In-process evaluation of culture errors using morphology-based image analysis
| Autor: | Kei Kanie, Mai Okada, Ryuji Kato, Hiroyuki Honda, Kei Yoshida, Kazunori Shimizu, Yuta Imai, Megumi Matsumoto |
|---|---|
| Rok vydání: | 2018 |
| Předmět: |
0301 basic medicine
Morphological analysis Computer science Process (engineering) Biomedical Engineering Non-invasive image analysis Bottleneck Plot (graphics) Cell manufacturing Biomaterials 03 medical and health sciences Linear regression lcsh:QH573-671 lcsh:R5-920 lcsh:Cytology business.industry In-process measurement Quality control Pattern recognition Visualization 030104 developmental biology Cell culture Principal component analysis Mesenchymal stem cells Original Article Artificial intelligence lcsh:Medicine (General) business Developmental Biology |
| Zdroj: | Regenerative Therapy Regenerative Therapy, Vol 9, Iss, Pp 15-23 (2018) |
| ISSN: | 2352-3204 |
| Popis: | Introduction Advancing industrial-scale manufacture of cells as therapeutic products is an example of the wide applications of regenerative medicine. However, one bottleneck in establishing stable and efficient cell manufacture is quality control. Owing to the lack of effective in-process measurement technology, analyzing the time-consuming and complex cell culture process that essentially determines cellular quality is difficult and only performed by manual microscopic observation. Our group has been applying advanced image-processing and machine-learning modeling techniques to construct prediction models that support quality evaluations during cell culture. In this study, as a model of errors during the cell culture process, intentional errors were compared to the standard culture and analyzed based only on the time-course morphological information of the cells. Methods Twenty-one lots of human mesenchymal stem cells (MSCs), including both bone-marrow-derived MSCs and adipose-derived MSCs, were cultured under 5 conditions (one standard and 4 types of intentional errors, such as clear failure of handlings and machinery malfunctions). Using time-course microscopic images, cell morphological profiles were quantitatively measured and utilized for visualization and prediction modeling. For visualization, modified principal component analysis (PCA) was used. For prediction modeling, linear regression analysis and the MT method were applied. Results By modified PCA visualization, the differences in cellular lots and culture conditions were illustrated as traits on a morphological transition line plot and found to be effective descriptors for discriminating the deviated samples in a real-time manner. In prediction modeling, both the cell growth rate and error condition discrimination showed high accuracy (>80%), which required only 2 days of culture. Moreover, we demonstrated the applicability of different concepts of machine learning using the MT method, which is effective for manufacture processes that mostly collect standard data but not a large amount of failure data. Conclusions Morphological information that can be quantitatively acquired during cell culture has great potential as an in-process measurement tool for quality control in cell manufacturing processes. Highlights • Morphological information was used for detecting deviation samples in MSC culture. • Visualization of morphological transition for error discrimination is indicated. • MSCs growth rate can be predicted with high accuracy from morphological profiles. • Mishandlings in the culture process can be predicted by morphological profiles. • Unexpected malfunction of instruments can be predicted by morphological profiles. |
| Databáze: | OpenAIRE |
| Externí odkaz: |
|