Your search keyword '"Ortis, Morgane"' showing total 5 results

1. Microbiote oral et santé bucco-dentaire des sportifs : revue narrative

Author

Dubois, Margaux, Ortis, Morgane, Doglio, Alain, and Bougault, Valérie

Published

2024

2. Centrifugal Microfluidic Cell Culture Platform for Physiologically Relevant Virus Infection Studies:A Case Study with HSV-1 Infection of Periodontal Cells

Author

Christfort, Juliane Fjelrad, Ortis, Morgane, Nguyen, Hau Van, Marsault, Robert, Doglio, Alain, Christfort, Juliane Fjelrad, Ortis, Morgane, Nguyen, Hau Van, Marsault, Robert, and Doglio, Alain

Abstract

Static well plates remain the gold standard to study viral infections in vitro, but they cannot accurately mimic dynamic viral infections as they occur in the human body. Therefore, we established a dynamic cell culture platform, based on centrifugal microfluidics, to study viral infections in perfusion. To do so, we used human primary periodontal dental ligament (PDL) cells and herpes simplex virus-1 (HSV-1) as a case study. By microscopy, we confirmed that the PDL cells efficiently attached and grew in the chip. Successful dynamic viral infection of perfused PDL cells was monitored using fluorescent imaging and RT-qPCR-based experiments. Remarkably, viral infection in flow resulted in a gradient of HSV-1-infected cells gradually decreasing from the cell culture chamber entrance towards its end. The perfusion of acyclovir in the chip prevented HSV-1 spreading, demonstrating the usefulness of such a platform for monitoring the effects of antiviral drugs. In addition, the innate antiviral response of PDL cells, measured by interferon gene expression, increased significantly over time in conventional static conditions compared to the perfusion model. These results provide evidence suggesting that dynamic viral infections differ from conventional static infections, which highlights the need for more physiologically relevant in vitro models to study viral infections.

Published

2024

3. Herpes Simplex Virus Type 1 Infection of Human Periodontal Ligament.

Author

Ortis, Morgane, Chevalier, Marlène, Olivieri, Charles-Vivien, Vitale, Sébastien, Paul, Adrien, Tonoyan, Lilit, Doglio, Alain, and Marsault, Robert

Subjects

*HUMAN herpesvirus 1, *PERIODONTAL ligament, *CONNECTIVE tissues, *ALVEOLAR process, *VIRUS diseases

Abstract

The periodontal ligament (PDL) is a complex connective tissue that connects the tooth root to the dental alveolar bone and plays crucial mechanical roles. PDL also exhibits regenerative roles and regulatory functions to maintain periodontium integrity and homeostasis. While PDL exposure to oral microbial pathogens is common, virtually nothing is known regarding viral infections of PDL. In particular, human herpes simplex virus type 1 (HSV-1) persistently infects the oral cavity through infections of the oral epithelium, connective tissue and neurons. While the oral spread of HSV-1 is generally asymptomatic, this virus has also been implicated in various oral pathologies. In this study, using a primary cell model derived from PDL (PDL cells), and whole surgical fragments of PDL, we provide evidence supporting the efficient infection of PDL by HSV-1 and the promotion of cytopathic effects. Infection of PDL by HSV-1 was also associated with an acute innate inflammatory response, as illustrated by the production of antiviral interferons and pro-inflammatory cytokines. Furthermore, this inflammatory response to HSV-1 was exacerbated in the presence of bacterial-derived products, such as peptidoglycans. This work therefore highlights the ability of HSV-1 to infect mesenchymal cells from PDL, suggesting that PDL may serve as a viral reservoir for the periodontal spread of HSV-1. Moreover, this raises questions about HSV-1 oral pathogenesis, as HSV-1-associated cytopathic and inflammatory effects may contribute to profound alterations of PDL integrity and functioning. [ABSTRACT FROM AUTHOR]

Published

2024

4. Centrifugal Microfluidic Cell Culture Platform for Physiologically Relevant Virus Infection Studies: A Case Study with HSV-1 Infection of Periodontal Cells.

Author

Christfort, Juliane Fjelrad, Ortis, Morgane, Nguyen, Hau Van, Marsault, Robert, and Doglio, Alain

Subjects

HUMAN herpesvirus 1, VIRUS diseases, PERIODONTAL ligament, MICROPHYSIOLOGICAL systems, CELL culture

Abstract

Static well plates remain the gold standard to study viral infections in vitro, but they cannot accurately mimic dynamic viral infections as they occur in the human body. Therefore, we established a dynamic cell culture platform, based on centrifugal microfluidics, to study viral infections in perfusion. To do so, we used human primary periodontal dental ligament (PDL) cells and herpes simplex virus-1 (HSV-1) as a case study. By microscopy, we confirmed that the PDL cells efficiently attached and grew in the chip. Successful dynamic viral infection of perfused PDL cells was monitored using fluorescent imaging and RT-qPCR-based experiments. Remarkably, viral infection in flow resulted in a gradient of HSV-1-infected cells gradually decreasing from the cell culture chamber entrance towards its end. The perfusion of acyclovir in the chip prevented HSV-1 spreading, demonstrating the usefulness of such a platform for monitoring the effects of antiviral drugs. In addition, the innate antiviral response of PDL cells, measured by interferon gene expression, increased significantly over time in conventional static conditions compared to the perfusion model. These results provide evidence suggesting that dynamic viral infections differ from conventional static infections, which highlights the need for more physiologically relevant in vitro models to study viral infections. [ABSTRACT FROM AUTHOR]

Published

2024

5. Dynamic in vitro cell culture model to study pathogenic interactions in periodontitis in flow using a Lab-on-a-Disc platform

Author

Christfort, Juliane Fjelrad, Ortis, Morgane, Nguyen, Hau Van, Zor, Kinga, Boisen, Anja, Doglio, Alain, Marsault, Robert, Christfort, Juliane Fjelrad, Ortis, Morgane, Nguyen, Hau Van, Zor, Kinga, Boisen, Anja, Doglio, Alain, and Marsault, Robert

Abstract

Periodontitis is one of the most common chronic inflammatory diseases worldwide [1]. Recently, the overgrowth of human herpes viruses (HHVs), including herpes simplex virus type 1 (HSV-1), has been suggested as a possible trigger for oral dysbiosis resulting in the progression of periodontitis [2]. Thus, there is a demand for in vitro platforms to facilitate studies of the interactions between oral cells (e.g. epithelial cells and fibroblasts) and HHVs in conditions mimicking the oral cavity to enable a better understanding of fundamental biological processes and evaluate new treatment strategies. Traditionally, viral infections are studied in cells cultured in static conditions, e.g. well plates. However, different methods to study cells in perfusion have received increasing attention [3, 4, 5]. A recently established methodology to study cell growth under perfusion in vitro is based on the Lab-on-a-Disc (LoD) [6] technology. LoD is a disc-shaped microfluidic platform the size of a DVD, where centrifugal forces are used to manipulate fluids through channels and chambers [6]. Compared to conventional perfusion systems, LoD platforms are advantageous since there are no external pumps, valves or tubings. In this work, we aim to establish a physiologically relevant LoD model to study dynamic interactions between cells isolated from the oral cavity, e.g. periodontal ligament (PDL) cells, and HHVs as it may occur in periodontitis.

Published

2023