Your search keyword '"Lab-on-a-chip"' showing total 9,085 results

51. Polymer Waveguide Sensor Based on Evanescent Bragg Grating for Lab-on-a-Chip Applications.

Author

Zhang, Zhenyu, Abdalwareth, Ahmad, Flachenecker, Günter, Angelmahr, Martin, and Schade, Wolfgang

Subjects

*BRAGG gratings, *REFRACTIVE index, *LABS on a chip, *POLYMERS, *DETECTORS, *PLANAR waveguides, *OPTICAL gratings, *ISOPROPYL alcohol

Abstract

In this work, an evanescent Bragg grating sensor inscribed in a few-mode planar polymer waveguide was integrated into microchannel structures and characterized by various chemical applications. The planar waveguide and the microchannels consisted of epoxide-based polymers. The Bragg grating structure was postprocessed by using point-by-point direct inscription technology. By monitoring the central wavelength shift of the reflected Bragg signal, the sensor showed a temperature sensitivity of −47.75 pm/K. Moreover, the functionality of the evanescent field-based measurements is demonstrated with two application examples: the refractive index sensing of different aqueous solutions and gas-phase hydrogen concentration detection. For the latter application, the sensor was additionally coated with a functional layer based on palladium nanoparticles. During the refractive index sensing measurement, the sensor achieved a sensitivity of 6.5 nm/RIU from air to 99.9% pure isopropyl alcohol. For the gas-phase hydrogen detection, the coated sensor achieved a reproducible concentration detection up to 4 vol% hydrogen. According to the reported experimental results, the integrated Bragg-grating-based waveguide sensor demonstrates high potential for applications based on the lab-on-a-chip concept. [ABSTRACT FROM AUTHOR]

Published

2024

52. Operando investigation of particle re-entrainment mechanism in electrostatic capture process on the lab-on-a-chip.

Author

Zhu, Yong, Zhang, Yikun, Yang, Xiaoyong, Tao, Shanlong, Chen, Mingxia, and Shangguan, Wenfeng

Subjects

*LABS on a chip, *DRAG force, *AIR pollutants, *ECOSYSTEM health, *ENVIRONMENTAL health

Abstract

• Operando observation system is developed to make in-situ test on lab-on-a-chip. • Actual evolution process of charged submicron particles is recorded intuitively. • This work demonstrates direct influence of drag force on particle chain fracture. • It is first-time visualization of mechanism elucidation of particle re-entrainment. Inhalable particle is a harmful air pollutant that causes a significant threat to people's health and ecological environments, which should be removed to purify air, but there exists limited removal efficiency due to particle re-entrainment. Here, Operando observation system based on microscopic visualization method is developed to make in situ test of particle migration, deposition and re-entrainment characteristics on a lab-on-a-chip to achieve the investigation in micro-level scale. The deposition evolution of charged particles is recorded in electric field region intuitively, which confirms the fracture of particle chain occurs during the growth process of deposited particles. It captures the instantaneous process that a larger particle with micron size due to the coagulation of submicron particles fractures from main body of the particle chain for the first time. The analysis of migration behavior of a single submicron particle near electrode surface demonstrates the direct influence of drag force on the fracture of particle chain. This work is the first-time visualization of dynamic process and mechanism elucidation of particle re-entrainment at the micron level, and the findings will provide the theory support for the particle re-entrainment mechanism and bring inspires of enhancing capture efficiency of inhalable particle. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

53. Advanced technologies towards improved HPV diagnostics.

Author

Bartosik, Martin, Moranova, Ludmila, Izadi, Nasim, Strmiskova, Johana, Sebuyoya, Ravery, Holcakova, Jitka, and Hrstka, Roman

Abstract

Persistent infection with high‐risk types of human papillomaviruses (HPV) is a major cause of cervical cancer, and an important factor in other malignancies, for example, head and neck cancer. Despite recent progress in screening and vaccination, the incidence and mortality are still relatively high, especially in low‐income countries. The mortality and financial burden associated with the treatment could be decreased if a simple, rapid, and inexpensive technology for HPV testing becomes available, targeting individuals for further monitoring with increased risk of developing cancer. Commercial HPV tests available in the market are often relatively expensive, time‐consuming, and require sophisticated instrumentation, which limits their more widespread utilization. To address these challenges, novel technologies are being implemented also for HPV diagnostics that include for example, isothermal amplification techniques, lateral flow assays, CRISPR‐Cas‐based systems, as well as microfluidics, paperfluidics and lab‐on‐a‐chip devices, ideal for point‐of‐care testing in decentralized settings. In this review, we first evaluate current commercial HPV tests, followed by a description of advanced technologies, explanation of their principles, critical evaluation of their strengths and weaknesses, and suggestions for their possible implementation into medical diagnostics. [ABSTRACT FROM AUTHOR]

Published

2024

54. Easy-to-Use Chemiluminescent-Based Assay for a Rapid and Low-Cost Evaluation of the Antioxidant Activity of Cosmetic Products.

