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2. Reconstructing human organ cross-sectional imaging along any axis

Author

Fan, Yifang, Fan, Yubo, Luo, Liangping, Lin, Wentao, Li, Zhiyu, Zhong, Xin, Shi, Changzheng, Newman, Tony, Zhou, Yi, Lv, Changsheng, and Fan, Yuzhou

Subjects
Physics - Medical Physics
Abstract

Cross-sectional imaging of human organ serves as a critical tool to provide diagnostic results of many diseases. Based on a unique body coordinate system, we present a method that we use to reconstruct any cross-sectional imaging of organ regardless of its original section going along which scanning or cutting axis. In clinical medicine, this method enables a patient to undergo only one scanning, and then the doctor can observe the structure of lesion sections along any axis, and it can help find changes of lesions at the same section from different scanning results and thus quantify diagnosis by cross-sectional imaging. Significant progress has thus been made towards quantitative diagnosis cross-sectional imaging., Comment: 8 pages, 4 figures. If you need any supporting materials (Movie (any section along any axis).swf), please contact us at tfyf@gipe.edu.cn

Published
2014

3. Three-Dimensional Reconstruction of Erythrocyte in the Capillary

Author

Fan, Yifang, Fan, Yubo, Li, Zhiyu, Lin, Wentao, Wei, Yuan, Zhong, Xing, Newman, Tony, Lv, Changsheng, and Fan, Yuzhou

Subjects
Physics - Medical Physics
Abstract

The dynamic analysis of erythrocyte deformability is used as an important means for early diagnosis of blood diseases and blood rheology. Yet no effective method is available in terms of three-dimensional reconstruction of erythrocytes in a capillary. In this study, ultrathin serial sections of skeletal muscle tissue are obtained from the ultramicrotome, the tomographic images of an erythrocyte in a capillary are captured by the transmission electron microscope, and then a method to position and restore is devised to demonstrate the physiological relationship between two adjacent tomographic images of an erythrocyte. Both the modeling and the physical verification reveal that this method is effective, which means that it can be used to make three-dimensional reconstruction of an erythrocyte in a capillary. An example of reconstructed deformation of erythrocyte based on the serial ultrathin sections is shown at the end of this paper., Comment: 6 pages, 3 figures

Published
2013

6. The Role of Footwear in the Pathogenesis of Hallux Valgus: A Proof-of-Concept Finite Element Analysis in Recent Humans and Homo naledi

Author

Yu, Genyu, Fan, Yuzhou, Fan, Yuxuan, Li, Ruining, Liu, Yaming, Antonijević, Đorđe, Milovanović, Petar, Zhang, Bo, Li, Zhiyu, Đurić, Marija, Fan, Yifang, Yu, Genyu, Fan, Yuzhou, Fan, Yuxuan, Li, Ruining, Liu, Yaming, Antonijević, Đorđe, Milovanović, Petar, Zhang, Bo, Li, Zhiyu, Đurić, Marija, and Fan, Yifang

Abstract

Hallux valgus (HV), the bunion of the first metatarsophalangeal joint (MTPJ), bothers many adults. No consensus has been reached about the causes of HV, be it a hereditary, or acquired, or multifactorial disease. Nor has agreement been reached using MTPJ angle to assess HV based on X-ray because in most cases the assessment of MTPJ is not reliable as it depends on the posture during scanning. In this study, we assume that HV is predominately acquired and that shoe wearing per se is an important player in HV pathogenesis. To verify our hypothesis, a CT-based finite element (FE) model of the first MTPJ of fossil remains of bear-footed Homo naledi was created and compared to that of five contemporary shoe-wearing wrestlers (10 models from two scans at an interval of about 18 months) because Homo naledi's first MTPJ is an ideal model for non-shoe wearing with parallel sesamoid grooves. We developed the first MTPJ structure transformation method and created MTPJ joint capsule model for both Homo naledi and wrestlers. Constraint on the medial side of the first MTPJ capsule was set to simulate shoe-wearing conditions compared to the lack of medial constraint for barefooted conditions. Analysis of eight FE models of different angles for the first MTPJ of Homo naledi was performed by the first MTPJ transformation method and results showed that stress concentrated on the medial capsule of the first MTPJ in simulated shoe-wearing conditions, even at MTPJ angle of 0°. Increase in the first MTPJ angle further increased stress concentration on the medial side, and stress-growth relationship might reveal the causes of HV. We further developed a method to position the first MTPJ in wrestlers and created CT-based models at two time points. It was evident that the first MTPJ angle increased in all but one athlete, with a maximal increase of 4.03 degrees. This verifies our hypothesis that HV might be developed by wearing shoes. Further longitudinal studies with larger sample sizes are

Published
2020

8. A multi-pronged investigation into the effect of glucose starvation and culture duration on fed-batch CHO cell culture

Author

Fan, Yuzhou, Jimenez Del Val, Ioscani, Müller, Christian, Lund, Anne Mathilde, Wagtberg Sen, Jette, Rasmussen, Søren Kofoed, Kontoravdi, Cleo, Baycin-Hizal, Deniz, Betenbaugh, Michael J., Weilguny, Dietmar, and Andersen, Mikael Rørdam

