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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  • Schmitt, S. B. (2016). Investigation of the Role of Tensile Forces in Cellular Response to Chemotherapeutic Agents (Doctoral dissertation, University of Kansas). View at Publisher | View at Google Scholar | View at Indexing
  • Jin, L., Wang, Z. S., Cao, Y., Sun, R. Q., Zhou, H., & Cao, R. Y. (2021). Establishment and optimization of a high-throughput mimic perfusion model in ambr® 15. Biotechnology Letters, 43(2), 423-433. View at Publisher | View at Google Scholar | View at Indexing
  • Yu Hongfei, Jiang Jiao, Dong Qinan, Huang Rong, Shang Hua, Ye Dongqing, & Liu Yanlin. Research on the factors related to ethanol fermentation of Saccharomyces cerevisiae in microplate screening. Food and Fermentation Industry , 47 (20), 8-14. View at Publisher | View at Google Scholar | View at Indexing
  • Dolata, K. M., Montero, I. G., Miller, W., Sievers, S., Sura, T., Wolff, C., ... & Robinson, C. (2019). Far-reaching cellular consequences of tat deletion in Escherichia coli revealed by comprehensive proteome analyses. Microbiological research, 218, 97-107. View at Publisher | View at Google Scholar | View at Indexing
  • Zedler, J. A., Mullineaux, C. W., & Robinson, C. (2016). Efficient targeting of recombinant proteins to the thylakoid lumen in Chlamydomonas reinhardtii using a bacterial Tat signal peptide. Algal research, 19, 57-62. View at Publisher | View at Google Scholar | View at Indexing
  • Pourhassan, N. Z., Smits, S. H., Ahn, J. H., & Schmitt, L. (2021). Biotechnological applications of type 1 secretion systems. Biotechnology advances, 107864. View at Publisher | View at Google Scholar | View at Indexing
  • Zedler, J. A. Z. (2016). Expanding the toolkit of the Chlamydomonas reinhardtii chloroplast for biotechnological applications (Doctoral dissertation, University of Kent,). View at Publisher | View at Google Scholar | View at Indexing
  • Kalkman, S., Arentshorst, M., Hoekman, J., Boon, W., Uijtendaal, E., van Thiel, G., & Moors, E. (2020). In-hospital production of medicines: preparing for disruption. Trends in biotechnology, 38(10), 1045-1047. View at Publisher | View at Google Scholar | View at Indexing
  • Desai, P. M., Liew, C. V., & Heng, P. W. S. (2016). Review of disintegrants and the disintegration phenomena. Journal of pharmaceutical sciences, 105(9), 2545-2555. View at Publisher | View at Google Scholar | View at Indexing
  • Hwang, I., Kang, C. Y., & Park, J. B. (2017). Advances in hot-melt extrusion technology toward pharmaceutical objectives. Journal of Pharmaceutical Investigation, 47(2), 123-132. View at Publisher | View at Google Scholar | View at Indexing
  • Alam, M. A., Shi, Z., Drennen III, J. K., & Anderson, C. A. (2017). In-line monitoring and optimization of powder flow in a simulated continuous process using transmission near infrared spectroscopy. International journal of pharmaceutics, 526(1-2), 199-208. View at Publisher | View at Google Scholar | View at Indexing
  • Desai, P. M., Hogan, R. C., Brancazio, D., Puri, V., Jensen, K. D., Chun, J. H., ... & Trout, B. L. (2017). Integrated hot-melt extrusion–injection molding continuous tablet manufacturing platform: Effects of critical process parameters and formulation attributes on product robustness and dimensional stability. International journal of pharmaceutics, 531(1), 332-342. View at Publisher | View at Google Scholar | View at Indexing
  • Kim, S. H., Hwang, K. M., Cho, C. H., Nguyen, T. T., Seok, S. H., Hwang, K. M., ... & Park, E. S. (2017). Application of continuous twin screw granulation for the metformin hydrochloride extended release formulation. International journal of pharmaceutics, 529(1-2), 410-422. View at Publisher | View at Google Scholar | View at Indexing
  • Desai, P. M., Puri, V., Brancazio, D., Halkude, B. S., Hartman, J. E., Wahane, A. V., ... & Trout, B. L. (2018). Tablet coating by injection molding technology–Optimization of coating formulation attributes and coating process parameters. European Journal of Pharmaceutics and Biopharmaceutics, 122, 25-36. View at Publisher | View at Google Scholar | View at Indexing
  • Yeap, E. W., Acevedo, A. J., & Khan, S. A. (2019). Microfluidic extractive crystallization for spherical drug/drug-excipient microparticle production. Organic Process Research & Development, 23(3), 375-381. View at Publisher | View at Google Scholar | View at Indexing
  • Yeap, E. W., Acevedo, A. J., & Khan, S. A. (2019). Microfluidic extractive crystallization for spherical drug/drug-excipient microparticle production. Organic Process Research & Development, 23(3), 375-381. View at Publisher | View at Google Scholar | View at Indexing