Author

Pour, Seyedeh Rojin Shariati, Calabria, Donato, Nascetti, Augusto, Caputo, Domenico, De Cesare, Giampiero, Guardigli, Massimo, Zangheri, Martina, and Mirasoli, Mara

Subjects

ANTIOXIDANTS, HORSERADISH peroxidase, CHEMILUMINESCENCE assay, MICROPLATES, AMORPHOUS silicon, VITAMIN C, HYDROGEN peroxide

Abstract

New cosmetic formulations are continuously requested by the market and the ingredients are constantly evolving. Recently the use of antioxidants has gained success and, in this context, analytical methods able to quickly and easily assess the antioxidant activity of cosmetics would make it possible to carry out analyses on new formulations even within the manufacturing process without the need for specialized laboratories and personnel, thus evaluating directly on-site the effectiveness and the shelf life of products. In this work, a chemiluminescent inhibition assay was developed for determining the total antioxidant activity in cosmetic products. The method was based on the luminol/enhancers/hydrogen peroxide/horseradish peroxidase chemiluminescent system, which generates light signals measurable through simple and compact instrumentation. The formation of the chemiluminescent signal is inhibited by the presence of antioxidant substances while it is restored once all the antioxidant molecules have been oxidized. The time of appearance of the light signal is related to the total antioxidant activity. The assay was carried out exploiting an integrated device comprising a microwell plate coupled with an array of amorphous silicon hydrogenated photosensors enclosed in a mini-dark box. The method was optimized in terms of concentrations and volumes of the required reagents and sample pre-treatment. A calibration curve was generated taking as a reference the antioxidant activity of ascorbic acid obtaining a detection limit of 10 µM. The developed method was applied to cosmetic products currently on the market as well as on spiked samples in order to evaluate the performance of the methods in terms of sensitivity, accuracy, and reproducibility. [ABSTRACT FROM AUTHOR]

Published

2024

55. Using Rapid Prototyping to Develop a Cell-Based Platform with Electrical Impedance Sensor Membranes for In Vitro RPMI2650 Nasal Nanotoxicology Monitoring.

Author

Vasconez Martinez, Mateo Gabriel, Reihs, Eva I., Stuetz, Helene M., Hafner, Astrid, Brandauer, Konstanze, Selinger, Florian, Schuller, Patrick, Bastus, Neus, Puntes, Victor, Frank, Johannes, Tomischko, Wolfgang, Frauenlob, Martin, Ertl, Peter, Resch, Christian, Bauer, Gerald, Povoden, Guenter, and Rothbauer, Mario

Subjects

MICROFLUIDIC devices, ELECTRIC impedance, RAPID prototyping, NANOPARTICLE toxicity, NASAL mucosa, ENVIRONMENTAL risk assessment, ZINC oxide

Abstract

Due to advances in additive manufacturing and prototyping, affordable and rapid microfluidic sensor-integrated assays can be fabricated using additive manufacturing, xurography and electrode shadow masking to create versatile platform technologies aimed toward qualitative assessment of acute cytotoxic or cytolytic events using stand-alone biochip platforms in the context of environmental risk assessment. In the current study, we established a nasal mucosa biosensing platform using RPMI2650 mucosa cells inside a membrane-integrated impedance-sensing biochip using exclusively rapid prototyping technologies. In a final proof-of-concept, we applied this biosensing platform to create human cell models of nasal mucosa for monitoring the acute cytotoxic effect of zinc oxide reference nanoparticles. Our data generated with the biochip platform successfully monitored the acute toxicity and cytolytic activity of 6 mM zinc oxide nanoparticles, which was non-invasively monitored as a negative impedance slope on nasal epithelial models, demonstrating the feasibility of rapid prototyping technologies such as additive manufacturing and xurography for cell-based platform development. [ABSTRACT FROM AUTHOR]

Published

2024

56. Molecular Separation by Using Active and Passive Microfluidic chip Designs: A Comprehensive Review.

Author

Ebrahimi, Aliakbar, Icoz, Kutay, Didarian, Reza, Shih, Chih‐Hsin, Tarim, E. Alperay, Nasseri, Behzad, Akpek, Ali, Cecen, Berivan, Bal‐Ozturk, Ayca, Güleç, Kadri, Li, Yi‐Chen Ethan, Shih, Steven, Sirma Tarim, Burcu, Tekin, H. Cumhur, Alarçin, Emine, Tayybi‐Azar, Mehdi, Ghorbanpoor, Hamed, Özel, Ceren, Eker Sarıboyacı, Ayla, and Dogan Guzel, Fatma

