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1.
Int J Mol Sci ; 22(8)2021 Apr 15.
Article in English | MEDLINE | ID: mdl-33921088

ABSTRACT

Novel nanomedicines have been engineered to deliver molecules with therapeutic potentials, overcoming drawbacks such as poor solubility, toxicity or short half-life. Lipid-based carriers such as liposomes represent one of the most advanced classes of drug delivery systems. A Monomethyl Auristatin E (MMAE) warhead was grafted on a lipid derivative and integrated in fusogenic liposomes, following the model of antibody drug conjugates. By modulating the liposome composition, we designed a set of particles characterized by different membrane fluidities as a key parameter to obtain selective uptake from fibroblast or prostate tumor cells. Only the fluid liposomes made of palmitoyl-oleoyl-phosphatidylcholine and dioleoyl-phosphatidylethanolamine, integrating the MMAE-lipid derivative, showed an effect on prostate tumor PC-3 and LNCaP cell viability. On the other hand, they exhibited negligible effects on the fibroblast NIH-3T3 cells, which only interacted with rigid liposomes. Therefore, fluid liposomes grafted with MMAE represent an interesting example of drug carriers, as they can be easily engineered to promote liposome fusion with the target membrane and ensure drug selectivity.


Subject(s)
Oligopeptides/pharmacology , Prostatic Neoplasms/pathology , Animals , Cell Line, Tumor , Cell Survival/drug effects , Humans , Liposomes , Male , Membrane Fluidity/drug effects , Mice , NIH 3T3 Cells , Particle Size , Time Factors , Triglycerides/chemistry
2.
BMC Biotechnol ; 15: 31, 2015 May 16.
Article in English | MEDLINE | ID: mdl-25981500

ABSTRACT

BACKGROUND: Each year, influenza is responsible for hundreds of thousand cases of illness and deaths worldwide. Due to the virus' fast mutation rate, the World Health Organization (WHO) is constantly on alert to rapidly respond to emerging pandemic strains. Although anti-viral therapies exist, the most proficient way to stop the spread of disease is through vaccination. The majority of influenza vaccines on the market are produced in embryonic hen's eggs and are composed of purified viral antigens from inactivated whole virus. This manufacturing system, however, is limited in its production capacity. Cell culture produced vaccines have been proposed for their potential to overcome the problems associated with egg-based production. Virus-like particles (VLPs) of influenza virus are promising candidate vaccines under consideration by both academic and industry researchers. METHODS: In this study, VLPs were produced in HEK293 suspension cells using the Bacmam transduction system and Sf9 cells using the baculovirus infection system. The proposed systems were assessed for their ability to produce influenza VLPs composed of Hemagglutinin (HA), Neuraminidase (NA) and Matrix Protein (M1) and compared through the lens of bioprocessing by highlighting baseline production yields and bioactivity. VLPs from both systems were characterized using available influenza quantification techniques, such as single radial immunodiffusion assay (SRID), HA assay, western blot and negative staining transmission electron microscopy (NSTEM) to quantify total particles. RESULTS: For the HEK293 production system, VLPs were found to be associated with the cell pellet in addition to those released in the supernatant. Sf9 cells produced 35 times more VLPs than HEK293 cells. Sf9-VLPs had higher total HA activity and were generally more homogeneous in morphology and size. However, Sf9 VLP samples contained 20 times more baculovirus than VLPs, whereas 293 VLPs were produced along with vesicles. CONCLUSIONS: This study highlights key production hurdles that must be overcome in both expression platforms, namely the presence of contaminants and the ensuing quantification challenges, and brings up the question of what truly constitutes an influenza VLP candidate vaccine.


Subject(s)
Antigens, Viral/chemistry , Antigens, Viral/metabolism , Influenza Vaccines/chemistry , Influenza Vaccines/metabolism , Virion/chemistry , Virion/metabolism , Animals , Antigens, Viral/genetics , Antigens, Viral/isolation & purification , HEK293 Cells , Humans , Influenza Vaccines/genetics , Influenza Vaccines/isolation & purification , Neuraminidase/chemistry , Neuraminidase/genetics , Neuraminidase/isolation & purification , Neuraminidase/metabolism , Sf9 Cells , Viral Matrix Proteins/chemistry , Viral Matrix Proteins/genetics , Viral Matrix Proteins/isolation & purification , Viral Matrix Proteins/metabolism , Viral Proteins/chemistry , Viral Proteins/genetics , Viral Proteins/isolation & purification , Viral Proteins/metabolism , Virion/genetics , Virion/isolation & purification
3.
J Mech Behav Biomed Mater ; 159: 106696, 2024 Nov.
Article in English | MEDLINE | ID: mdl-39205347