  • Desai, P. M., Anbalagan, P., Koh, C. J., Heng, P. W., & Liew, C. V. (2018). Evaluation of tablet punch configuration on mitigating capping by a quality by design approach. Drug delivery and translational research, 8(6), 1635-1643. View at Publisher | View at Google Scholar | View at Indexing
  • Fischer, S., Handrick, R., & Otte, K. (2015). The art of CHO cell engineering: A comprehensive retrospect and future perspectives. Biotechnology advances, 33(8), 1878-1896. View at Publisher | View at Google Scholar | View at Indexing
  • Quan, G., & Li, J. (2018). Circular RNAs: biogenesis, expression and their potential roles in reproduction. Journal of ovarian research, 11(1), 1-12. View at Publisher | View at Google Scholar | View at Indexing
  • Bobbili, M. R., Mader, R. M., Grillari, J., & Dellago, H. (2017). OncomiR-17-5p: alarm signal in cancer?. Oncotarget, 8(41), 71206. View at Publisher | View at Google Scholar | View at Indexing
  • Fischer, S., Mathias, S., Schaz, S., Emmerling, V. V., Buck, T., Kleemann, M., ... & Otte, K. (2015). Enhanced protein production by microRNA-30 family in CHO cells is mediated by the modulation of the ubiquitin pathway. Journal of biotechnology, 212, 32-43. View at Publisher | View at Google Scholar | View at Indexing
  • Fischer, S., Marquart, K. F., Pieper, L. A., Fieder, J., Gamer, M., Gorr, I., ... & Bradl, H. (2017). miRNA engineering of CHO cells facilitates production of difficult?to?express proteins and increases success in cell line development. Biotechnology and bioengineering, 114(7), 1495-1510. View at Publisher | View at Google Scholar | View at Indexing
  • Stiefel, F., Fischer, S., Sczyrba, A., Otte, K., & Hesse, F. (2016). miRNA profiling of high, low and non-producing CHO cells during biphasic fed-batch cultivation reveals process relevant targets for host cell engineering. Journal of biotechnology, 225, 31-43. View at Publisher | View at Google Scholar | View at Indexing
  • Schoellhorn, M., Fischer, S., Wagner, A., Handrick, R., & Otte, K. (2017). miR?143 targets MAPK7 in CHO cells and induces a hyperproductive phenotype to enhance production of difficult?to?express proteins. Biotechnology progress, 33(4), 1046-1058. View at Publisher | View at Google Scholar | View at Indexing
  • Inwood, S., Betenbaugh, M. J., & Shiloach, J. (2018). Methods for using small non-coding RNAs to improve recombinant protein expression in mammalian cells. Genes, 9(1), 25. View at Publisher | View at Google Scholar | View at Indexing
  • Weis, B. L., Guth, N., Fischer, S., Wissing, S., Fradin, S., Holzmann, K. H., ... & Otte, K. (2018). Stable miRNA overexpression in human CAP cells: Engineering alternative production systems for advanced manufacturing of biologics using miR?136 and miR?3074. Biotechnology and bioengineering, 115(8), 2027-2038. View at Publisher | View at Google Scholar | View at Indexing
  • Meyer, H. J., Reilly, D., Martin, S. E., & Wong, A. W. (2017). Identification of a novel miRNA that increases transient protein expression in combination with valproic acid. Biotechnology progress, 33(4), 1139-1145. View at Publisher | View at Google Scholar | View at Indexing
  • Wang, T. Y., & Guo, X. (2020). Expression vector cassette engineering for recombinant therapeutic production in mammalian cell systems. Applied microbiology and biotechnology, 104(13), 5673-5688. View at Publisher | View at Google Scholar | View at Indexing
  • Eitoku, M., Kato, H., Suganuma, N., & Kiyosawa, H. (2018). Markers associated with neuron-specific Ube3a imprinting during neuronal differentiation of mouse embryonic stem cells. Cytotechnology, 70(1), 45-53. View at Publisher | View at Google Scholar | View at Indexing
  • Janakiraman, V., Kwiatkowski, C., Kshirsagar, R., Ryll, T., & Huang, Y. M. (2015). Application of high?throughput mini?bioreactor system for systematic scale?down modeling, process characterization, and control strategy development. Biotechnology progress, 31(6), 1623-1632. View at Publisher | View at Google Scholar | View at Indexing
  • Tai, M., Ly, A., Leung, I., & Nayar, G. (2015). Efficient high?throughput biological process characterization: Definitive screening design with the Ambr250 bioreactor system. Biotechnology progress, 31(5), 1388-1395. View at Publisher | View at Google Scholar | View at Indexing
  • Xu, P., Clark, C., Ryder, T., Sparks, C., Zhou, J., Wang, M., ... & Scott, C. (2017). Characterization of TAP Ambr 250 disposable bioreactors, as a reliable scale?down model for biologics process development. Biotechnology progress, 33(2), 478-489. View at Publisher | View at Google Scholar | View at Indexing
  • Flitsch, D., Krabbe, S., Ladner, T., Beckers, M., Schilling, J., Mahr, S., ... & Büchs, J. (2016). Respiration activity monitoring system for any individual well of a 48-well microtiter plate. Journal of biological engineering, 10(1), 1-14. View at Publisher | View at Google Scholar | View at Indexing
