ISSN: 2048-9145

Pharmaceutical Bioprocessing

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

Total published articles

 31 7 5 23 10 17

Citations received as per Google Scholar, other indexing platforms and portals

 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 2019 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
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  • Nian, R., Zhang, W., Tan, L., Lee, J., Bi, X., Yang, Y., ... & Gagnon, P. (2016). Advance chromatin extraction improves capture performance of protein A affinity chromatography. Journal of Chromatography A, 1431, 1-7. View at Publisher | View at Google Scholar | View at Indexing
  • Burgstaller, D., Krepper, W., Haas, J., Maszelin, M., Mohoric, J., Pajnic, K., ... & Satzer, P. (2018). Continuous cell flocculation for recombinant antibody harvesting. Journal of Chemical Technology & Biotechnology, 93(7), 1881-1890. View at Publisher | View at Google Scholar | View at Indexing
  • Liu, W., Fan, X., Wang, X., Rai, K., Su, J., Xian, M., & Nian, R. (2019). Chromatin-directed clarification in cell culture fluid enables non-protein affinity antibody purification by tangential flow filtration integrated with high-capacity cation exchange chromatography. Biochemical Engineering Journal, 151, 107315. View at Publisher | View at Google Scholar | View at Indexing
  • Schmitt, M. G., Rajendra, Y., Hougland, M. D., Boyles, J. S., & Barnard, G. C. (2017). Polymer?mediated flocculation of transient CHO cultures as a simple, high throughput method to facilitate antibody discovery. Biotechnology progress, 33(5), 1393-1400. View at Publisher | View at Google Scholar | View at Indexing
  • Dryden, W. A., Larsen, L. M., Britt, D. W., & Smith, M. T. (2021). Technical and economic considerations of cell culture harvest and clarification technologies. Biochemical Engineering Journal, 167, 107892. View at Publisher | View at Google Scholar | View at Indexing
  • Khodadadian, M., Ghassemi, M., Behrouz, H., Maleknia, S., & Mahboudi, F. (2019). Determination of residual poly diallyldimethylammonium chloride (pDADMAC) in monoclonal antibody formulations by size exclusion chromatography and evaporative light scattering detector. Biologicals, 57, 21-28. View at Publisher | View at Google Scholar | View at Indexing
  • Pereira, S., Kildegaard, H. F., & Andersen, M. R. (2018). Impact of CHO metabolism on cell growth and protein production: an overview of toxic and inhibiting metabolites and nutrients. Biotechnology journal, 13(3), 1700499. View at Publisher | View at Google Scholar | View at Indexing
  • Toussaint, C., Henry, O., & Durocher, Y. (2016). Metabolic engineering of CHO cells to alter lactate metabolism during fed-batch cultures. Journal of biotechnology, 217, 122-131. View at Publisher | View at Google Scholar | View at Indexing
  • Templeton, N., Lewis, A., Dorai, H., Qian, E. A., Campbell, M. P., Smith, K. D., ... & Young, J. D. (2014). The impact of anti-apoptotic gene Bcl-2? expression on CHO central metabolism. Metabolic engineering, 25, 92-102. View at Publisher | View at Google Scholar | View at Indexing
  • Yuk, I. H., Zhang, J. D., Ebeling, M., Berrera, M., Gomez, N., Werz, S., ... & Szperalski, B. (2014). Effects of copper on CHO cells: insights from gene expression analyses. Biotechnology progress, 30(2), 429-442. View at Publisher | View at Google Scholar | View at Indexing
  • Pan, X., Streefland, M., Dalm, C., Wijffels, R. H., & Martens, D. E. (2017). Selection of chemically defined media for CHO cell fed-batch culture processes. Cytotechnology, 69(1), 39-56. View at Publisher | View at Google Scholar | View at Indexing