ABSTRACT

Bioprinted hydrogels are extensively studied to provide an artificial matrix for 3D cell culture. The success of bioprinting hydrogels relies on fine-tuning their rheology and composition to achieve shear-thinning behavior. However, a challenge arises from the limited viscoelastic and stiffness range accessible from a single hydrogel formulation. Nevertheless, hydrogel mechanical properties are recognized as essential cues influencing cell phenotype, migration, and differentiation. Thus, it is crucial to develop a system to easily modulate bioprinted hydrogels' mechanical behaviors. In this work, we modulated the viscoelastic properties and stiffness of bioprinted hydrogels composed of fibrinogen, alginate, and gelatin by tuning the crosslinking bath solution. Various concentrations of calcium ionically crosslinked alginate, while transglutaminase crosslinked gelatin. Subsequently, we characterized the mechanical behavior of our bioprinted hydrogels from the nanoscale to the macroscale. This approach enabled the production of diverse bioprinted constructs, either with similar elastic behavior but different elastic moduli or with similar elastic moduli but different viscoelastic behavior from the same hydrogel formulation. Culturing fibroblasts in the hydrogels for 33 days revealed a preference for cell growth and matrix secretion in the viscoelastic hydrogels. This work demonstrates the suitability of the method to decouple the effects of material mechanical from biochemical composition cues on 3D cultured cells.


Subject(s)
Bioprinting , Elasticity , Hydrogels , Hydrogels/chemistry , Viscosity , Animals , Alginates/chemistry , Mice , Cell Culture Techniques, Three Dimensional , Cell Culture Techniques , Fibroblasts/cytology , Fibroblasts/drug effects
4.
Sci Rep ; 14(1): 11003, 2024 05 14.
Article in English | MEDLINE | ID: mdl-38744985

ABSTRACT

The future of organ and tissue biofabrication strongly relies on 3D bioprinting technologies. However, maintaining sterility remains a critical issue regardless of the technology used. This challenge becomes even more pronounced when the volume of bioprinted objects approaches organ dimensions. Here, we introduce a novel device called the Flexible Unique Generator Unit (FUGU), which is a unique combination of flexible silicone membranes and solid components made of stainless steel. Alternatively, the solid components can also be made of 3D printed medical-grade polycarbonate. The FUGU is designed to support micro-extrusion needle insertion and removal, internal volume adjustment, and fluid management. The FUGU was assessed in various environments, ranging from custom-built basic cartesian to sophisticated 6-axis robotic arm bioprinters, demonstrating its compatibility, flexibility, and universality across different bioprinting platforms. Sterility assays conducted under various infection scenarios highlight the FUGU's ability to physically protect the internal volume against contaminations, thereby ensuring the integrity of the bioprinted constructs. The FUGU also enabled bioprinting and cultivation of a 14.5 cm3 human colorectal cancer tissue model within a completely confined and sterile environment, while allowing for the exchange of gases with the external environment. This FUGU system represents a significant advancement in 3D bioprinting and biofabrication, paving the path toward the sterile production of implantable tissues and organs.


Subject(s)
Bioprinting , Bioreactors , Printing, Three-Dimensional , Bioprinting/methods , Humans , Tissue Engineering/methods , Sterilization , Tissue Scaffolds
5.
Biochimie ; 2024 Jul 31.
Article in English | MEDLINE | ID: mdl-39094823

ABSTRACT

To ensure selective targeting based on membrane fluidity and physico-chemical compatibility between the biological membrane of the target cell and the lipid membrane of the liposomes carriers. Lipid-based carriers as liposomes with varying membrane fluidities were designed for delivering vincristine, an anti-tumor compound derived from Madagascar's periwinkle. Liposomes, loaded with vincristine, were tested on prostate, colon, and breast cancer cell lines alongside non-tumor controls. Results showed that vincristine-loaded liposomes with fluid membranes significantly decreased the viability of cancer cell lines compared to controls. Confocal microscopy revealed the intracellular release of vincristine, evidenced by disrupted mitosis-specific labeling of actin filaments in metastatic prostate cell lines. This highlights the crucial role of membrane fluidity in the development of lipid-based drug carriers, offering a promising and cost-effective option for targeting cancer cells as an alternative to conventional strategies.

