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 |
- Schmidt, C., Wehsling, M., Le Mignon, M., Wille, G., Rey, Y., Schnellbaecher, A., ... & Zimmer, A. (2021). Lactoyl leucine and isoleucine are bioavailable alternatives for canonical amino acids in cell culture media. Biotechnology and Bioengineering. View at Publisher | View at Google Scholar | View at Indexing
- Pollock, J., Coffman, J., Ho, S. V., & Farid, S. S. (2017). Integrated continuous bioprocessing: Economic, operational, and environmental feasibility for clinical and commercial antibody manufacture. Biotechnology progress, 33(4), 854-866. View at Publisher | View at Google Scholar | View at Indexing
- Hummel, J., Pagkaliwangan, M., Gjoka, X., Davidovits, T., Stock, R., Ransohoff, T., ... & Schofield, M. (2019). Modeling the downstream processing of monoclonal antibodies reveals cost advantages for continuous methods for a broad range of manufacturing scales. Biotechnology journal, 14(2), 1700665. View at Publisher | View at Google Scholar | View at Indexing
- Somasundaram, B., Pleitt, K., Shave, E., Baker, K., & Lua, L. H. (2018). Progression of continuous downstream processing of monoclonal antibodies: Current trends and challenges. Biotechnology and bioengineering, 115(12), 2893-2907. View at Publisher | View at Google Scholar | View at Indexing
- Gjoka, X., Rogler, K., Martino, R. A., Gantier, R., & Schofield, M. (2015). A straightforward methodology for designing continuous monoclonal antibody capture multi-column chromatography processes. Journal of Chromatography A, 1416, 38-46. View at Publisher | View at Google Scholar | View at Indexing
- Hardick, O., Dods, S., Stevens, B., & Bracewell, D. G. (2015). Nanofiber adsorbents for high productivity continuous downstream processing. Journal of biotechnology, 213, 74-82. View at Publisher | View at Google Scholar | View at Indexing
- Sinclair, A., Brower, M., Lopes, A. G., Pollard, D., & Abe, Y. (2016). Standardized economic cost modeling for next-generation MAb production. Bioprocess international, 14, 14-23. View at Publisher | View at Google Scholar | View at Indexing
- Castilho, L. R. (2014). Continuous animal cell perfusion processes: the first step toward integrated continuous biomanufacturing. Continuous processing in pharmaceutical manufacturing, 1, 115-154. View at Publisher | View at Google Scholar | View at Indexing
- Großhans, S., Wang, G., Fischer, C., & Hubbuch, J. (2018). An integrated precipitation and ion-exchange chromatography process for antibody manufacturing: process development strategy and continuous chromatography exploration. Journal of Chromatography A, 1533, 66-76. View at Publisher | View at Google Scholar | View at Indexing
- Farid, S. S., Thompson, B., & Davidson, A. (2014, November). Continuous bioprocessing: the real thing this time? 10th Annual bioProcessUK conference, December 3–4, 2013, London, UK. In MAbs (Vol. 6, No. 6, pp. 1357-1361). Taylor & Francis. View at Publisher | View at Google Scholar | View at Indexing
- Farid, S. S., Thompson, B., & Davidson, A. (2014, November). Continuous bioprocessing: the real thing this time? 10th Annual bioProcessUK conference, December 3–4, 2013, London, UK. In MAbs (Vol. 6, No. 6, pp. 1357-1361). Taylor & Francis. View at Publisher | View at Google Scholar | View at Indexing
- Pagkaliwangan, M., Hummel, J., Gjoka, X., Bisschops, M., & Schofield, M. (2019). Optimized continuous multicolumn chromatography enables increased productivities and cost savings by employing more columns. Biotechnology journal, 14(2), 1800179. View at Publisher | View at Google Scholar | View at Indexing
- Worsham, R. D., Thomas, V., & Farid, S. S. (2019). Potential of continuous manufacturing for liposomal drug products. Biotechnology journal, 14(2), 1700740. View at Publisher | View at Google Scholar | View at Indexing
- Schofield, M. (2018). Current state of the art in continuous bioprocessing. Biotechnology letters, 40(9), 1303-1309. View at Publisher | View at Google Scholar | View at Indexing
- Chiang, M. J., Pagkaliwangan, M., Lute, S., Bolton, G., Brorson, K., & Schofield, M. (2019). Validation and optimization of viral clearance in a downstream continuous chromatography setting. Biotechnology and bioengineering, 116(9), 2292-2302. View at Publisher | View at Google Scholar | View at Indexing
- El?Sabbahy, H., Ward, D., Ogonah, O., Deakin, L., Jellum, G. M., & Bracewell, D. G. (2018). The effect of feed quality due to clarification strategy on the design and performance of protein A periodic counter?current chromatography. Biotechnology progress, 34(6), 1380-1392. View at Publisher | View at Google Scholar | View at Indexing