Subjects

COMPLEX fluids, LABS on a chip, BLOOD sampling, MOLECULES, POLYSACCHARIDES

Abstract

Separation and identification of molecules and biomolecules such as nucleic acids, proteins, and polysaccharides from complex fluids are known to be important due to unmet needs in various applications. Generally, many different separation techniques, including chromatography, electrophoresis, and magnetophoresis, have been developed to identify the target molecules precisely. However, these techniques are expensive and time consuming. "Lab‐on‐a‐chip" systems with low cost per device, quick analysis capabilities, and minimal sample consumption seem to be ideal candidates for separating particles, cells, blood samples, and molecules. From this perspective, different microfluidic‐based techniques have been extensively developed in the past two decades to separate samples with different origins. In this review, "lab‐on‐a‐chip" methods by passive, active, and hybrid approaches for the separation of biomolecules developed in the past decade are comprehensively discussed. Due to the wide variety in the field, it will be impossible to cover every facet of the subject. Therefore, this review paper covers passive and active methods generally used for biomolecule separation. Then, an investigation of the combined sophisticated methods is highlighted. The spotlight also will be shined on the elegance of separation successes in recent years, and the remainder of the article explores how these permit the development of novel techniques. [ABSTRACT FROM AUTHOR]

Published

2024

57. Accelerated Computational Fluid Dynamics Simulations of Microfluidic Devices by Exploiting Higher Levels of Abstraction.

Author

Takken, Michel and Wille, Robert

Subjects

MICROFLUIDIC devices, MICROFLUIDICS, COMPUTATIONAL fluid dynamics

Abstract

The design of microfluidic devices is a cumbersome and tedious process that can be significantly improved by simulation. Methods based on Computational Fluid Dynamics (CFD) are considered state-of-the-art, but require extensive compute time—oftentimes limiting the size of microfluidic devices that can be simulated. Simulation methods that abstract the underlying physics on a higher level generally provide results instantly, but the fidelity of these methods is usually worse. In this work, a simulation method that accelerates CFD simulations by exploiting simulation methods on higher levels of abstraction is proposed. Case studies confirm that the proposed method accelerates CFD simulations by multiple factors (often several orders of magnitude) while maintaining the fidelity of CFD simulations. [ABSTRACT FROM AUTHOR]

Published

2024

58. FIGURE OF MERIT STUDY FOR VALVELESS PIEZOELECTRIC MICROPUMP DESIGNED TO HANDLE LIQUID AND GAS FLUID IN MEDICAL AND ENVIRONMENTAL APPLICATIONS.

Author

Bouzid, Asma, Brixi Negassa, Mohamed El Amine, Pirastesh, Parastesh, Charrier, Joel, and Soulimane, Sofiane

Subjects

PIEZOELECTRIC actuators, FINITE element method, LIQUEFIED gases, LABS on a chip, MICROPUMPS

Abstract

Micropumps are revolutionizing compact and autonomous monitoring systems due to their portability and efficiency. In this paper, we present a valveless piezoelectric micropump design. This micropump distributes gas and liquid using a PDMS membrane that moves in response to a force applied by a piezoelectric actuator. The proposed design aims to achieve an average flow rate between 10 µl/min and 100 µl/min, while emphasizing mobility and low energy. For these specifications, a figure of merit (FOM) is evaluated through a parametric study of piezoelectric membrane to achieve optimized micropump performance for both gas and liquid. The finite element analysis shows the optimum thickness of PZT and PDMS, delivering a significant flow rate of 79 µl/min for liquid and 50 µl/min for gas at a lower voltage of 9 V, 60 Hz. These promising results show immense potential of micropump design in diverse applications, from intricate lab-on-a-chip platforms to precise drug delivery systems, and even integration into medical and environmental sensors. [ABSTRACT FROM AUTHOR]

Published

2024

59. A Rapid Prototyping Approach for Multi-Material, Reversibly Sealed Microfluidics.

Author

Halwes, Michael, Stamp, Melanie, and Collins, David J.