6.
Front Oncol ; 14: 1384499, 2024.
Article in English | MEDLINE | ID: mdl-39091906

ABSTRACT

The oncolytic virus represents a promising therapeutic strategy involving the targeted replication of viruses to eliminate cancer cells, while preserving healthy ones. Despite ongoing clinical trials, this approach encounters significant challenges. This study delves into the interaction between an oncolytic virus and extracellular matrix mimics (ECM mimics). A three-dimensional colorectal cancer model, enriched with ECM mimics through bioprinting, was subjected to infection by an oncolytic virus derived from the vaccinia virus (oVV). The investigation revealed prolonged expression and sustained oVV production. However, the absence of a significant antitumor effect suggested that the virus's progression toward non-infected tumoral clusters was hindered by the ECM mimics. Effective elimination of tumoral cells was achieved by introducing an oVV expressing FCU1 (an enzyme converting the prodrug 5-FC into the chemotherapeutic compound 5-FU) alongside 5-FC. Notably, this efficacy was absent when using a non-replicative vaccinia virus expressing FCU1. Our findings underscore then the crucial role of oVV proliferation in a complex ECM mimics. Its proliferation facilitates payload expression and generates a bystander effect to eradicate tumors. Additionally, this study emphasizes the utility of 3D bioprinting for assessing ECM mimics impact on oVV and demonstrates how enhancing oVV capabilities allows overcoming these barriers. This showcases the potential of 3D bioprinting technology in designing purpose-fit models for such investigations.

7.
J Invest Dermatol ; 2024 Aug 09.
Article in English | MEDLINE | ID: mdl-39127929

ABSTRACT

Skin in vitro models offer much promise for research, testing drugs, cosmetics, and medical devices, reducing animal testing and extensive clinical trials. There are several in vitro approaches to mimicking human skin behavior, ranging from simple cell monolayer to complex organotypic and bioengineered 3-dimensional models. Some have been approved for preclinical studies in cosmetics, pharmaceuticals, and chemicals. However, development of physiologically reliable in vitro human skin models remains in its infancy. This review reports on advances in in vitro complex skin models to study skin homeostasis, aging, and skin disease.

8.
Virol J ; 10: 141, 2013 May 04.
Article in English | MEDLINE | ID: mdl-23642219

ABSTRACT

Influenza virus-like particle vaccines are one of the most promising ways to respond to the threat of future influenza pandemics. VLPs are composed of viral antigens but lack nucleic acids making them non-infectious which limit the risk of recombination with wild-type strains. By taking advantage of the advancements in cell culture technologies, the process from strain identification to manufacturing has the potential to be completed rapidly and easily at large scales. After closely reviewing the current research done on influenza VLPs, it is evident that the development of quantification methods has been consistently overlooked. VLP quantification at all stages of the production process has been left to rely on current influenza quantification methods (i.e. Hemagglutination assay (HA), Single Radial Immunodiffusion assay (SRID), NA enzymatic activity assays, Western blot, Electron Microscopy). These are analytical methods developed decades ago for influenza virions and final bulk influenza vaccines. Although these methods are time-consuming and cumbersome they have been sufficient for the characterization of final purified material. Nevertheless, these analytical methods are impractical for in-line process monitoring because VLP concentration in crude samples generally falls out of the range of detection for these methods. This consequently impedes the development of robust influenza-VLP production and purification processes. Thus, development of functional process analytical techniques, applicable at every stage during production, that are compatible with different production platforms is in great need to assess, optimize and exploit the full potential of novel manufacturing platforms.


Subject(s)
Antigens, Viral/analysis , Biotechnology/standards , Influenza Vaccines/immunology , Influenza Vaccines/isolation & purification , Technology, Pharmaceutical/standards , Vaccines, Virus-Like Particle/immunology , Vaccines, Virus-Like Particle/isolation & purification , Humans , Influenza Vaccines/genetics , Influenza Vaccines/standards , Vaccines, Virus-Like Particle/genetics , Vaccines, Virus-Like Particle/standards
9.
Biotechnol Adv ; 68: 108211, 2023 11.
Article in English | MEDLINE | ID: mdl-37463610

ABSTRACT

Various research fields use the transfection of mammalian cells with genetic material to induce the expression of a target transgene or gene silencing. It is a tool widely used in biological research, bioproduction, and therapy. Current transfection protocols are usually performed on 2D adherent cells or suspension cultures. The important rise of new gene therapies and regenerative medicine in the last decade raises the need for new tools to empower the in situ transfection of tissues and 3D cell cultures. This review will present novel in situ transfection methods based on a chemical or physical non-viral transfection of cells in tissues and 3D cultures, discuss the advantages and remaining gaps, and propose future developments and applications.