Subjects
carbohydrates (lipids), Monoclonal antibody, Proteomics, Culture duration, Glycosylation, Fed-batch, Chinese hamster ovary cells, Glucose starvation
Abstract

In this study, omics-based analysis tools were used to explore the effect of glucose starvation and culture duration on monoclonal antibody (mAb) production in fed-batch CHO cell culture to gain better insight into how these parameters can be controlled to ensure optimal mAb productivity and quality. Titer and N-glycosylation of mAbs, as well as proteomic signature and metabolic status of the production cells in the culture were assessed. We found that the impact of glucose starvation on the titer and N-glycosylation of mAbs was dependent on the degree of starvation during early stationary phase of the fed-batch culture. Higher degree of glucose starvation reduced intracellular concentrations of UDP-GlcNAc and UDP-GalNAc, but increased the levels of UDP-Glc and UDP-Gal. Increased GlcNAc and Gal occupancy correlated well with increased degree of glucose starvation, which can be attributed to the interplay between the dilution effect associated with change in specific productivity of mAbs and the changed nucleotide sugar metabolism. Herein, we also show and discuss that increased cell culture duration negatively affect the maturation of glycans. In addition, comparative proteomics analysis of cells was conducted to observe differences in protein abundance between early growth and early stationary phases. Generally higher expression of proteins involved in regulating cellular metabolism, extracellular matrix, apoptosis, protein secretion and glycosylation was found in early stationary phase. These analyses offered a systematic view of the intrinsic properties of these cells and allowed us to explore the root causes correlating culture duration with variations in the productivity and glycosylation quality of monoclonal antibodies produced with CHO cells.

Published
2015
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9. N-Glycosylation optimization of recombinant antibodies in CHO cell through process and metabolic engineering

Author

Fan, Yuzhou

Abstract

Takket være nylige fremskridt inden for den "omic" revolution af Chinese hamster ovary (CHO) celler, er udvikling og produktion af rekombinante terapeutiske proteiner i CHO cellefabrikker begyndt at blive præget med afsæt i systembiologi. En holistisk forståelse af titer og N-glykosylering af et produceret rekombinant protein i forhold til den tilknyttede celle kultiverings proces, samt en genomisk, proteomisk, metabolisk og fysiologisk forståelse, vise sig at være yderst effektiv når der samtidig er fokus på sikkerhed, effektivitet og pris, af det enkelte protein. Ved at kombinere og sammensætte viden indenfor CHO celle kultiverings teknologi, upstream proces udvikling, metabolisk optimering, og glyco-biologi, til et systematisk framework med fokus på kvalitet og kvantitet, kan produktionen af rekombinante terapeutiske proteiner blive optimeret.I det præsenterede arbejde er det seneste know-how indenfor analyse, kontrol og optimering af N-glykosylering, samt indflydelsen af N-glykosylering på terapeutiske proteiner, blevet grundigt revideret og analyseret. Mere specifikt er det blevet undersøgt hvordan man kan kontrollere og optimere N-glykosylering i CHO celler. Hoved fokus i dette PhD projekt har været at udvikle effektive metoder til modelering af N-glycosylering af CHO-producerede recombinante monoklonale antistoffer (mAb), således at ønskede glycosylerings mønstre kan opnåes, samtidig med at udvide forståelsen for de dybere mekanismer der styrer N-glycosylering set fra et systembiologisk perspektiv. To forskellige strategier blev brugt til at glyko-optimere med stor succes: 1) optimering af medie og kultiverings processer; 2) genetisk forbedring af CHO som cellefabrik.I den første del af tesen, er den første strategi demonstreret af flere successfulde case-studies, hvor process- og medieoptimering blev brugt til at styre N-glykosyleringen. Balancen mellem glukose- og aminosyremetabolismen blev kontrolleret ved at bruge galaktose som feed additiv og ved at ændre process parametre såsom udsåningstætheden og længden af kultiveringen. Ved at kontrollere balancen mellem glukose- og aminosyremetabolismen, kunne N-glycosyleringen påvirkes. Der er flere forklaringer på, hvorfor denne balance styrer glykosyleringen, herunder mekanismer associeret med produktion, metabolisme, proteomet, og fysiologi.I den anden del af tesen bliver både literaturen og eksperimentelle applikationer undersøgt, for at demonstrere hvorledes omics data og implementering af systembiologi kan udnyttes til at forstår biologiske mekanismer, herunder N-glycosylering i CHO celler.I den tredje og sidste del af tesen, bliver den anden strategi demonstreret. Lovende resultater viser at det er muligt at optimere N-glykosylering ved at modificere genetikken og metabolismen i CHO celler. Ved at overudtrykke enten N-acetylglucosaminyltransferase I (GnTI) proteiner kunne GlcNAc tilgængeligheden øges, med en medfølgende forbedring af matureringen af glykaner i mAbs.Resultaterne demonstrerer integrationen af systembiologi koncepter og process- og metabolisme modifikationer, som en effektiv måde hvorved N-glykosylering af CHO-producerede rekombinante terapeutiske proteiner kan kontrolleres og optimeres. Thanks to the recent advances in Chinese hamster ovary (CHO) “omic” revolution, the development of recombinant therapeutic protein bioprocessing using CHO cell factory started to merge with the new biological mindset called systems biology. In order to produce a CHO-derived recombinant therapeutic protein with ensured safety, efficacy and cost-effectiveness, holistic understanding of titer and N-glycosylation of the protein in relation to cell culture process as well as genomic, proteomic, metabolic and physiological status of the cells becomes a superior approach. Combining the knowledge of CHO cell culture technology, upstream process engineering, metabolic engineering, and glycobiology into a systematic framework allow us to improve the production of recombinant therapeutic protein towards an optimal balance between quantity and quality.In the presented work, recent know-how on impact, analysis, control and optimization of N-glycosylation were thoroughly reviewed. In particular, how to control and optimize N-glycosylation in CHO cells was exclusively studied. The main focus of this PhD project is to find effective approaches of modulating N-glycosylation of CHO-derived recombinant monoclonal antibody (mAb) towards desired patterns, and at the same time try to understand the underlying mechanisms of that from a systems biology perspective. Two different strategies were used and achieved great success in glyco-optimization: 1) optimize media and culture process; 2) Genetically optimize CHO cell factory.In the early part of the thesis, the first strategy was displayed by a number of successful case studies, in which process and media engineering approach was successfully used to direct N-glycosylation. Controlling the balance between glucose and amino acid metabolism, using galactose as feed additives, changing process parameters such as seeding density and cultivation duration are all demonstrated to be effective. The causal explanation of their impact on glycosylation can be various, including product, metabolism, proteome and physiology-associated mechanism.In the middle part of the thesis, both literature reviews and experimental applications were provided to demonstrate how to use omics data and implement systems biology to understand biological activities, especially N-glycosylation in CHO cells.In the last part of the thesis, the second strategy that apply genetic and metabolic engineering approach to improve N-glycosylation capability of CHO cells was also presented promising results. Overexpression of either N-acetylglucosaminyltransferase I (GnTI) in CHO cells was confirmed to improve the maturation of glycans in mAb.In conclusion, integrating the concept of systems biology with process and metabolic engineering has been demonstrated through a number of studies to be a superior way of controlling and optimizing N-glycosylation of CHO-derived recombinant therapeutic protein.

