Citations Report

Pharmaceutical Bioprocessing : Citations & Metrics Report

Articles published in Pharmaceutical Bioprocessing have been cited by esteemed scholars and scientists all around the world.

Pharmaceutical Bioprocessing has got h-index 25, which means every article in Pharmaceutical Bioprocessing has got 25 average citations.

Following are the list of articles that have cited the articles published in Pharmaceutical Bioprocessing.

• Baghban, R., Farajnia, S., Rajabibazl, M., Ghasemi, Y., Mafi, A., Hoseinpoor, R., ... & Aria, M. (2019). Yeast expression systems: overview and recent advances. Molecular biotechnology, 61(5), 365-384. View at Publisher | View at Google Scholar | View at Indexing
• Bao, J., Huang, M., Petranovic, D., & Nielsen, J. (2017). Moderate expression of SEC16 increases protein secretion by Saccharomyces cerevisiae. Applied and environmental microbiology, 83(14), e03400-16. View at Publisher | View at Google Scholar | View at Indexing
• Huang, M., Wang, G., Qin, J., Petranovic, D., & Nielsen, J. (2018). Engineering the protein secretory pathway of Saccharomyces cerevisiae enables improved protein production. Proceedings of the National Academy of Sciences, 115(47), E11025-E11032. View at Publisher | View at Google Scholar | View at Indexing
• Fidan, O., & Zhan, J. (2015). Recent advances in engineering yeast for pharmaceutical protein production. RSC advances, 5(105), 86665-86674. View at Publisher | View at Google Scholar | View at Indexing
• Pollet, J., Chen, W. H., & Strych, U. (2021). Recombinant protein vaccines, a proven approach against coronavirus pandemics. Advanced Drug Delivery Reviews. View at Publisher | View at Google Scholar | View at Indexing
• García-Ortega, X., Cámara, E., Ferrer, P., Albiol, J., Montesinos-Seguí, J. L., & Valero, F. (2019). Rational development of bioprocess engineering strategies for recombinant protein production in Pichia pastoris (Komagataella phaffii) using the methanol-free GAP promoter. Where do we stand?. New biotechnology, 53, 24-34. View at Publisher | View at Google Scholar | View at Indexing
• Martani, F., Marano, F., Bertacchi, S., Porro, D., & Branduardi, P. (2015). The Saccharomyces cerevisiae poly (A) binding protein Pab1 as a target for eliciting stress tolerant phenotypes. Scientific reports, 5(1), 1-13. View at Publisher | View at Google Scholar | View at Indexing
• Bao, J., Huang, M., Petranovic, D., & Nielsen, J. (2018). Balanced trafficking between the ER and the Golgi apparatus increases protein secretion in yeast. AMB Express, 8(1), 1-10. View at Publisher | View at Google Scholar | View at Indexing
• Martínez, J. L., Meza, E., Petranovic, D., & Nielsen, J. (2016). The impact of respiration and oxidative stress response on recombinant α-amylase production by Saccharomyces cerevisiae. Metabolic engineering communications, 3, 205-210. View at Publisher | View at Google Scholar | View at Indexing
• Nambu-Nishida, Y., Nishida, K., Hasunuma, T., & Kondo, A. (2018). Genetic and physiological basis for antibody production by Kluyveromyces marxianus. AMB Express, 8(1), 1-9. View at Publisher | View at Google Scholar | View at Indexing
• Gast, V., Campbell, K., Campos, C. P., Engqvist, M., Siewers, V., & Molin, M. (2021). The yeast eIF2 kinase Gcn2 facilitates H2O2-mediated feedback inhibition of both protein synthesis and ER oxidative folding during recombinant protein production. bioRxiv. View at Publisher | View at Google Scholar | View at Indexing
