biodiesel,” CHEMSUSCHEM, vol. 9, no. 22, pp. 3161–3170, 2016.
[58] K. E, K. J, W. D, P. L, and S. A, “Lipase immobilization in novel poly(aspartic acid)-alginate polymer matrix,” in 3rd International Conference on Bio-based Polymers and Composites, 2016.
[59] D. Weiser, “Enzimrögzítési módszerek nanostrukturált rendszerekben,” Budapesti Műszaki és Gazdaságtudományi Egyetem, 2016.
[60] J. H. Bartha-Vári, M. I. Toşa, F.-D. Irimie, D. Weiser, Z. Boros, B. G. Vértessy, C. Paizs, and L. Poppe, “Immobilization of Phenylalanine Ammonia‐Lyase on Single‐Walled Carbon Nanotubes for Stereoselective Biotransformations in Batch and Continuous‐Flow Modes,” CHEMCATCHEM, vol. 7, no. 7, pp. 1122–1128, 2015.
[61] D. Weiser, L. C. Bencze, G. Bánóczi, F. Ender, R. Kiss, E. Kókai, A. Szilágyi, B. G. Vértessy, Ö. Farkas, C. Paizs, and L. Poppe, “Phenylalanine ammonia-lyase catalyzed deamination of an acyclic amino acid – Enzyme mechanistic studies aided by a novel microreactor filled with magnetic nanoparticles,” CHEMBIOCHEM, vol. 16, no. 16, pp. 2283–2288, 2015.
[62] F. Ender, A. Vitez, G. Sallai, D. Weiser, and M. Nemeth, “In-situ measurement of nanoparticle quantity in microchambers,” in Proceedings of the Symposium on Design, Test, Integration and Packaging of MEMS/MOEMS (DTIP’15), 2015.
[63] D. Weiser, A. Varga, K. Kovács, F. Nagy, A. Szilágyi, B. G. Vértessy, C. Paizs, and L. Poppe, “Bisepoxide cross-linked enzyme aggregates – New immobilized biocatalysts for selective biotransformations,” CHEMCATCHEM, vol. 6, no. 5, pp. 1463–1469, 2014.
[64] F. Ender, H. Gusztáv, V. András, and W. Diána, “In-situ Thermal Conductivity Measurement of Magnetic Nanoparticle Layers in Lab-on-a-Chip Devices,” in 20th International Workshop on THERMal INvestigation of ICs and Systems (THERMINIC’14), 2014.
[65] Z. Boros, E. Abaháziová, D. Weiser, P. Kovács, A. Varga, V. Zaharia, and L. Poppe, “Surface modification of silica gels for selective adsorption of bacterial lipases,” STUDIA UNIVERSITATIS BABES-BOLYAI CHEMIA, vol. 59, no. 3, pp. 33–38, 2014.
[66] Z. Boros, D. Weiser, M. Márkus, E. Abaháziová, Á. Magyar, A. Tomin, B. Koczka, P. Kovács, and L. Poppe, “Hydrophobic adsorption and covalent immobilization of Candida antarctica lipase B on mixed-function-grafted silica gel supports for continuous-flow biotransformations,” PROCESS BIOCHEMISTRY, vol. 48, no. 7, pp. 1039–1047, 2013.
[67] Z. Boros, P. Falus, M. Márkus, D. Weiser, M. Oláh, G. Hornyánszky, J. Nagy, and L. Poppe, “How the mode of Candida antarctica lipase B immobilization effects the continuous-flow kinetic resolution of racemic amines at various temperatures,” JOURNAL OF MOLECULAR CATALYSIS B-ENZYMATIC, vol. 85–86, pp. 119–125, 2013.
[68] W. D, K. K, E. F, V. BG, and P. L, “Enzyme coated sol-gel nanoparticles for use in continuous flow microfluidical devices,” in Enzyme coated sol-gel nanoparticles for use in continuous flow microfluidical devices, 2013.
[69] D. Weiser, Z. Boros, G. Hornyánszky, A. Tóth, and L. Poppe, “Disubstituted dialkoxysilane precursors in binary and ternary sol-gel systems for lipase immobilization,” PROCESS BIOCHEMISTRY, vol. 47, pp. 428–434, 2012.
[70] D. Weiser, K. Kovács, Z. Boros, G. B. Vértessy, and L. Poppe, “Novel immobilized phenylalanine ammonia-lyase biocatalysts,” in 6th International Congress on Biocatalysis, Biocat2012, 2012, pp. 89–89.
[71] M. Ősze, D. Weiser, G. Hornyánszky, and L. Poppe, “Multi-substrate kinetic resolution screening method for lipase biocatalysts,” STUDIA UNIVERSITATIS BABES-BOLYAI CHEMIA, vol. 57, no. 2, pp. 129–137, 2012.
[72] A. Tomin, D. Weiser, G. Hellner, Z. Bata, L. Corici, F. Péter, B. Koczka, and L. Poppe, “Fine tuning the second generation sol-gel lipase immobilization with ternary alkoxysilane precursor systems,” PROCESS BIOCHEMISTRY, vol. 46, pp. 52–58, 2011.
[73] D. Weiser, A. Tomin, and L. Poppe, “Novel solid supports for lipases in sol-gel immobilization systems,” STUDIA UNIVERSITATIS BABES-BOLYAI CHEMIA, vol. 55, no. 4, pp. 283–288, 2010.
[74] A. Tomin, D. Weiser, Z. Bata, L. Corici, F. Péter, and L. Poppe, “Entrapment of lipases in novel sol-gel systems,” STUDIA UNIVERSITATIS BABES-BOLYAI CHEMIA, vol. 54, no. Sp. 2, pp. 77–82, 2009.