Subjects

MICROFLUIDIC devices, RAPID prototyping, MICROFLUIDICS, LASER beam cutting, THREE-dimensional printing, SEALS (Closures), LASER printing

Abstract

Microfluidic organ-on-chip models recapitulate increasingly complex physiological phenomena to study tissue development and disease mechanisms, where there is a growing interest in retrieving delicate biological structures from these devices for downstream analysis. Standard bonding techniques, however, often utilize irreversible sealing, making sample retrieval unfeasible or necessitating destructive methods for disassembly. To address this, several commercial devices employ reversible sealing techniques, though integrating these techniques into early-stage prototyping workflows is often ignored because of the variation and complexity of microfluidic designs. Here, we demonstrate the concerted use of rapid prototyping techniques, including 3D printing and laser cutting, to produce multi-material microfluidic devices that can be reversibly sealed. This is enhanced via the incorporation of acrylic components directly into polydimethylsiloxane channel layers to enhance stability, sealing, and handling. These acrylic components act as a rigid surface separating the multiple mechanical seals created between the bottom substrate, the microfluidic features in the device, and the fluidic interconnect to external tubing, allowing for greater design flexibility. We demonstrate that these devices can be produced reproducibly outside of a cleanroom environment and that they can withstand ~1 bar pressures that are appropriate for a wide range of biological applications. By presenting an accessible and low-cost method, we hope to enable microfluidic prototyping for a broad range of biomedical research applications. [ABSTRACT FROM AUTHOR]

Published

2023

60. Optofluidic Particle Manipulation Platform with Nanomembrane.

Author

Walker, Zachary, Wells, Tanner, Belliston, Ethan, Romney, Sage, Walker, Seth, Sampad, Mohammad, Saiduzzaman, S, Losakul, Ravipa, Schmidt, Holger, and Hawkins, Aaron

Subjects

NEMS, biosensor, lab-on-a-chip, microfluidic, nanomembrane, optofluidic

Abstract

We demonstrate a method for fabricating and utilizing an optofluidic particle manipulator on a silicon chip that features a 300 nm thick silicon dioxide membrane as part of a microfluidic channel. The fabrication method is based on etching silicon channels and converting the walls to silicon dioxide through thermal oxidation. Channels are encapsulated by a sacrificial polymer which fills the length of the fluid channel by way of spontaneous capillary action. The sacrificial material is then used as a mold for the formation of a nanoscale, solid-state, silicon dioxide membrane. The hollow channel is primarily used for fluid and particle transport but is capable of transmitting light over short distances and utilizes radiation pressure for particle trapping applications. The optofluidic platform features solid-core ridge waveguides which can direct light on and off of the silicon chip and intersect liquid channels. Optical loss values are characterized for liquid and solid-core structures and at interfaces. Estimates are provided for the optical power needed to trap particles of various sizes.

Published

2022

61. Advances of Fluorescent Nanodiamond Platforms for Intracellular and On-Chip Biosensing

Author

Taisuke Shimada, Yasuyuki Ueda, Yoshinobu Baba, and Hiroshi Yukawa

Subjects

fluorescent nanodiamonds, biosensing, surface functionalization, intracellular biosensing, lab-on-a-chip, Biotechnology, TP248.13-248.65

Abstract

Intracellular and extracellular sensing of physical and chemical variables is important for disease diagnosis and the understanding of cellular biology. Optical sensing utilizing fluorescent nanodiamonds (FNDs) is promising for probing intracellular and extracellular variables owing to their biocompatibility, photostability, and sensitivity to physicochemical quantities. Based on the potential of FNDs, we outlined the optical properties, biocompatibility, surface chemistry of FNDs and their applications in intracellular biosensing. This review also introduces biosensing platforms that combine FNDs and lab-on-a-chip approaches to control the extracellular environment and improve sample/reagent handling and sensing performance.

Published

2024

62. Increasing Optical Path Lengths in Micro-Fluidic Devices Using a Multi-Pass Cell

Author

Victor Argueta-Diaz, McKenna Owens, and Ahmed Al Ramadan

Subjects

microfluidics, long-optical path, lab-on-a-chip, Mechanical engineering and machinery, TJ1-1570

Abstract

This study presents a novel absorption cell with a circular geometry that can be integrated into microfluidic devices for optical spectroscopy applications. The absorption cell is made of PDMS/SU8 and offers an optical path length that is 8.5 times its diameter, resulting in a significant increase in the sensitivity of the measurements. Overall, this design provides a reliable and efficient solution for optical spectroscopy in microfluidic systems, enabling the precise detection and analysis of small quantities of analytes.