• Eche, S., & Gordon, M. L. (2021). Recombinant expression of HIV-1 protease using soluble fusion tags in Escherichia coli: A vital tool for functional characterization of HIV-1 protease. Virus Research, 198289. View at Publisher | View at Google Scholar | View at Indexing
• Pallujam, A. D., Zali, S. A., Oslan, S. N. H., Salleh, A. B., & Oslan, S. N. MALAYSIAN JOURNAL OF BIOCHEMISTRY & MOLECULAR BIOLOGY. View at Publisher | View at Google Scholar | View at Indexing
• Aza, P., Molpeceres, G., Ruiz-Dueñas, F. J., & Camarero, S. (2021). Heterologous Expression, Engineering and Characterization of a Novel Laccase of Agrocybe pediades with Promising Properties as Biocatalyst. Journal of Fungi, 7(5), 359. View at Publisher | View at Google Scholar | View at Indexing
• Tampubolon, P. M., Pambudi, S., Erlyandi, B. S. P., Sitepu, F. A., & Lestari, R. (2020, June). Incubation time optimization for the expression of recombinant CHIKV envelope protein E2 in the yeast Saccharomyces cerevisiae using SDS-PAGE. In AIP Conference Proceedings (Vol. 2242, No. 1, p. 050011). AIP Publishing LLC. View at Publisher | View at Google Scholar | View at Indexing
• Ivanova, E. (2021). Yeasts in nanotechnology-enabled oral vaccine and gene delivery. Bioengineered, 12(1), 8325-8335. View at Publisher | View at Google Scholar | View at Indexing
• Wang, Y., Li, X., Chen, X., Nielsen, J., Petranovic, D., & Siewers, V. (2021). Expression of antibody fragments in Saccharomyces cerevisiae strains evolved for enhanced protein secretion. Microbial cell factories, 20(1), 1-17. View at Publisher | View at Google Scholar | View at Indexing
• Aza, P., Molpeceres, G., De Salas, F., & Camarero, S. (2021). Design of an improved universal signal peptide based on the α-factor mating secretion signal for enzyme production in yeast. Cellular and Molecular Life Sciences, 78(7), 3691-3707. View at Publisher | View at Google Scholar | View at Indexing
• Pérez-Bernal, M., Hernández, C., & Delgado, M. (2021). ELISA validation approach for the detection of anti-Saccharomyces cerevisiae antibodies in patients treated with biopharmaceutical Heberprot-P®. J Anal Pharm Res, 10(2), 50-56. View at Publisher | View at Google Scholar | View at Indexing
• Behera, B. K., Prasad, R., & Behera, S. (2020). Management and Manufacturing Process of Biologics. In Competitive Strategies in Life Sciences (pp. 43-104). Springer, Singapore. View at Publisher | View at Google Scholar | View at Indexing
• Strittmatter, T., Egli, S., Bertschi, A., Plieninger, R., Bojar, D., Xie, M., & Fussenegger, M. (2021). Gene switch for l?glucose?induced biopharmaceutical production in mammalian cells. Biotechnology and Bioengineering, 118(6), 2220-2233. View at Publisher | View at Google Scholar | View at Indexing
• Kish, W. S., Sachi, H., Naik, A. D., Roach, M. K., Bobay, B. G., Blackburn, R. K., ... & Carbonell, R. G. (2017). Design, selection, and development of cyclic peptide ligands for human erythropoietin. Journal of Chromatography A, 1500, 105-120. View at Publisher | View at Google Scholar | View at Indexing
• Tong, H. F., Lin, D. Q., Zhang, Q. L., Wang, R. Z., & Yao, S. J. (2014). Molecular recognition of Fc?specific ligands binding onto the consensus binding site of IgG: insights from molecular simulation. Journal of Molecular Recognition, 27(8), 501-509. View at Publisher | View at Google Scholar | View at Indexing
• Wang, X., Xia, D., Han, H., Peng, K., Zhu, P., Crommen, J., ... & Jiang, Z. (2018). Biomimetic small peptide functionalized affinity monoliths for monoclonal antibody purification. Analytica chimica acta, 1017, 57-65. View at Publisher | View at Google Scholar | View at Indexing