Subject(s)
Genetic Therapy , Tissue Engineering , Animals , Tissue Engineering/methods , Transfection , Transgenes , Cell Culture Techniques, Three Dimensional , Mammals
10.
Pharmaceutics ; 15(12)2023 Dec 07.
Article in English | MEDLINE | ID: mdl-38140081

ABSTRACT

Nanomedicines engineered to deliver molecules with therapeutic potentials, overcoming drawbacks such as poor solubility, toxicity or a short half-life, are targeted towards their cellular destination either passively or through various elements of cell membranes. The differences in the physicochemical properties of the cell membrane between tumor and nontumor cells have been reported, but they are not systematically used for drug delivery purposes. Thus, in this study, a new approach based on a match between the liposome compositions, i.e., membrane fluidity, to selectively interact with the targeted cell membrane was used. Lipid-based carriers of two different fluidities were designed and used to deliver 4(RS)-4-F4t-Neuroprostane (F4t-NeuroP), a potential antitumor molecule derived from docosahexaenoic acid (DHA). Based on its hydrophobic character, F4t-NeuroP was added to the lipid mixture prior to liposome formation, a protocol that yielded over 80% encapsulation efficiency in both rigid and fluid liposomes. The presence of the active molecule did not modify the liposome size but increased the liposome negative charge and the liposome membrane fluidity, which suggested that the active molecule was accommodated in the lipid membrane. F4t-NeuroP integration in liposomes with a fluid character allowed for the selective targeting of the metastatic prostate cell line PC-3 vs. fibroblast controls. A significant decrease in viability (40%) was observed for the PC-3 cancer line in the presence of F4t-NeuroP fluid liposomes, whereas rigid F4t-NeuroP liposomes did not alter the PC-3 cell viability. These findings demonstrate that liposomes encapsulating F4t-NeuroP or other related molecules may be an interesting model of drug carriers based on membrane fluidity.

11.
Adv Healthc Mater ; 12(23): e2300443, 2023 09.
Article in English | MEDLINE | ID: mdl-37353904

ABSTRACT

3D bioprinting has developed tremendously in the last couple of years and enables the fabrication of simple, as well as complex, tissue models. The international space agencies have recognized the unique opportunities of these technologies for manufacturing cell and tissue models for basic research in space, in particular for investigating the effects of microgravity and cosmic radiation on different types of human tissues. In addition, bioprinting is capable of producing clinically applicable tissue grafts, and its implementation in space therefore can support the autonomous medical treatment options for astronauts in future long term and far-distant space missions. The article discusses opportunities but also challenges of operating different types of bioprinters under space conditions, mainly in microgravity. While some process steps, most of which involving the handling of liquids, are challenging under microgravity, this environment can help overcome problems such as cell sedimentation in low viscous bioinks. Hopefully, this publication will motivate more researchers to engage in the topic, with publicly available bioprinting opportunities becoming available at the International Space Station (ISS) in the imminent future.


Subject(s)
Bioprinting , Cosmic Radiation , Space Flight , Weightlessness , Humans , Printing, Three-Dimensional
12.
J Mech Behav Biomed Mater ; 134: 105365, 2022 10.
Article in English | MEDLINE | ID: mdl-35863297

ABSTRACT

Contraction assay based on surface measurement have been widely used to evaluate cell contractility in 3D models. This method is straightforward and requires no specific equipment, but it does not provide quantitative data about contraction forces generated by cells. We expanded this method with a new biomechanical model, based on the work-energy theorem, to provide non-destructive longitudinal monitoring of contraction forces generated by cells in 3D. We applied this method on hydrogels seeded with either fibroblasts or osteoblasts. Hydrogel mechanical characteristics were modulated to enhance (condition HCAHigh: hydrogel contraction assay high contraction) or limit (condition HCALow: hydrogel contraction assay low contraction) cell contractile behaviors. Macroscopic measures were further correlated with cell contractile behavior and descriptive analysis of their physiology in response to different mechanical environments. Fibroblasts and osteoblasts contracted their matrix up to 47% and 77% respectively. Contraction stress peaked at day 5 with 1.1 10-14 Pa for fibroblasts and 3.5 10-14 Pa for osteoblasts, which correlated with cell attachment and spreading. Negligible contraction was seen in HCALow. Both fibroblasts and osteoblasts expressed α-SMA contractile fibers in HCAHigh and HCALow. Failure to contract HCALow was attributed to increased cross-linking and resistance to proteolytic degradation of the hydrogel.