  • Sandner, V., Pybus, L. P., McCreath, G., & Glassey, J. (2019). Scale?down model development in Ambr systems: An industrial perspective. Biotechnology journal, 14(4), 1700766. View at Publisher | View at Google Scholar | View at Indexing
  • Ladner, T., Flitsch, D., Schlepütz, T., & Büchs, J. (2015). Online monitoring of dissolved oxygen tension in microtiter plates based on infrared fluorescent oxygen-sensitive nanoparticles. Microbial cell factories, 14(1), 1-14. View at Publisher | View at Google Scholar | View at Indexing
  • Pollard, J., McDonald, P., & Hesslein, A. (2016). Lessons learned in building high?throughput process development capabilities. Engineering in Life Sciences, 16(2), 93-98. View at Publisher | View at Google Scholar | View at Indexing
  • Pollard, D., & Kistler, C. (2017). Disposable bioreactors. In Current Developments in Biotechnology and Bioengineering (pp. 353-379). Elsevier. View at Publisher | View at Google Scholar | View at Indexing
  • Petroff, M. G., Feliciano, J., Pollard, D. J., Li, H., Linden, T. O., & Pollard, J. M. (2016). High?throughput purification tools for rapid upstream process development are interchangeable for biologics. Engineering in Life Sciences, 16(2), 114-123. View at Publisher | View at Google Scholar | View at Indexing
  • Rotondi, M., Grace, N., Betts, J., Bargh, N., Costariol, E., Zoro, B., ... & Rafiq, Q. A. (2021). Design and development of a new ambr250® bioreactor vessel for improved cell and gene therapy applications. Biotechnology Letters, 43(5), 1103-1116. View at Publisher | View at Google Scholar | View at Indexing
  • Terán, W. G. M., Aiello, R. C., & Bastidas, P. A. B. (2017). Control y automatización de un secador experimental de granos en lecho fluidizado pulsante. Revista Ciências Exatas, 23(1). View at Publisher | View at Google Scholar | View at Indexing
  • Betts, M. R. N. G. J., Costariol, N. B. E., Alvin, B. Z. C. J. H., & Rafiq, W. N. Q. A. (2021). Design and development of a new ambr250Ò bioreactor vessel for improved cell and gene therapy applications. View at Publisher | View at Google Scholar | View at Indexing
  • Combe, M., & Sokolenko, S. (2021). Quantifying the impact of cell culture media on CHO cell growth and protein production. Biotechnology Advances, 107761. View at Publisher | View at Google Scholar | View at Indexing
  • Fernandes, C. F., Pereira, S. S., Luiz, M. B., Silva, N. K., da Silva, M. C., Marinho, A. C. M., ... & Stabeli, R. G. (2021). Engineering of single-domain antibodies for next generation snakebite antivenoms. International journal of biological macromolecules. View at Publisher | View at Google Scholar | View at Indexing
  • Ling, W. L. W. (2019). Current Considerations and Future Advances in Chemically Defined Medium Development for the Production of Protein Therapeutics in CHO Cells. Cell Culture Engineering: Recombinant Protein Production, 279-294. View at Publisher | View at Google Scholar | View at Indexing
  • Sheen, D. A., Shen, V. K., Brinson, R. G., Arbogast, L. W., Marino, J. P., & Delaglio, F. (2020). Chemometric outlier classification of 2D-NMR spectra to enable higher order structure characterization of protein therapeutics. Chemometrics and Intelligent Laboratory Systems, 199, 103973. View at Publisher | View at Google Scholar | View at Indexing
  • Gerdtzen, Z. P. (2017). Medium Design, Culture Management, and the PAT Initiative. Applied Bioengineering: Innovations and Future Directions, 2, 8. View at Publisher | View at Google Scholar | View at Indexing
  • Carrara, S. C., Ulitzka, M., Grzeschik, J., Kornmann, H., Hock, B., & Kolmar, H. (2021). From cell line development to the formulated drug product: The art of manufacturing therapeutic monoclonal antibodies. International Journal of Pharmaceutics, 594, 120164. View at Publisher | View at Google Scholar | View at Indexing
  • Jordan, M., Mac Kinnon, N., Monchois, V., Stettler, M., & Broly, H. (2018). Intensification of large-scale cell culture processes. Current opinion in chemical engineering, 22, 253-257. View at Publisher | View at Google Scholar | View at Indexing
  • Yongky, A., Xu, J., Tian, J., Oliveira, C., Zhao, J., McFarland, K., ... & Li, Z. J. (2019, November). Process intensification in fed-batch production bioreactors using non-perfusion seed cultures. In MAbs (Vol. 11, No. 8, pp. 1502-1514). Taylor & Francis. View at Publisher | View at Google Scholar | View at Indexing
  • Liu, T., Guo, H., Zhu, L., Zheng, Y., Xu, J., Guo, Q., ... & Wang, H. (2016). Fast characterization of Fc-containing proteins by middle-down mass spectrometry following IdeS digestion. Chromatographia, 79(21), 1491-1505. View at Publisher | View at Google Scholar | View at Indexing