- Pleitt, K., Somasundaram, B., Johnson, B., Shave, E., & Lua, L. H. (2019). Evaluation of process simulation as a decisional tool for biopharmaceutical contract development and manufacturing organizations. Biochemical Engineering Journal, 150, 107252. View at Publisher | View at Google Scholar | View at Indexing
- Ishihara, T., Miyahara, M., Yamada, T., & Yamamoto, K. (2019). Innovative next-generation monoclonal antibody purification using activated carbon: A challenge for flow-through and column-free processes. Journal of Chromatography B, 1121, 72-81. View at Publisher | View at Google Scholar | View at Indexing
- Erickson, J., Baker, J., Barrett, S., Brady, C., Brower, M., Carbonell, R., ... & Lee, K. (2021). End?to?end collaboration to transform biopharmaceutical development and manufacturing. Biotechnology and Bioengineering. View at Publisher | View at Google Scholar | View at Indexing
- Ghose, S., Rajshekaran, R., Labanca, M., & Conley, L. (2017). Modeling on-column reduction of trisulfide bonds in monoclonal antibodies during protein A chromatography. Journal of Chromatography A, 1479, 81-86. View at Publisher | View at Google Scholar | View at Indexing
- Armstrong, A., Horry, K., Cui, T., Hulley, M., Turner, R., Farid, S. S., ... & Bracewell, D. G. (2021). Advanced control strategies for bioprocess chromatography: Challenges and opportunities for intensified processes and next generation products. Journal of Chromatography A, 1639, 461914. View at Publisher | View at Google Scholar | View at Indexing
- Deulgaonkar, P., Bhambure, R., Prasad, B., Mishra, A., Tiwari, S., & Mody, R. (2021). Mechanistic modeling of continuous capture step purification of biosimilar monoclonal antibody therapeutic. Journal of Chemical Technology & Biotechnology. View at Publisher | View at Google Scholar | View at Indexing
- Deulgaonkar, P., Bhambure, R., Prasad, B., Mishra, A., Tiwari, S., & Mody, R. (2021). Mechanistic modeling of continuous capture step purification of biosimilar monoclonal antibody therapeutic. Journal of Chemical Technology & Biotechnology. View at Publisher | View at Google Scholar | View at Indexing
- Löfgren, A., Gomis?Fons, J., Andersson, N., Nilsson, B., Berghard, L., & Lagerquist Hägglund, C. (2021). An integrated continuous downstream process with real?time control: A case study with periodic countercurrent chromatography and continuous virus inactivation. Biotechnology and Bioengineering, 118(4), 1645-1657. View at Publisher | View at Google Scholar | View at Indexing
- Ketterer, B., Moore-Kelly, C., Thomas, O. R., & Franzreb, M. (2020). Integrated system for temperature-controlled fast protein liquid chromatography. III. Continuous downstream processing of monoclonal antibodies. Journal of Chromatography A, 1609, 460429. View at Publisher | View at Google Scholar | View at Indexing
- Manser, B., Glenz, M., & Bisschops, M. (2019). Single?Use Downstream Processing for Biopharmaceuticals: Current State and Trends. Single?Use Technology in Biopharmaceutical Manufacture, 117-126. View at Publisher | View at Google Scholar | View at Indexing
- Li, Y., Chang, A., Beattie, D., & Remington, K. M. (2020). Novel spiking methods developed for anion exchange chromatography operating in a continuous process. Biotechnology and Bioengineering, 117(11), 3379-3389. View at Publisher | View at Google Scholar | View at Indexing
- ZHANG, L., CAO, X. D., YANG, H. X., & LI, W. L. (2021). The Application of Continuous Purification in Affinity Chromatography and Evaluation of Production Scale-up. China Biotechnology, 41(6), 38-44. View at Publisher | View at Google Scholar | View at Indexing
- Somasundaram, B., Pleitt, K., Shave, E., Baker, K., & HL, L. monoclonal antibodies: current trends and challenges. View at Publisher | View at Google Scholar | View at Indexing
- Bisschops, M., Manser, B., & Glenz, M. (2019). Single?Use Continuous Downstream Processing for Biopharmaceutical Products. Single?Use Technology in Biopharmaceutical Manufacture, 279-283. View at Publisher | View at Google Scholar | View at Indexing
- Bisschops, M., Manser, B., & Glenz, M. (2019). Single?Use Continuous Downstream Processing for Biopharmaceutical Products. Single?Use Technology in Biopharmaceutical Manufacture, 279-283. View at Publisher | View at Google Scholar | View at Indexing
- Gillette, K., Bisschops, M., & Schofield, M. (2021). Development and optimization of multicolumn chromatography for mAb perfusion processes. Journal of Chemical Technology & Biotechnology. View at Publisher | View at Google Scholar | View at Indexing
- Müller, D., Klein, L., Lemke, J., Schulze, M., Kruse, T., Saballus, M., ... & Zijlstra, G. (2022). Process intensification in the biopharma industry: Improving efficiency of protein manufacturing processes from development to production scale using synergistic approaches. Chemical Engineering and Processing-Process Intensification, 171, 108727. View at Publisher | View at Google Scholar | View at Indexing