Subject(s)
Hydrogels , Mechanical Phenomena , Fibroblasts , Muscle Contraction
13.
BMC Biotechnol ; 11: 84, 2011 Sep 01.
Article in English | MEDLINE | ID: mdl-21884612

ABSTRACT

BACKGROUND: Cell culture-based production of influenza vaccine remains an attractive alternative to egg-based production. Short response time and high production yields are the key success factors for the broader adoption of cell culture technology for industrial manufacturing of pandemic and seasonal influenza vaccines. Recently, HEK293SF cells have been successfully used to produce influenza viruses, achieving hemagglutinin (HA) and infectious viral particle (IVP) titers in the highest ranges reported to date. In the same study, it was suggested that beyond 4 × 10(6) cells/mL, viral production was limited by a lack of nutrients or an accumulation of toxic products. RESULTS: To further improve viral titers at high cell densities, perfusion culture mode was evaluated. Productivities of both perfusion and batch culture modes were compared at an infection cell density of 6 × 10(6) cells/mL. The metabolism, including glycolysis, glutaminolysis and amino acids utilization as well as physiological indicators such as viability and apoptosis were extensively documented for the two modes of culture before and after viral infection to identify potential metabolic limitations. A 3 L bioreactor with a perfusion rate of 0.5 vol/day allowed us to reach maximal titers of 3.3 × 10(11) IVP/mL and 4.0 logHA units/mL, corresponding to a total production of 1.0 × 10(15) IVP and 7.8 logHA units after 3 days post-infection. Overall, perfusion mode titers were higher by almost one order of magnitude over the batch culture mode of production. This improvement was associated with an activation of the cell metabolism as seen by a 1.5-fold and 4-fold higher consumption rates of glucose and glutamine respectively. A shift in the viral production kinetics was also observed leading to an accumulation of more viable cells with a higher specific production and causing an increase in the total volumetric production of infectious influenza particles. CONCLUSIONS: These results confirm that the HEK293SF cell is an excellent substrate for high yield production of influenza virus. Furthermore, there is great potential in further improving the production yields through better control of the cell culture environment and viral production kinetics. Once accomplished, this cell line can be promoted as an industrial platform for cost-effective manufacturing of the influenza seasonal vaccine as well as for periods of peak demand during pandemics.


Subject(s)
Cell Culture Techniques/methods , HEK293 Cells/virology , Influenza A Virus, H1N1 Subtype/metabolism , Virion/metabolism , Virus Cultivation/methods , Amino Acids/metabolism , Animals , Apoptosis , Bioreactors/virology , Cell Line , Cell Proliferation , Cell Survival , Dogs , Glycolysis , HEK293 Cells/metabolism , Humans , Influenza A Virus, H1N1 Subtype/chemistry , Kinetics , Perfusion/methods , Temperature , Virion/chemistry
14.
Biotechnol Bioeng ; 107(1): 143-53, 2010 Sep 01.
Article in English | MEDLINE | ID: mdl-20506276

ABSTRACT

A global kinetic study of the central metabolism of Vero cells cultivated in a serum-free medium is proposed in the present work. Central metabolism including glycolysis, glutaminolysis, and tricarboxylic acid cycle (TCA) was demonstrated to be saturated by high flow rates of consumption of the two major substrates, glucose, and glutamine. Saturation was reavealed by an accumulation of metabolic intermediates and amino acids, by a high production of lactate needed to balance the redox pathway, and by a low participation of the carbon flow to the TCA cycle supply. Different culture conditions were set up to reduce the central metabolism saturation and to better balance the metabolic flow rates between lactate production and energetic pathways. From these culture conditions, substitutions of glutamine by other carbon sources, which have lower transport rates such as asparagine, or pyruvate in order to shunt the glycolysis pathway, were successful to better balance the central metabolism. As a result, an increase of the cell growth with a concomitant decrease of cell death and a better distribution of the carbon flow between TCA cycle and lactate production occurred. We also demonstrated that glutamine was a major carbon source to supply the TCA cycle in Vero cells and that a reduction of lactate production did not necessary improve the efficiency of the Vero cell metabolism. Thus, to adapt the formulation of the medium to the Vero cell needs, it is important to provide carbon substrates inducing a regulated supply of carbon in the TCA cycle either through the glycolysis or through other pathways such as glutaminolysis. Finally, this study allowed to better understand the Vero cell behavior in serum-free medium which is a valuable help for the implementation of this cell line in serum-free industrial production processes.


