Ames Lastra et al., 2023 - Google Patents
Design and Heat Transfer Simulation of a Thermal Block for the Integration of a DNA Biosensor Based on PCRAmes Lastra et al., 2023
- Document ID
- 17059554834516866543
- Author
- Ames Lastra G
- González Díaz C
- Publication year
- Publication venue
- Congreso Nacional de Ingeniería Biomédica
External Links
Snippet
In this work, we present the design of a thermal block and the heat transfer simulation for the integration of a DNA biosensor based on PCR. The thermal block contains the PCR tubes which needs to be heated and cooled in order to catalyze the Polymerase Chain Reaction …
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| US10835900B2 (en) | Microfluidic device with multiple temperature zones | |
| Dos‐Reis‐Delgado et al. | Recent advances and challenges in temperature monitoring and control in microfluidic devices | |
| Kulkarni et al. | Recent advancements in integrated microthermofluidic systems for biochemical and biomedical applications–a review | |
| Guijt et al. | Chemical and physical processes for integrated temperature control in microfluidic devices | |
| Lin et al. | Simulation and experimental validation of micro polymerase chain reaction chips | |
| Chen et al. | Analytical study of a microfludic DNA amplification chip using water cooling effect | |
| Demello | DNA amplification moves on | |
| JP2011523345A (en) | Microfluidic high-speed thermal cycler for nucleic acid amplification | |
| Pardy et al. | Integrated self-regulating resistive heating for isothermal nucleic acid amplification tests (NAAT) in Lab-on-a-Chip (LoC) devices | |
| Hennig et al. | Convective polymerase chain reaction around micro immersion heater | |
| Chen et al. | One-heater flow-through polymerase chain reaction device by heat pipes cooling | |
| Jain et al. | Closed EWOD-based low-cost portable thermal detection system for point-of-care applications | |
| CN101145060A (en) | Temperature-controlled arrays for microfluidic chips | |
| Lim et al. | Battery-operated portable PCR system with enhanced stability of Pt RTD | |
| Ji et al. | Open thermal control system for stable polymerase chain reaction on a digital microfluidic chip | |
| Ames Lastra et al. | Design and Heat Transfer Simulation of a Thermal Block for the Integration of a DNA Biosensor Based on PCR | |
| Priye et al. | Convective PCR thermocycling with smartphone-based detection: a versatile platform for rapid, inexpensive, and robust mobile diagnostics | |
| Maltezos et al. | Microfluidic polymerase chain reaction | |
| Selva et al. | Integration of a uniform and rapid heating source into microfluidic systems | |
| Lastra¹ et al. | Design and Heat Transfer Simulation of a Thermal Block for the Integration of a DNA | |
| Papadopoulos et al. | Modeling heat losses in microfluidic devices: The case of static chamber devices for DNA amplification | |
| Chen et al. | Modeling and experiment of shuttling speed effects on the OSTRYCH | |
| Zhang et al. | Continuous‐flow polymerase chain reaction microfluidics by using spiral capillary channel embedded on copper | |
| Ibrahim et al. | Three-dimensional transient thermal analysis for a silicon PCR microreactor | |
| Zhang et al. | Continuous‐Flow PCR Microfluidics for Rapid DNA Amplification Using Thin Film Heater with Low Thermal Mass |