Design strategies for integrated protein purification processes: challenges, progress and outlook

被引:81
作者
Nfor, Beckley K. [1 ]
Ahamed, Tangir [1 ]
van Dedem, Gijs W. K. [1 ]
van der Wielen, Luuk A. M. [1 ]
van de Sandt, Emile J. A. X. [2 ]
Eppink, Michel H. M. [3 ]
Ottens, Marcel [1 ]
机构
[1] Delft Univ Technol, Dept Biotechnol, Delft, Netherlands
[2] DSM Anti Infect, Delft, Netherlands
[3] NV Organon, Biotechnol Operat, Oss, Netherlands
来源
JOURNAL OF CHEMICAL TECHNOLOGY AND BIOTECHNOLOGY | 2008年 / 83卷 / 02期
关键词
protein purification; process development; process synthesis; high throughput experimentation; expert systems; algorithmic approach;
D O I
10.1002/jctb.1815
中图分类号
Q81 [生物工程学(生物技术)]; Q93 [微生物学];
学科分类号
071005 ; 0836 ; 090102 ; 100705 ;
摘要
The key to successful and efficient protein purification is the selection of the most appropriate purification techniques and their combination in a logical way to obtain the desired purification in the minimum number of steps. However, the rationalization of protein purification process development is faced with a number of challenges. In this paper, the challenges in protein purification process development are captured. The state-of-the-art in protein purification process synthesis and design is reviewed and the strengths and weaknesses of the current strategies highlighted. Finally, views on the future directions of protein purification process development are presented. (c) 2007 Society of Chemical Industry.
引用
收藏
页码:124 / 132
页数:9
相关论文
共 38 条
[21]   Towards Integrated Design and Delivery Solutions: Pinpointed Challenges of Process Change [J].
Rekola, Mirkka ;
Kojima, Jun ;
Makelainen, Tarja .
ARCHITECTURAL ENGINEERING AND DESIGN MANAGEMENT, 2010, 6 (04) :264-278
[22]   Integrated design and control of chemical processes - Part I: Revision and classification [J].
Vega, P. ;
Lamanna de Rocco, R. ;
Revollar, S. ;
Francisco, M. .
COMPUTERS & CHEMICAL ENGINEERING, 2014, 71 :602-617
[23]   Integrated design and control of chemical processes - Part II: An illustrative example [J].
Vega, P. ;
Lamanna, R. ;
Revollar, S. ;
Francisco, M. .
COMPUTERS & CHEMICAL ENGINEERING, 2014, 71 :618-635
[24]   Algorithmic synthesis and integrated design for activated sludge processes using genetic algorithms [J].
Revollar, S ;
Lamanna, R ;
Vega, P .
European Symposium on Computer-Aided Process Engineering-15, 20A and 20B, 2005, 20a-20b :739-744
[25]   Use of proteomics for design of a tailored host cell for highly efficient protein purification [J].
Liu, Zhu ;
Bartlow, Patrick ;
Varakata, Rajaramesh ;
Beitle, Robert ;
Koepsel, Richard ;
Ataa, Mohammad M. .
JOURNAL OF CHROMATOGRAPHY A, 2009, 1216 (12) :2433-2438
[26]   Recombinant protein purification and immobilization strategies based on peptides with dual affinity to iron oxide and silica [J].
Aguiar, Tatiana Q. ;
Domingues, Lucilia .
BIOTECHNOLOGY JOURNAL, 2023, 18 (11)
[27]   Enveloped Virus Inactivation Using Neutral Arginine Solutions and Applications in Therapeutic Protein Purification Processes [J].
McCue, Justin T. ;
Selvitelli, Keith ;
Cecchini, Doug ;
Brown, Rhonda .
BIOTECHNOLOGY PROGRESS, 2014, 30 (01) :108-112
[28]   Generic chromatography-based purification strategies accelerate the development of downstream processes for biopharmaceutical proteins produced in plants [J].
Buyel, Johannes F. ;
Fischer, Rainer .
BIOTECHNOLOGY JOURNAL, 2014, 9 (04) :566-577
[29]   Broad application and optimization of a single wash-step for integrated endotoxin depletion during protein purification [J].
Koziel, David ;
Michaelis, Uwe ;
Kruse, Tobias .
JOURNAL OF CHROMATOGRAPHY B-ANALYTICAL TECHNOLOGIES IN THE BIOMEDICAL AND LIFE SCIENCES, 2018, 1091 :101-107
[30]   Development of purification processes for fully human bispecific antibodies based upon modification of protein A binding avidity [J].
Tustian, Andrew D. ;
Endicott, Christine ;
Adams, Benjamin ;
Mattila, John ;
Bak, Hanne .
MABS, 2016, 8 (04) :828-838
1234