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.
2021 | 2020 | 2019 | 2018 | 2017 | 2016 | |
---|---|---|---|---|---|---|
Year wise published articles |
31 | 7 | 5 | 23 | 10 | 17 |
Year wise citations received |
271 | 188 | 163 | 177 | 175 | 146 |
Journal total citations count | 1649 |
Journal impact factor | 9.31372549 |
Journal 5 years impact factor | 11.9418604 |
Journal cite score | 13.3492063 |
Journal h-index | 25 |
Journal h-index since 2018 | 20 |
Journal Impact Factor 2020 formula |
IF= Citations(y)/{Publications(y-1)+ Publications(y-2)} Y= Year |
Journal 5-year Impact Factor 2020 formula |
Citations(2016 + 2017 + 2018 + 2019 + 2020)/ {Published articles(2016 + 2017 + 2018 + 2019 + 2020)} |
Journal citescore |
Citescorey = Citationsy + Citationsy-1 + Citationsy-2 + Citations y-3 / Published articlesy + Published articlesy-1 + Published articlesy-2 + Published articles y-3 |
- Wessner, M., Meier, M., Bommarius, B., Bommarius, A. S., & Brandenbusch, C. (2021). Intensifying aqueous two-phase extraction by adding decisive excipients for enhancement of stability and solubility of biomolecules. Chemical Engineering and Processing-Process Intensification, 167, 108534. View at Publisher | View at Google Scholar | View at Indexing
- Schneider, A., Herlevi, L. M., Guo, Y., & Fernandez Lahore, H. M. (2021). Perspectives on adsorption technology as an effective strategy for continuous downstream bioprocessing. Journal of Chemical Technology & Biotechnology. View at Publisher | View at Google Scholar | View at Indexing
- Yelemane, V., Kangwa, M., Dsouza, R. N., & Fernández-Lahore, H. M. (2020). Convenient Screening of Antifouling Agents for Direct Recovery of Bioproducts Employing a Fast Microplate Assay. View at Publisher | View at Google Scholar | View at Indexing
- Mejía-Manzano, L. A., Vázquez-Villegas, P., & González-Valdez, J. (2020). Perspectives, Tendencies, and Guidelines in Affinity-Based Strategies for the Recovery and Purification of PEGylated Proteins. Advances in Polymer Technology, 2020. View at Publisher | View at Google Scholar | View at Indexing
- Mandal, I. (2016). Microcapillary membranes for purification of biomolecules (Doctoral dissertation, University of Cambridge). View at Publisher | View at Google Scholar | View at Indexing
- Mandal, I. (2016). Microcapillary membranes for purification of biomolecules (Doctoral dissertation, University of Cambridge). View at Publisher | View at Google Scholar | View at Indexing
- Salas?Villalobos, U. A., Gómez?Acata, R. V., Castillo?Reyna, J., & Aguilar, O. (2021). In?situ product recovery as a strategy for bioprocess integration and depletion of inhibitory products. Journal of Chemical Technology & Biotechnology. View at Publisher | View at Google Scholar | View at Indexing
- Khan, S., Ullah, M. W., Siddique, R., Nabi, G., Manan, S., Yousaf, M., & Hou, H. (2016). Role of recombinant DNA technology to improve life. International journal of genomics, 2016. View at Publisher | View at Google Scholar | View at Indexing
- Kwang, T. W., Zeng, X., & Wang, S. (2016). Manufacturing of AcMNPV baculovirus vectors to enable gene therapy trials. Molecular Therapy-Methods & Clinical Development, 3, 15050. View at Publisher | View at Google Scholar | View at Indexing
- Sharon, D., & Kamen, A. (2018). Advancements in the design and scalable production of viral gene transfer vectors. Biotechnology and bioengineering, 115(1), 25-40. View at Publisher | View at Google Scholar | View at Indexing