• Bacon, K., Lavoie, A., Rao, B. M., Daniele, M., & Menegatti, S. (2020). Past, present, and future of affinity-based cell separation technologies. Acta Biomaterialia, 112, 29-51. View at Publisher | View at Google Scholar | View at Indexing
• Nascimento, A., Mullerpatan, A., Azevedo, A. M., Karande, P., & Cramer, S. (2019). Development of phage biopanning strategies to identify affinity peptide ligands for kappa light chain Fab fragments. Biotechnology progress, 35(6), e2884. View at Publisher | View at Google Scholar | View at Indexing
• ??cki, K. M., & Riske, F. J. (2020). Affinity Chromatography: An Enabling Technology for Large?Scale Bioprocessing. Biotechnology journal, 15(1), 1800397. View at Publisher | View at Google Scholar | View at Indexing
• Trasatti, J. P., Woo, J., Ladiwala, A., Cramer, S., & Karande, P. (2018). Rational design of peptide affinity ligands for the purification of therapeutic enzymes. Biotechnology progress, 34(4), 987-998. View at Publisher | View at Google Scholar | View at Indexing
• Tehrani Najafian, F., Bibi, N. S., Islam, T., & Fernández?Lahore, M. (2017). A megaporous material harbouring a peptide ligand for affinity IgG purification. Electrophoresis, 38(22-23), 2914-2921. View at Publisher | View at Google Scholar | View at Indexing
• Naik, A. D., Islam, T., Terasaka, T., Ohara, Y., Hashimoto, Y., Menegatti, S., & Carbonell, R. (2019). Silica resins and peptide ligands to develop disposable affinity adsorbents for antibody purification. Biochemical Engineering Journal, 145, 53-61. View at Publisher | View at Google Scholar | View at Indexing
• Barozzi, A., Lavoie, R. A., Day, K. N., Prodromou, R., & Menegatti, S. (2020). Affibody-Binding Ligands. International Journal of Molecular Sciences, 21(11), 3769. View at Publisher | View at Google Scholar | View at Indexing
• Chenette, H. C., Welsh, J. M., & Husson, S. M. (2017). Affinity membrane adsorbers for binding arginine-rich proteins. Separation Science and Technology, 52(2), 276-286. View at Publisher | View at Google Scholar | View at Indexing
• Day, K., Prodromou, R., Saberi Bosari, S., Lavoie, A., Omary, M., Market, C., ... & Menegatti, S. (2019). Discovery and evaluation of peptide ligands for selective adsorption and release of Cas9 nuclease on solid substrates. Bioconjugate chemistry, 30(12), 3057-3068. View at Publisher | View at Google Scholar | View at Indexing
• Chu, W., Prodromou, R., Day, K. N., Schneible, J. D., Bacon, K. B., Bowen, J. D., ... & Menegatti, S. (2021). Peptides and pseudopeptide ligands: a powerful toolbox for the affinity purification of current and next-generation biotherapeutics. Journal of Chromatography A, 1635, 461632. View at Publisher | View at Google Scholar | View at Indexing
• Bereli, N., & Denizli, A. (2016). Superior magnetic monodisperse particles for direct purification of immunoglobulin G under magnetic field. Journal of Macromolecular Science, Part A, 53(3), 160-168. View at Publisher | View at Google Scholar | View at Indexing
• Bereli, N., & Denizli, A. (2016). Superior magnetic monodisperse particles for direct purification of immunoglobulin G under magnetic field. Journal of Macromolecular Science, Part A, 53(3), 160-168. View at Publisher | View at Google Scholar | View at Indexing
• Reese, H. R., Xiao, X., Shanahan, C. C., Chu, W., Van Den Driessche, G. A., Fourches, D., ... & Menegatti, S. (2020). Novel peptide ligands for antibody purification provide superior clearance of host cell protein impurities. Journal of Chromatography A, 1625, 461237. View at Publisher | View at Google Scholar | View at Indexing