Subject(s)
Cell Culture Techniques/methods , Models, Biological , Proteome/metabolism , Signal Transduction/physiology , Animals , Chlorocebus aethiops , Computer Simulation , Culture Media, Serum-Free , Metabolic Clearance Rate , Vero Cells
15.
Expert Rev Vaccines ; 18(12): 1285-1300, 2019 12.
Article in English | MEDLINE | ID: mdl-31829068

ABSTRACT

Introduction: Influenza Virus-like Particles (VLPs) are one of the most promising vaccine strategies to complement traditional egg-based processes and contribute to shortening the response time when facing future pandemics. Research programs have taken advantage of the potential of this approach to produce influenza VLPs on a variety of cellular platforms, reaching the industrial level of development and recent commercialization.Area covered: This review aims to give an overview of available strategies for influenza-VLP production and their respective stages of development, from small-scale preclinical studies to large-scale industrial processes. Recent trends and fulfillments in purification schemes of influenza VLP were also reviewed with regards to quality and potency requirements that go along with influenza vaccine manufacturing.Expert opinion: In the next five years, it is expected that there will be licensing of new influenza vaccine products based on VLP strategy. Few VLP upstream processes are mature enough and close to fully complement or seriously concurrence the ovoculture process. Nevertheless, many improvements have yet to be achieved in downstream processes. In the next few years, research efforts in this field are expected to provide purification strategies and tools to achieve higher recovery yields and improve the cost-effectiveness of VLP processes.


Subject(s)
Influenza Vaccines/isolation & purification , Technology, Pharmaceutical/methods , Technology, Pharmaceutical/trends , Vaccines, Virus-Like Particle/isolation & purification , Humans , Influenza Vaccines/immunology , Vaccine Potency , Vaccines, Virus-Like Particle/immunology
16.
Vaccine ; 37(12): 1614-1621, 2019 03 14.
Article in English | MEDLINE | ID: mdl-30773402

ABSTRACT

Influenza vaccine manufacturers lack tools, whatever the involved production bioprocess (egg or cell-based), to precisely and accurately evaluate vaccine antigen content from samples. Indeed, the gold standard single-radial immunodiffusion (SRID) assay, which remains the only validated assay for the evaluation of influenza vaccine potency, is criticized by the scientific community and regulatory agencies since a decade for its high variability, lack of flexibility and low sensitivity. We hereby report an imaging surface plasmon resonance (SPRi) assay for the quantification of both inactivated vaccine influenza antigens and viral particles derived from egg- and cell-based production samples, respectively. The assay, based on fetuin-hemagglutinin interactions, presents higher reproducibility (<3%) and a greater analytical range (0.03-20 µg/mL) than SRID for bulk monovalent and trivalent vaccine and its limit of detection was evaluated to be 100 times lower than the SRID's one. Finally, viral particles production through cell culture-based bioprocess was also successfully monitored using our SPRi-based assay and a clear correlation was found between the biosensor response and total virus particle content.


Subject(s)
Hemagglutinin Glycoproteins, Influenza Virus/immunology , Immunoassay/methods , Influenza Vaccines/biosynthesis , Influenza Vaccines/immunology , Surface Plasmon Resonance/methods , Animals , Cells, Cultured , Hemagglutinin Glycoproteins, Influenza Virus/biosynthesis , Humans , Immunogenicity, Vaccine , Influenza A virus/immunology , Influenza Vaccines/standards , Influenza, Human/prevention & control , Reproducibility of Results , Sensitivity and Specificity , Vaccine Potency
17.
Vaccine ; 36(22): 3101-3111, 2018 05 24.
Article in English | MEDLINE | ID: mdl-28571695