- Moleirinho, M. G., Silva, R. J., Alves, P. M., Carrondo, M. J., & Peixoto, C. (2020). Current challenges in biotherapeutic particles manufacturing. Expert opinion on biological therapy, 20(5), 451-465. View at Publisher | View at Google Scholar | View at Indexing
- Fuenmayor, J., Cervera, L., Gòdia, F., & Kamen, A. (2019). Extended gene expression for Gag VLP production achieved at bioreactor scale. Journal of Chemical Technology & Biotechnology, 94(1), 302-308. View at Publisher | View at Google Scholar | View at Indexing
- Bilsland, A. E., Spiliopoulou, P., & Evans, T. J. (2016). Virotherapy: cancer gene therapy at last?. F1000Research, 5. View at Publisher | View at Google Scholar | View at Indexing
- Maunder, H. E., Wright, J., Kolli, B. R., Vieira, C. R., Mkandawire, T. T., Tatoris, S., ... & Farley, D. C. (2017). Enhancing titres of therapeutic viral vectors using the transgene repression in vector production (TRiP) system. Nature communications, 8(1), 1-13. View at Publisher | View at Google Scholar | View at Indexing
- Sprick, G., Weidner, T., Salzig, D., & Czermak, P. (2017). Baculovirus-induced recombinant protein expression in human mesenchymal stromal stem cells: a promoter study. New biotechnology, 39, 161-166. View at Publisher | View at Google Scholar | View at Indexing
- Smith, J., Grieger, J., & Samulski, J. (2018). Overcoming bottlenecks in AAV manufacturing for gene therapy. Cell Gene Ther. Insights, 4, 815-827. View at Publisher | View at Google Scholar | View at Indexing
- Smith, J., Grieger, J., & Samulski, J. (2018). Overcoming bottlenecks in AAV manufacturing for gene therapy. Cell Gene Ther. Insights, 4, 815-827. View at Publisher | View at Google Scholar | View at Indexing
- Comisel, R. M., Kara, B., Fiesser, F. H., & Farid, S. S. (2021). Lentiviral vector bioprocess economics for cell and gene therapy commercialization. Biochemical Engineering Journal, 167, 107868. View at Publisher | View at Google Scholar | View at Indexing
- Ramirez, J. C. (2018). Lentiviral Vectors Come of Age? Hurdles and Challenges in Scaling Up Manufacture. In Systems Biology. IntechOpen. View at Publisher | View at Google Scholar | View at Indexing
- Galligan, C., Nguyen, C., Nelson, J., Spooner, P., Miller, T., Davis, B. M., ... & Puleo, C. M. (2018). High-Capacity Redox Polymer Electrodes: Applications in Molecular and Cellular Processing. SLAS TECHNOLOGY: Translating Life Sciences Innovation, 23(4), 374-386. View at Publisher | View at Google Scholar | View at Indexing
- Merten, O. W. (2017). Present situation of viral vector manufacturing and ways to overcome potential barriers in view of the routine large scale production and use of viral vectors. Current Trends in Biomedical Engineering & Biosciences, 7(1), 13-20. View at Publisher | View at Google Scholar | View at Indexing
- Labisch, J. J., Bollmann, F., Wolff, M. W., & Pflanz, K. (2021). A new simplified clarification approach for lentiviral vectors using diatomaceous earth improves throughput and safe handling. Journal of Biotechnology, 326, 11-20. View at Publisher | View at Google Scholar | View at Indexing
- Comisel, R. M., Kara, B., Fiesser, F. H., & Farid, S. S. (2021). Gene therapy process change evaluation framework: Transient transfection and stable producer cell line comparison. Biochemical Engineering Journal, 176, 108202. View at Publisher | View at Google Scholar | View at Indexing
- Farley, D. VIRUS TO VECTOR. View at Publisher | View at Google Scholar | View at Indexing
- Moreira, A. S., Silva, A. C., Sousa, M. F., Hagner?McWhirterc, Å., Ahlénc, G., Lundgren, M., ... & Carrondo, M. J. (2020). Establishing Suspension Cell Cultures for Improved Manufacturing of Oncolytic Adenovirus. Biotechnology journal, 15(4), 1900411. View at Publisher | View at Google Scholar | View at Indexing