• Ishida, T., Hashimoto, T., Masaki, K., Funabashi, H., Hirota, R., Ikeda, T., ... & Kuroda, A. (2020). Application of peptides with an affinity for phospholipid membranes during the automated purification of extracellular vesicles. Scientific reports, 10(1), 1-12. View at Publisher | View at Google Scholar | View at Indexing
• Martinšek, K. (2021). Attempt to optimize peptide ligands of the Fc immunoglobulin G region (Doctoral dissertation, University of Ljubljana, Biotechnical Faculty). View at Publisher | View at Google Scholar | View at Indexing
• Ho, S. C., Koh, E. Y., Soo, B. P., Chao, S. H., & Yang, Y. (2016). Evaluating the use of a CpG free promoter for long-term recombinant protein expression stability in Chinese hamster ovary cells. BMC biotechnology, 16(1), 1-13. View at Publisher | View at Google Scholar | View at Indexing
• Merten, O. W., Bakker, W. A., Vorlop, J., Reiter, M., Visnovsky, G., Jäger, V., ... & Reichl, U. (2014). Virus production under suspension conditions. Industrial scale suspension culture of living cells, 503-554. View at Publisher | View at Google Scholar | View at Indexing
• Merten, O. W., Bakker, W. A., Vorlop, J., Reiter, M., Visnovsky, G., Jäger, V., ... & Reichl, U. (2014). Virus production under suspension conditions. Industrial scale suspension culture of living cells, 503-554. View at Publisher | View at Google Scholar | View at Indexing
• Gupta, K., Parasnis, M., Jain, R., & Dandekar, P. (2019). Vector-related stratagems for enhanced monoclonal antibody production in mammalian cells. Biotechnology advances, 37(8), 107415. View at Publisher | View at Google Scholar | View at Indexing
• Cui Ying, Bai Yu, & Cheng Suyuan. (2020). Application status and review considerations of screening markers in the construction of mammalian cell lines for recombinant protein drug production. Acta Pharmaceutica Sinica , 55 (12), 2989-2993. View at Publisher | View at Google Scholar | View at Indexing
• Prachasuphap, A., Jongpitisub, K., Saengtong, N., Treeyoung, P., Chaiya, P., & Dhepakson, P. (2020). Cloning and expression of potential human monoclonal antibodies in Catching the new corona virus 2019. BULLETIN OF THE DEPARTMENT OF MEDICAL SCIENCES , 62 (3), 155-166. View at Publisher | View at Google Scholar | View at Indexing
• Holm, P., Allesø, M., Bryder, M. C., & Holm, R. (2017). Q8 (R2) Pharmaceutical Development. ICH quality guidelines: an implementation guide, 535-577. View at Publisher | View at Google Scholar | View at Indexing
• Rathore, A. S., Singh, S. K., Kumar, J., & Kapoor, G. (2018). Implementation of QbD for Manufacturing of Biologics—Has It Met the Expectations?. In Biopharmaceutical Processing (pp. 1051-1073). Elsevier. View at Publisher | View at Google Scholar | View at Indexing
• Brown, A. (2014). Tools for Next-Generation Transcriptional Control in Chinese Hamster Ovary Cell Factories (Doctoral dissertation, University of Sheffield). View at Publisher | View at Google Scholar | View at Indexing
• Choi, G., Le, TH, & Shin, S. (2015). A new multidimensional design space identification method for a quality oriented drug development process. Proceedings of the fall academic presentation of the Korean Society for Quality Management , 2015 , 1274-1283. View at Publisher | View at Google Scholar | View at Indexing
• Abhinandana, P., & Nadendla, R. Application of Quality by Design and its Parameters for Pharmaceutical Products. View at Publisher | View at Google Scholar | View at Indexing

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