  • Del Val, I. J., Polizzi, K. M., & Kontoravdi, C. (2016). A theoretical estimate for nucleotide sugar demand towards Chinese Hamster Ovary cellular glycosylation. Scientific reports, 6(1), 1-15. View at Publisher | View at Google Scholar | View at Indexing
  • Kyriakopoulos, S., & Kontoravdi, C. (2014). A framework for the systematic design of fed?batch strategies in mammalian cell culture. Biotechnology and Bioengineering, 111(12), 2466-2476. View at Publisher | View at Google Scholar | View at Indexing
  • Gupta, P., Hourigan, K., Jadhav, S., Bellare, J., & Verma, P. (2017). Effect of lactate and pH on mouse pluripotent stem cells: Importance of media analysis. Biochemical Engineering Journal, 118, 25-33. View at Publisher | View at Google Scholar | View at Indexing
  • Blondeel, E. J., Ho, R., Schulze, S., Sokolenko, S., Guillemette, S. R., Slivac, I., ... & Aucoin, M. G. (2016). An omics approach to rational feed: enhancing growth in CHO cultures with NMR metabolomics and 2D-DIGE proteomics. Journal of biotechnology, 234, 127-138. View at Publisher | View at Google Scholar | View at Indexing
  • Wurm, F. M., & de Jesus, M. (2016). Manufacture of Recombinant Therapeutic Proteins Using Chinese Hamster Ovary Cells in Large?Scale Bioreactors: History, Methods, and Perspectives. Biosimilars of Monoclonal Antibodies: A Practical Guide to Manufacturing, Preclinical, and Clinical Development, 327-353. 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
  • Hong, J. K., Nargund, S., Lakshmanan, M., Kyriakopoulos, S., Kim, D. Y., Ang, K. S., ... & Lee, D. Y. (2018). Comparative phenotypic analysis of CHO clones and culture media for lactate shift. Journal of biotechnology, 283, 97-104. View at Publisher | View at Google Scholar | View at Indexing
  • Guerra, A., von Stosch, M., & Glassey, J. (2019). Toward biotherapeutic product real-time quality monitoring. Critical reviews in biotechnology, 39(3), 289-305. View at Publisher | View at Google Scholar | View at Indexing
  • Simutis, R., & Lübbert, A. (2015). Bioreactor control improves bioprocess performance. Biotechnology journal, 10(8), 1115-1130. View at Publisher | View at Google Scholar | View at Indexing
  • Jenzsch, M., Bell, C., Buziol, S., Kepert, F., Wegele, H., & Hakemeyer, C. (2017). Trends in process analytical technology: Present state in bioprocessing. In New bioprocessing strategies: Development and manufacturing of recombinant antibodies and proteins (pp. 211-252). Springer, Cham. View at Publisher | View at Google Scholar | View at Indexing
  • Zhang, P., Woen, S., Wang, T., Liau, B., Zhao, S., Chen, C., ... & Rudd, P. M. (2016). Challenges of glycosylation analysis and control: an integrated approach to producing optimal and consistent therapeutic drugs. Drug discovery today, 21(5), 740-765. View at Publisher | View at Google Scholar | View at Indexing
  • Jedrzejewski, P. M., Del Val, I. J., Constantinou, A., Dell, A., Haslam, S. M., Polizzi, K. M., & Kontoravdi, C. (2014). Towards controlling the glycoform: a model framework linking extracellular metabolites to antibody glycosylation. International journal of molecular sciences, 15(3), 4492-4522. View at Publisher | View at Google Scholar | View at Indexing
  • Brown, A. J., & James, D. C. (2016). Precision control of recombinant gene transcription for CHO cell synthetic biology. Biotechnology advances, 34(5), 492-503. View at Publisher | View at Google Scholar | View at Indexing