- Moreira, A. S., Silva, A. C., Sousa, M. F., Hagner?McWhirterc, Å., Ahlénc, G., Lundgren, M., ... & Carrondo, M. J. (2020). Establishing Suspension Cell Cultures for Improved Manufacturing of Oncolytic Adenovirus. Biotechnology journal, 15(4), 1900411. View at Publisher | View at Google Scholar | View at Indexing
- Farley, D. Standardizing viral vector manufacture: maximizing production with the TRiP SystemTM. View at Publisher | View at Google Scholar | View at Indexing
- Feast, S., Fee, C., Huber, T., & Clarke, D. (2021). Printed monolith adsorption as an alternative to expanded bed adsorption for purifying M13 bacteriophage. Journal of Chromatography A, 1652, 462365. View at Publisher | View at Google Scholar | View at Indexing
- Feast, S., Fee, C., Huber, T., & Clarke, D. (2021). Printed monolith adsorption as an alternative to expanded bed adsorption for purifying M13 bacteriophage. Journal of Chromatography A, 1652, 462365. View at Publisher | View at Google Scholar | View at Indexing
- Sha, S., Agarabi, C., Brorson, K., Lee, D. Y., & Yoon, S. (2016). N-glycosylation design and control of therapeutic monoclonal antibodies. Trends in biotechnology, 34(10), 835-846. View at Publisher | View at Google Scholar | View at Indexing
- Brühlmann, D., Jordan, M., Hemberger, J., Sauer, M., Stettler, M., & Broly, H. (2015). Tailoring recombinant protein quality by rational media design. Biotechnology progress, 31(3), 615-629. View at Publisher | View at Google Scholar | View at Indexing
- Pais, D. A., Carrondo, M. J., Alves, P. M., & Teixeira, A. P. (2014). Towards real-time monitoring of therapeutic protein quality in mammalian cell processes. Current opinion in biotechnology, 30, 161-167. View at Publisher | View at Google Scholar | View at Indexing
- Vishwanathan, N., Yongky, A., Johnson, K. C., Fu, H. Y., Jacob, N. M., Le, H., ... & Hu, W. S. (2015). Global insights into the Chinese hamster and CHO cell transcriptomes. Biotechnology and bioengineering, 112(5), 965-976. View at Publisher | View at Google Scholar | View at Indexing
- McAtee, A. G., Jazmin, L. J., & Young, J. D. (2015). Application of isotope labeling experiments and 13C flux analysis to enable rational pathway engineering. Current opinion in biotechnology, 36, 50-56. View at Publisher | View at Google Scholar | View at Indexing
- Templeton, N., Smith, K. D., McAtee-Pereira, A. G., Dorai, H., Betenbaugh, M. J., Lang, S. E., & Young, J. D. (2017). Application of 13C flux analysis to identify high-productivity CHO metabolic phenotypes. Metabolic engineering, 43, 218-225. View at Publisher | View at Google Scholar | View at Indexing
- Richelle, A., & Lewis, N. E. (2017). Improvements in protein production in mammalian cells from targeted metabolic engineering. Current opinion in systems biology, 6, 1-6. View at Publisher | View at Google Scholar | View at Indexing
- Young, J. D. (2014). 13C metabolic flux analysis of recombinant expression hosts. Current opinion in biotechnology, 30, 238-245. View at Publisher | View at Google Scholar | View at Indexing
- Lewis, A. M., Croughan, W. D., Aranibar, N., Lee, A. G., Warrack, B., Abu-Absi, N. R., ... & Li, Z. J. (2016). Understanding and controlling sialylation in a CHO Fc-fusion process. PLoS One, 11(6), e0157111. View at Publisher | View at Google Scholar | View at Indexing
