A Disposable Passive Microfluidic Device for Cell Culturing

Guzzi, Francesco; Candeloro, Patrizio; Coluccio, Maria Laura; Cristiani, Costanza Maria; Parrotta, Elvira Immacolata; Scaramuzzino, Luana; Scalise, Stefania; Dattola, Elisabetta; D'Attimo, Maria Antonia; Cuda, Giovanni; Lamanna, E.; Passacatini, Lucia Carmela; Carbone, Ennio; Krühne, Ulrich; Fabrizio, E. Di; Perozziello, Gerardo

doi:10.3390/bios10030018

Cited by 13 publications

(4 citation statements)

References 60 publications

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“…For instance, future studies using the methodologies described here will allow the evaluation of the effect of candidate pharmacological agents on key pathophysiological alterations, such as those reported above. Moreover, an interesting outlook would be the implementation of our methodology with innovative and dynamic techniques of cell culture [65][66][67][68]. Additional future investigations will focus on transcriptomic and proteomic profiling for a comprehensive understanding of how genes and proteins are expressed and interconnected in the complex disease phenotype.…”

Section: Discussionmentioning

confidence: 99%

Human iPSC Modeling of Genetic Febrile Seizure Reveals Aberrant Molecular and Physiological Features Underlying an Impaired Neuronal Activity

et al. 2022

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Mutations in SCN1A gene, encoding the voltage-gated sodium channel (VGSC) NaV1.1, are widely recognized as a leading cause of genetic febrile seizures (FS), due to the decrease in the Na+ current density, mainly affecting the inhibitory neuronal transmission. Here, we generated induced pluripotent stem cells (iPSCs)-derived neurons (idNs) from a patient belonging to a genetically well-characterized Italian family, carrying the c.434T>C mutation in SCN1A gene (hereafter SCN1AM145T). A side-by-side comparison of diseased and healthy idNs revealed an overall maturation delay of SCN1AM145T cells. Membranes isolated from both diseased and control idNs were injected into Xenopus oocytes and both GABA and AMPA currents were successfully recorded. Patch-clamp measurements on idNs revealed depolarized action potential for SCN1AM145T, suggesting a reduced excitability. Expression analyses of VGSCs and chloride co-transporters NKCC1 and KCC2 showed a cellular “dysmaturity” of mutated idNs, strengthened by the high expression of SCN3A, a more fetal-like VGSC isoform, and a high NKCC1/KCC2 ratio, in mutated cells. Overall, we provide strong evidence for an intrinsic cellular immaturity, underscoring the role of mutant NaV1.1 in the development of FS. Furthermore, our data are strengthening previous findings obtained using transfected cells and recordings on human slices, demonstrating that diseased idNs represent a powerful tool for personalized therapy and ex vivo drug screening for human epileptic disorders.

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Section: Discussionmentioning

confidence: 99%

Human iPSC Modeling of Genetic Febrile Seizure Reveals Aberrant Molecular and Physiological Features Underlying an Impaired Neuronal Activity

et al. 2022

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“…Because it is easy to manipulate, it is a suitable material for the fabrication of microfluidic devices ( Horowitz et al, 2020 ; Persson et al, 2022 ; Madadi et al, 2023 ; Zolti et al, 2023 ). PMMA is also biocompatible and can be sterilized easily by various sterilization methods, such as autoclaving ( Guzzi et al, 2020 ; Khot et al, 2020 ) and chemical sterilization ( Nguyen et al, 2019 ; Ameri et al, 2022 ), making it useful for biotechnological and biomedical applications. However, PMMA has some limitations, including high hydrophobicity and low mechanical strength ( Amirabad et al, 2022 ; Shakeri et al, 2022a ; Kulkarni & Goel, 2022 ).…”

Section: Methodsmentioning

confidence: 99%

Breaking the clean room barrier: exploring low-cost alternatives for microfluidic devices

Rodríguez

Andrade-Pérez

Vargas

et al. 2023

Front. Bioeng. Biotechnol.

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Microfluidics is an interdisciplinary field that encompasses both science and engineering, which aims to design and fabricate devices capable of manipulating extremely low volumes of fluids on a microscale level. The central objective of microfluidics is to provide high precision and accuracy while using minimal reagents and equipment. The benefits of this approach include greater control over experimental conditions, faster analysis, and improved experimental reproducibility. Microfluidic devices, also known as labs-on-a-chip (LOCs), have emerged as potential instruments for optimizing operations and decreasing costs in various of industries, including pharmaceutical, medical, food, and cosmetics. However, the high price of conventional prototypes for LOCs devices, generated in clean room facilities, has increased the demand for inexpensive alternatives. Polymers, paper, and hydrogels are some of the materials that can be utilized to create the inexpensive microfluidic devices covered in this article. In addition, we highlighted different manufacturing techniques, such as soft lithography, laser plotting, and 3D printing, that are suitable for creating LOCs. The selection of materials and fabrication techniques will depend on the specific requirements and applications of each individual LOC. This article aims to provide a comprehensive overview of the numerous alternatives for the development of low-cost LOCs to service industries such as pharmaceuticals, chemicals, food, and biomedicine.

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“…These devices require external energy sources to drive fluid flow and can achieve more complex operations such as mixing, separation, and sorting. Examples of active microfluidic devices include electrokinetically-driven microfluidic devices, where electric fields are used to drive fluid flow, and microfluidic devices that utilize acoustic waves or magnetic fields to manipulate fluids and particles ( Guzzi et al, 2020 ). Active microfluidic devices can achieve faster fluid flow rates, higher throughput, and more precise fluid control, but they are also more complex to fabricate and require more sophisticated control systems ( Wang et al, 2015 ), ( Herbig et al, 2018 ).…”

Section: Principles Of Microfluidics-based Cell Deformation Measurementmentioning

confidence: 99%

Measuring cell deformation by microfluidics

Jiang

Zhao

et al. 2023

Front. Bioeng. Biotechnol.

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Microfluidics is an increasingly popular method for studying cell deformation, with various applications in fields such as cell biology, biophysics, and medical research. Characterizing cell deformation offers insights into fundamental cell processes, such as migration, division, and signaling. This review summarizes recent advances in microfluidic techniques for measuring cellular deformation, including the different types of microfluidic devices and methods used to induce cell deformation. Recent applications of microfluidics-based approaches for studying cell deformation are highlighted. Compared to traditional methods, microfluidic chips can control the direction and velocity of cell flow by establishing microfluidic channels and microcolumn arrays, enabling the measurement of cell shape changes. Overall, microfluidics-based approaches provide a powerful platform for studying cell deformation. It is expected that future developments will lead to more intelligent and diverse microfluidic chips, further promoting the application of microfluidics-based methods in biomedical research, providing more effective tools for disease diagnosis, drug screening, and treatment.

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A Disposable Passive Microfluidic Device for Cell Culturing

Cited by 13 publications

References 60 publications

Human iPSC Modeling of Genetic Febrile Seizure Reveals Aberrant Molecular and Physiological Features Underlying an Impaired Neuronal Activity

Human iPSC Modeling of Genetic Febrile Seizure Reveals Aberrant Molecular and Physiological Features Underlying an Impaired Neuronal Activity

Breaking the clean room barrier: exploring low-cost alternatives for microfluidic devices

Measuring cell deformation by microfluidics

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