  • Del Val, I. J., Polizzi, K. M., & Kontoravdi, C. (2016). A theoretical estimate for nucleotide sugar demand towards Chinese Hamster Ovary cellular glycosylation. Scientific reports, 6(1), 1-15. View at Publisher | View at Google Scholar | View at Indexing
  • Liu, J., Wang, J., Fan, L., Chen, X., Hu, D., Deng, X., ... & Tan, W. S. (2015). Galactose supplementation enhance sialylation of recombinant Fc-fusion protein in CHO cell: an insight into the role of galactosylation in sialylation. World Journal of Microbiology and Biotechnology, 31(7), 1147-1156. View at Publisher | View at Google Scholar | View at Indexing
  • Zalai, D., Hevér, H., Lovász, K., Molnár, D., Wechselberger, P., Hofer, A., ... & Herwig, C. (2016). A control strategy to investigate the relationship between specific productivity and high-mannose glycoforms in CHO cells. Applied microbiology and biotechnology, 100(16), 7011-7024. View at Publisher | View at Google Scholar | View at Indexing
  • Ribitsch, D., Zitzenbacher, S., Augustin, P., Schmölzer, K., Czabany, T., Luley-Goedl, C., ... & Schwab, H. (2014). High-quality production of human α-2, 6-sialyltransferase in Pichia pastoris requires control over N-terminal truncations by host-inherent protease activities. Microbial cell factories, 13(1), 1-12. View at Publisher | View at Google Scholar | View at Indexing
  • Hanneman, A. J., Strand, J., & Huang, C. T. (2014). Profiling and characterization of sialylated N-glycans by 2D-HPLC (HIAX/PGC) with online orbitrap MS/MS and offline MSn. Journal of pharmaceutical sciences, 103(2), 400-408. View at Publisher | View at Google Scholar | View at Indexing
  • Bello-Gil, D., & Manez, R. (2015). Exploiting natural anti-carbohydrate antibodies for therapeutic purposes. Biochemistry (Moscow), 80(7), 836-845. View at Publisher | View at Google Scholar | View at Indexing
  • Wang, T., Hoi, K. M., Stöckmann, H., Wan, C., Sim, L. C., Shi Jie Tay, N. H. B. K., ... & Rudd, P. M. (2018). LC/MS?based Intact IgG and Released Glycan Analysis for Bioprocessing Applications. Biotechnology journal, 13(4), 1700185. View at Publisher | View at Google Scholar | View at Indexing
  • Liu, J., Chen, X., Fan, L., Deng, X., Poon, H. F., Tan, W. S., & Liu, X. (2015). Monitoring sialylation levels of Fc-fusion protein using size-exclusion chromatography as a process analytical technology tool. Biotechnology letters, 37(7), 1371-1377. View at Publisher | View at Google Scholar | View at Indexing
  • Brown, A. J., Kalsi, D., Fernandez?Martell, A., Cartwright, J., Barber, N. O., Patel, Y. D., ... & James, D. C. (2017). Expression Systems for Recombinant Biopharmaceutical Production by Mammalian Cells in Culture. Protein Therapeutics, 2, 423-467. View at Publisher | View at Google Scholar | View at Indexing
  • Goey, C. H. (2016). Cascading effects in bioprocessing: the impact of cell culture environment on CHO cell behaviour and host cell protein species. View at Publisher | View at Google Scholar | View at Indexing
  • Rao, C. V. (2017). Inclusion of human chorionic gonadotropin in the family of therapeutic glycoproteins. Women Health Open J, 3(1), 30-35. View at Publisher | View at Google Scholar | View at Indexing
  • Klymenko, O. V., Shah, N., Kontoravdi, C., Royle, K. E., & Polizzi, K. M. (2016). Designing an Artificial Golgi reactor to achieve targeted glycosylation of monoclonal antibodies. AIChE Journal, 62(9), 2959-2973. View at Publisher | View at Google Scholar | View at Indexing