Published
2015

11. Dynamics of immature mAb glycoform secretion during CHO cell culture:An integrated modelling framework

Author

Jimenez del Val, Ioscani, Fan, Yuzhou, Weilguny, Dietmar, Jimenez del Val, Ioscani, Fan, Yuzhou, and Weilguny, Dietmar

Abstract

Ensuring consistent glycosylation-associated quality of therapeutic monoclonal antibodies (mAbs) has become a priority in pharmaceutical bioprocessing given that the distribution and composition of the carbohydrates (glycans) bound to these molecules determines their therapeutic efficacy and immunogenicity. However, the interaction between bioprocess conditions, cellular metabolism and the intracellular process of glycosylation remains to be fully understood. To gain further insight into these interactions, we present a novel integrated modelling platform that links dynamic variations in mAb glycosylation with cellular secretory capacity. Two alternative mechanistic representations of how mAb specific productivity (qp) influences glycosylation are compared. In the first, mAb glycosylation is modulated by the linear velocity with which secretory cargo traverses the Golgi apparatus. In the second, glycosylation is influenced by variations in Golgi volume. Within our modelling framework, both mechanisms accurately reproduce experimentally-observed dynamic changes in mAb glycosylation. In addition, an optimisation-based strategy has been developed to estimate the concentration of glycosylation enzymes required to minimise mAb glycoform variability. Our results suggest that the availability of glycosylation machinery relative to cellular secretory capacity may play a crucial role in mAb glycosylation. In the future, the modelling framework presented here may aid in selecting and engineering cell lines that ensure consistent mAb glycosylatio.

Published
2016

12. Trends and approaches in N-Glycosylation engineering in Chinese hamster ovary cell culture

Author

Fan, Yuzhou, Kildegaard, Helene Faustrup, Andersen, Mikael Rørdam, Fan, Yuzhou, Kildegaard, Helene Faustrup, and Andersen, Mikael Rørdam

Abstract

Chinese hamster ovary (CHO) cells have become the preferred expression system for the production of complex recombinantglycoproteins. It has been historically successful in industrial scale-up application and in generating human-like protein glycosylation.N-glycosylation of recombinant proteins, in particular, of those as drug substances, is extremely concerned in drug development andapproval, as it will largely affect their stability, efficacy, clearance rate and immunogenicity. Therefore to engineering N-glycosylationof CHO cell-derived recombinant proteins are extremely important. Here, we will summarize a group of recent strategies andapproaches and come up with case studies for N-glycosylation engineering in CHO cells and show several examples of relevantstudy cases from our research: 1) media and feed design, 2) culture process optimization, 3) substrate addition, 4) geneticengineering, 5) omics-based characterization, 6) mathematical modelling.

Published
2016

13. Fan, Yuzhou

Author

Fan, Yuzhou and Fan, Yuzhou

Published
2012

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