Smart Organ-on-Chip Devices: Dynamic Microfluidic Systems for Cell Culture
Editat de Tiago Albertini Balbino, Paulo Bartolo, Letícia Charellien Limba Engleză Paperback – 18 iun 2025
The authors present new information regarding in silico studies of cell spheroids within microfluidic devices, as well as step-by-step guidance on key procedures. Written for researchers, practitioners and students using microfluidic devices as platforms, by well-respected scientists from both academia and industry.
- Presents the physiological relevance of in vitro tissue-like models
- Introduces evidence that stimuli-responsive organotypic-on-chip devices are the next generation
- Provides latest achievements to attain an organ-on-chip device, as well as case studies
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Specificații
ISBN-13: 9780443134036
ISBN-10: 0443134030
Pagini: 230
Dimensiuni: 191 x 235 x 13 mm
Greutate: 0.5 kg
Editura: ELSEVIER SCIENCE
ISBN-10: 0443134030
Pagini: 230
Dimensiuni: 191 x 235 x 13 mm
Greutate: 0.5 kg
Editura: ELSEVIER SCIENCE
Cuprins
SECTION 1: MICROFLUIDICS AND ORGAN-ON-CHIP TECHNOLOGIES
1. Organotypic On-Chip Models: Bridging the Gap Between Traditional In Vitro Culture and Animal Testing
2. Microfabrication Processes for the Manufacturing of Smart Organ-on-Chip Devices
3. Bioprinted Organ-on-a-Chip: A Strategy to Achieve Humanized In Vitro Models
4. Disease Modeling and Developmental Biology Through Microfluidic Channels
5. Artificial Intelligence-Assisted Organ-on-Chip Systems
SECTION 2: STIMULI ACTIVE ORGANOTYPIC-ON-CHIP DEVICES
6. Mechanically Active Organotypic-On-Chip Devices for Dynamic Cell Culture
7. Sensors within Microfluidic Chips: Optofluidics to Explore In Vitro Organoid Behavior
8. Photothermal and Magnetic Cell Stimuli Caused by Nanoparticles Inside Organ-on-Chip Platforms
SECTION 3: MICROPHYSIOLOGICAL CASE STUDIES
9. Brain-on-Chip Microplatforms for Precision Medicine, Disease Modelling, and Developmental Biology
10. Dynamic Microphysiological Systems to Access Sickle Cell Disease - A Case Study for Disease Modeling
11. Microtechnologies and Mathematical Modeling in Signaling Cascades Multiorgan Microphysiological Systems
12. Mechanically Active Heart-on-a-Chip: Toward a Reliable Heart Beating Study Model
13. Remaining Challenges: Are We Close to a Physiologically Representative In Vitro Model for Clinical Deployment?
1. Organotypic On-Chip Models: Bridging the Gap Between Traditional In Vitro Culture and Animal Testing
2. Microfabrication Processes for the Manufacturing of Smart Organ-on-Chip Devices
3. Bioprinted Organ-on-a-Chip: A Strategy to Achieve Humanized In Vitro Models
4. Disease Modeling and Developmental Biology Through Microfluidic Channels
5. Artificial Intelligence-Assisted Organ-on-Chip Systems
SECTION 2: STIMULI ACTIVE ORGANOTYPIC-ON-CHIP DEVICES
6. Mechanically Active Organotypic-On-Chip Devices for Dynamic Cell Culture
7. Sensors within Microfluidic Chips: Optofluidics to Explore In Vitro Organoid Behavior
8. Photothermal and Magnetic Cell Stimuli Caused by Nanoparticles Inside Organ-on-Chip Platforms
SECTION 3: MICROPHYSIOLOGICAL CASE STUDIES
9. Brain-on-Chip Microplatforms for Precision Medicine, Disease Modelling, and Developmental Biology
10. Dynamic Microphysiological Systems to Access Sickle Cell Disease - A Case Study for Disease Modeling
11. Microtechnologies and Mathematical Modeling in Signaling Cascades Multiorgan Microphysiological Systems
12. Mechanically Active Heart-on-a-Chip: Toward a Reliable Heart Beating Study Model
13. Remaining Challenges: Are We Close to a Physiologically Representative In Vitro Model for Clinical Deployment?