- Klein, T., Niklas, J., & Heinzle, E. (2015). Engineering the supply chain for protein production/secretion in yeasts and mammalian cells. Journal of Industrial Microbiology and Biotechnology, 42(3), 453-464. View at Publisher | View at Google Scholar | View at Indexing
- Radhakrishnan, D., Robinson, A. S., & Ogunnaike, B. A. (2018). Controlling the glycosylation profile in mAbs using time-dependent media supplementation. Antibodies, 7(1), 1. View at Publisher | View at Google Scholar | View at Indexing
- Milne, J. J. (2017). Scale-up of protein purification: downstream processing issues. Protein Chromatography, 71-84. View at Publisher | View at Google Scholar | View at Indexing
- McAtee Pereira, A. G., Walther, J. L., Hollenbach, M., & Young, J. D. (2018). 13C flux analysis reveals that rebalancing medium amino acid composition can reduce ammonia production while preserving central carbon metabolism of CHO cell cultures. Biotechnology journal, 13(10), 1700518. View at Publisher | View at Google Scholar | View at Indexing
- Zhu, M. M., Mollet, M., Hubert, R. S., Kyung, Y. S., & Zhang, G. G. (2017). Industrial production of therapeutic proteins: cell lines, cell culture, and purification. In Handbook of industrial chemistry and biotechnology (pp. 1639-1669). Springer, Cham. View at Publisher | View at Google Scholar | View at Indexing
- O’Mara, B., Gao, Z. H., Kuruganti, M., Mallett, R., Nayar, G., Smith, L., ... & Fann, J. (2019). Impact of depth filtration on disulfide bond reduction during downstream processing of monoclonal antibodies from CHO cell cultures. Biotechnology and bioengineering, 116(7), 1669-1683. View at Publisher | View at Google Scholar | View at Indexing
- Templeton, N., & Young, J. D. (2018). Biochemical and metabolic engineering approaches to enhance production of therapeutic proteins in animal cell cultures. Biochemical Engineering Journal, 136, 40-50. View at Publisher | View at Google Scholar | View at Indexing
- Liu, Y., Fernandez, J., Pu, Z., Zhang, H., Cao, L., Aguilar, I., ... & Liu, A. (2020). Simultaneous monitoring and comparison of multiple product quality attributes for cell culture processes at different scales using a LC/MS/MS based multi-attribute method. Journal of Pharmaceutical Sciences, 109(11), 3319-3329. View at Publisher | View at Google Scholar | View at Indexing
- Liu, Y., Fernandez, J., Pu, Z., Zhang, H., Cao, L., Aguilar, I., ... & Liu, A. (2020). Simultaneous monitoring and comparison of multiple product quality attributes for cell culture processes at different scales using a LC/MS/MS based multi-attribute method. Journal of Pharmaceutical Sciences, 109(11), 3319-3329. View at Publisher | View at Google Scholar | View at Indexing
- Karengera, E., Durocher, Y., De Crescenzo, G., & Henry, O. (2017). Combining metabolic and process engineering strategies to improve recombinant glycoprotein production and quality. Applied microbiology and biotechnology, 101(21), 7837-7851. View at Publisher | View at Google Scholar | View at Indexing
- Bulté, D. B., Palomares, L. A., Parra, C. G., Martínez, J. A., Contreras, M. A., Noriega, L. G., & Ramírez, O. T. (2020). Overexpression of the mitochondrial pyruvate carrier reduces lactate production and increases recombinant protein productivity in CHO cells. Biotechnology and Bioengineering, 117(9), 2633-2647. View at Publisher | View at Google Scholar | View at Indexing
- Kirsch, B. J., Bennun, S. V., Mendez, A., Johnson, A. S., Wang, H., Qiu, H., ... & Betenbaugh, M. J. (2021). Metabolic Analysis of the Asparagine and Glutamine Dynamics in an Industrial CHO Fed?Batch Process. Biotechnology and Bioengineering. View at Publisher | View at Google Scholar | View at Indexing