ABSTRACT

The influenza vaccine manufacturing industry is looking for production cell lines that are easily scalable, highly permissive to multiple viruses, and more effective in term of viral productivity. One critical characteristic of such cell lines is their ability to grow in suspension, in serum free conditions and at high cell densities. Influenza virus causing severe epidemics both in human and animals is an important threat to world healthcare. The repetitive apparition of influenza pandemic outbreaks in the last 20years explains that manufacturing sector is still looking for more effective production processes to replace/supplement embryonated egg-based process. Cell-based production strategy, with a focus on avian cell lines, is one of the promising solutions. Three avian cell lines, namely duck EB66®cells (Valneva), duck AGE.CR® cells (Probiogen) and quail QOR/2E11 cells (Baxter), are now competing with traditional mammalian cell platforms (Vero and MDCK cells) used for influenza vaccine productions and are currently at advance stage of commercial development for the manufacture of influenza vaccines. The DuckCelt®-T17 cell line presented in this work is a novel avian cell line developed by Transgene. This cell line was generated from primary embryo duck cells with the constitutive expression of the duck telomerase reverse transcriptase (dTERT). The DuckCelt®-T17 cells were able to grow in batch suspension cultures and serum-free conditions up to 6.5×106cell/ml and were easily scaled from 10ml up to 3l bioreactor. In the present study, DuckCelt®-T17 cell line was tested for its abilities to produce various human, avian and porcine influenza strains. Most of the viral strains were produced at significant infectious titers (>5.8 log TCID50/ml) with optimization of the infection conditions. Human strains H1N1 and H3N2, as well as all the avian strains tested (H5N2, H7N1, H3N8, H11N9, H12N5) were the most efficiently produced with highest titre reached of 9.05 log TCID50/ml for A/Panama/2007/99 influenza H3N2. Porcine strains were also greatly rescued with titres from 4 to 7 log TCID50/ml depending of the subtypes. Interestingly, viral kinetics showed maximal titers reached at 24h post-infection for most of the strains, allowing early harvest time (Time Of Harvest: TOH). The B strains present specific production kinetics with a delay of 24h before reaching the maximal viral particle release. Process optimization on H1N1 2009 human pandemic strain allowed identifying best operating conditions for production (MOI, trypsin concentration, cell density at infection) allowing improving the production level by 2 log. Our results suggest that the DuckCelt®-T17 cell line is a very promising platform for industrial production of influenza viruses and particularly for avian viral strains.


Subject(s)
Cell Culture Techniques/methods , Cell Line , Orthomyxoviridae/growth & development , Virus Cultivation/methods , Virus Replication , Animals , Bioreactors , Ducks , Influenza A Virus, H1N1 Subtype/growth & development , Influenza A Virus, H1N1 Subtype/physiology , Influenza A Virus, H3N2 Subtype/growth & development , Influenza A Virus, H3N2 Subtype/physiology , Influenza A Virus, H3N8 Subtype/growth & development , Influenza A Virus, H3N8 Subtype/physiology , Influenza A Virus, H5N2 Subtype/growth & development , Influenza A Virus, H5N2 Subtype/physiology , Influenza A Virus, H7N1 Subtype/growth & development , Influenza A Virus, H7N1 Subtype/physiology , Influenza Vaccines , Orthomyxoviridae/physiology
18.
J Biotechnol ; 242: 19-29, 2017 Jan 20.
Article in English | MEDLINE | ID: mdl-27867077

ABSTRACT

Over the last decade industrial manufacturing of viral vaccines and viral vectors for prophylactic and therapeutic applications is experiencing a remarkable growth. Currently, the quality attributes of viral derived products are assessed only at the end-point of the production process, essentially because in-process monitoring tools are not available or not implemented at industrial scale. However, to demonstrate process reproducibility and robustness, manufacturers are strongly advised by regulatory agencies to adopt more on-line process monitoring and control. Dielectric spectroscopy has been successfully used as an excellent indicator of the cell culture state in mammalian and yeast cell systems. We previously reported the use of this technique for monitoring influenza and lentiviral productions in HEK293 cell cultures. For both viruses, multi-frequency capacitance measurements allowed not only the on-line monitoring of the production kinetics, but also the identification of the viral release time from the cells. The present study demonstrates that the same approach can be successfully exploited for the on-line monitoring of different enveloped and non-enveloped virus production kinetics in cell culture processes. The on-line monitoring multi-frequency capacitance method was assessed in human HEK293 and Sf9 insect cells expression systems, with viral productions initiated by either infection or transfection. The comparative analyses of all the data acquired indicate that the characteristic capacitance signals were highly correlated with the occurrence of viral replication phases. Furthermore the evolution of the cell dielectric properties (intracellular conductivity and membrane capacitance) were indicative of each main replication steps. In conclusion, multi-frequency capacitance has a great potential for on-line monitoring, supervision and control of viral vector production in cell culture processes.