  • Jedrzejewski, P. M., Polizzi, K. M., & Kontoravdi, C. (2015, December). An improved model framework linking the extracellular environment to antibody glycosylation. In BMC Proceedings (Vol. 9, No. 9, pp. 1-3). BioMed Central. View at Publisher | View at Google Scholar | View at Indexing
  • Wang, P. Z. S. W. T., Chen, B. L. S. Z. C., Song, Y. Y. Z., Pauline, M. R. W. C. Y., Rudd, M., Zhao, S., ... & Yu, C. (2016). Challenges of glycosylation analysis and control: an integrated approach to producing optimal and consistent therapeutic drugs. View at Publisher | View at Google Scholar | View at Indexing
  • Kotidis, P., Pappas, I., Avraamidou, S., Pistikopoulos, E. N., Kontoravdi, C., & Papathanasiou, M. M. (2021). DigiGlyc: A hybrid tool for reactive scheduling in cell culture systems. Computers & Chemical Engineering, 154, 107460. View at Publisher | View at Google Scholar | View at Indexing
  • Saravanakumar, K., Kathiresan, K., Rajendran, N., Yu, C., & Chen, J. (2016). Marine Fungi: Glycolipidomics. In Marine Glycobiology (pp. 203-212). CRC Press. View at Publisher | View at Google Scholar | View at Indexing
  • Yamamoto, T. (2016). Sialyltransferases from Marine Environments: Preparation of Sialyloligosaccharides and its Application. In Marine Glycobiology (pp. 215-226). CRC Press. View at Publisher | View at Google Scholar | View at Indexing
  • Yamamoto, T. (2016). Sialyltransferases from Marine Environments: Preparation of Sialyloligosaccharides and its Application. In Marine Glycobiology (pp. 215-226). CRC Press. View at Publisher | View at Google Scholar | View at Indexing
  • Yamamoto, T. (2016). Sialyltransferases from Marine Environments: Preparation of Sialyloligosaccharides and its Application. In Marine Glycobiology (pp. 215-226). CRC Press. View at Publisher | View at Google Scholar | View at Indexing
  • Mousavi, M., Dehbashi, M., & Movahedi, A. Impact of Glycosylation on Therapeutic Glycoproteins. View at Publisher | View at Google Scholar | View at Indexing
  • Shukla, A. A., Wolfe, L. S., Mostafa, S. S., & Norman, C. (2017). Evolving trends in mAb production processes. Bioengineering & translational medicine, 2(1), 58-69. View at Publisher | View at Google Scholar | View at Indexing
  • Gillespie, C., Holstein, M., Mullin, L., Cotoni, K., Tuccelli, R., Caulmare, J., & Greenhalgh, P. (2019). Continuous in?line virus inactivation for next generation bioprocessing. Biotechnology journal, 14(2), 1700718. View at Publisher | View at Google Scholar | View at Indexing
  • Barone, P. W., Wiebe, M. E., Leung, J. C., Hussein, I. T., Keumurian, F. J., Bouressa, J., ... & Springs, S. L. (2020). Viral contamination in biologic manufacture and implications for emerging therapies. Nature biotechnology, 38(5), 563-572. View at Publisher | View at Google Scholar | View at Indexing
  • Conley, L., Tao, Y., Henry, A., Koepf, E., Cecchini, D., Pieracci, J., & Ghose, S. (2017). Evaluation of eco?friendly zwitterionic detergents for enveloped virus inactivation. Biotechnology and bioengineering, 114(4), 813-820. View at Publisher | View at Google Scholar | View at Indexing
  • Martins, D. L., Sencar, J., Hammerschmidt, N., Tille, B., Kinderman, J., Kreil, T. R., & Jungbauer, A. (2019). Continuous solvent/detergent virus inactivation using a packed?bed reactor. Biotechnology journal, 14(8), 1800646. View at Publisher | View at Google Scholar | View at Indexing
  • Junter, G. A., & Lebrun, L. (2020). Polysaccharide-based chromatographic adsorbents for virus purification and viral clearance. Journal of pharmaceutical analysis, 10(4), 291-312. View at Publisher | View at Google Scholar | View at Indexing