Subject(s)
Baculoviridae/physiology , Lentivirus/physiology , Orthomyxoviridae/physiology , Animals , Baculoviridae/genetics , Baculoviridae/immunology , Bioreactors , Electric Capacitance , Environmental Monitoring/instrumentation , Environmental Monitoring/methods , Genetic Vectors , HEK293 Cells , Humans , Lentivirus/genetics , Lentivirus/immunology , Orthomyxoviridae/genetics , Orthomyxoviridae/immunology , Reproducibility of Results , Sf9 Cells , Viral Vaccines/biosynthesis , Viral Vaccines/genetics , Virology/methods , Virus Assembly/physiology , Virus Replication/physiology
19.
Vaccine ; 35(26): 3423-3430, 2017 06 08.
Article in English | MEDLINE | ID: mdl-28495315

ABSTRACT

Despite major advances in developing capacities and alternative technologies to egg-based production of influenza vaccines, responsiveness to an influenza pandemic threat is limited by the time it takes to generate a Candidate Vaccine Virus (CVV) as reported by the 2015 WHO Informal Consultation report titled "Influenza Vaccine Response during the Start of a Pandemic". In previous work, we have shown that HEK-293 cell culture in suspension and serum free medium is an efficient production platform for cell culture manufacturing of influenza candidate vaccines. This report, took advantage of, recombinant DNA technology using Reverse Genetics of influenza strains, and advances in the large-scale transfection of suspension cultured HEK-293 cells. We demonstrate the efficient generation of H1N1 with the PR8 backbone reassortant under controlled bioreactor conditions in two sequential steps (transfection/rescue and infection/production). This approach could deliver a CVV for influenza vaccine manufacturing within two-weeks, starting from HA and NA pandemic sequences. Furthermore, the scalability of the transfection technology combined with the HEK-293 platform has been extensively demonstrated at >100L scale for several biologics, including recombinant viruses. Thus, this innovative approach is better suited to rationally engineer and mass produce influenza CVV within significantly shorter timelines to enable an effective global response in pandemic situations.


Subject(s)
HEK293 Cells/virology , Influenza A Virus, H1N1 Subtype/growth & development , Reverse Genetics , Virus Cultivation , Bioreactors , Hemagglutination Inhibition Tests , Humans , Influenza Vaccines , Reassortant Viruses/growth & development , Transfection
20.
PLoS One ; 12(6): e0180314, 2017.
Article in English | MEDLINE | ID: mdl-28662134

ABSTRACT

Vaccination is the most effective course of action to prevent influenza. About 150 million doses of influenza vaccines were distributed for the 2015-2016 season in the USA alone according to the Centers for Disease Control and Prevention. Vaccine dosage is calculated based on the concentration of hemagglutinin (HA), the main surface glycoprotein expressed by influenza which varies from strain to strain. Therefore yearly-updated strain-specific antibodies and calibrating antigens are required. Preparing these quantification reagents can take up to three months and significantly slows down the release of new vaccine lots. Therefore, to circumvent the need for strain-specific sera, two anti-HA monoclonal antibodies (mAbs) against a highly conserved sequence have been produced by immunizing mice with a novel peptide-conjugate. Immunoblots demonstrate that 40 strains of influenza encompassing HA subtypes H1 to H13, as well as B strains from the Yamagata and Victoria lineage were detected when the two mAbs are combined to from a pan-HA mAb cocktail. Quantification using this pan-HA mAbs cocktail was achieved in a dot blot assay and results correlated with concentrations measured in a hemagglutination assay with a coefficient of correlation of 0.80. A competitive ELISA was also optimised with purified viral-like particles. Regardless of the quantification method used, pan-HA antibodies can be employed to accelerate process development when strain-specific antibodies are not available, and represent a valuable tool in case of pandemics. These antibodies were also expressed in CHO cells to facilitate large-scale production using bioreactor technologies which might be required to meet industrial needs for quantification reagents. Finally, a simulation model was created to predict the binding affinity of the two anti-HA antibodies to the amino acids composing the highly conserved epitope; different probabilities of interaction between a given amino acid and the antibodies might explain the affinity of each antibody against different influenza strains.


Subject(s)
Antibodies, Monoclonal/immunology , Hemagglutinin Glycoproteins, Influenza Virus/immunology , Influenza A virus/classification , Animals , Bioreactors , CHO Cells , Cricetinae , Cricetulus , Enzyme-Linked Immunosorbent Assay , HEK293 Cells , Humans , Influenza A virus/immunology , Surface Plasmon Resonance
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