Published

2024

63. Targeting Epigenetics in Pulmonary Arterial Hypertension

Author

Rahman, K. M. Taufiqur, Islam, Tanim, Islam, Md Fahmid, Carbone, Roberto G., Butzin, Nicholas C., Ali, Md Khadem, Gupta, Gaurav, editor, Oliver, Brian G., editor, Dua, Kamal, editor, Ali, Md Khadem, editor, and Dave, Piyush, editor

Published

2023

64. Future Perspective of Nanobiomaterials in Human Health Care

Author

Hunsur Ravikumar, Chandan, Muangphrom, Paskorn, Pataranutaporn, Pat, Surareungchai, Werasak, Azad, Uday Pratap, editor, and Chandra, Pranjal, editor

Published

2023

65. Microfluidic Culture Platforms in Neuroscience Research

Author

Pham, Vuong M., Ha, Huong T. T., Thakor, Nitish V., and Thakor, Nitish V., editor

Published

2023

66. Nanotechnology for Personalized Medicine

Author

Shrestha, Binita, Tang, Liang, Hood, R. Lyle, You, Zheng, Series Editor, Wang, Xiaohao, Series Editor, and Gu, Ning, editor

Published

2023

67. Sounding a New Era in Biomechanics with Acoustic Force Spectroscopy

Author

Silvani, Giulia, Romanov, Valentin, Martinac, Boris, and Turksen, Kursad, editor

Published

2023

68. An Attempt to Develop an Organ-on-a-Chip Using 3D Printing Technology for in Vitro Drug Testing

Author

Appalanaidu, Botcha, Maurya, Tara Chand Kumar, Rajakumaran, Maran, Tewari, Abhishek, editor, Dhawan, Nikhil, editor, Agarwal, Gautam, editor, Das, Sourav, editor, Mishra, Sumeet, editor, and Karmakar, Anish, editor

Published

2023

69. Rapid Detection of SARS-CoV-2 Variants of Concern by Genomic Surveillance Techniques

Author

Guest, Paul C., Hawkins, Steve F. C., Rahmoune, Hassan, Crusio, Wim E., Series Editor, Dong, Haidong, Series Editor, Radeke, Heinfried H., Series Editor, Rezaei, Nima, Series Editor, Steinlein, Ortrud, Series Editor, Xiao, Junjie, Series Editor, and Guest, Paul C., editor

Published

2023

70. The Role of Diagnostic Microdevices in the Fight Against Tuberculosis

Author

Cañadas-Ortega, Marina, Gómez-Cruz, Clara, Vaquero, Juan José, Muñoz-Barrutia, Arrate, and Rezaei, Nima, Editor-in-Chief

Published

2023

71. Microfluidics and Lab-on-a-Chip for Biomedical Applications

Author

Patel, Dinesh K., Espinal, Maria Mercedes, Patil, Tejal V., Ganguly, Keya, Dutta, Sayan Deb, Luthfikasari, Rachmi, Lim, Ki-Taek, Lim, Ki-Taek, editor, and Abd-Elsalam, Kamel A., editor

Published

2023

72. Lab-on-a-Chip Devices for Medical Diagnosis II: Strategies for Pathogen Detection

Author

Luthfikasari, Rachmi, Patil, Tejal V., Patel, Dinesh K., Ganguly, Keya, Dutta, Sayan Deb, Lim, Ki-Taek, Lim, Ki-Taek, editor, and Abd-Elsalam, Kamel A., editor

Published

2023

73. Application of microfluidic technologies on COVID-19 diagnosis and drug discovery

Author

Zhun Lin, Zhengyu Zou, Zhe Pu, Minhao Wu, and Yuanqing Zhang

Subjects

Microfluidic, COVID-19, SARS-CoV-2, Lab-on-a-chip, Detection, Organ-on-a-chip, Therapeutics. Pharmacology, RM1-950

Abstract

The ongoing coronavirus disease 2019 (COVID-19) pandemic has boosted the development of antiviral research. Microfluidic technologies offer powerful platforms for diagnosis and drug discovery for severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) diagnosis and drug discovery. In this review, we introduce the structure of SARS-CoV-2 and the basic knowledge of microfluidic design. We discuss the application of microfluidic devices in SARS-CoV-2 diagnosis based on detecting viral nucleic acid, antibodies, and antigens. We highlight the contribution of lab-on-a-chip to manufacturing point-of-care equipment of accurate, sensitive, low-cost, and user-friendly virus-detection devices. We then investigate the efforts in organ-on-a-chip and lipid nanoparticles (LNPs) synthesizing chips in antiviral drug screening and mRNA vaccine preparation. Microfluidic technologies contribute to the ongoing SARS-CoV-2 research efforts and provide tools for future viral outbreaks.

Published

2023

74. Simple microfluidic devices for in situ detection of water contamination: a state-of-art review

Author

Buthaina A. AlMashrea, Ahmed M. Almehdi, and Samar Damiati

Subjects

micro-total analytical system, lab-on-a-chip, water contaminants, in situ detection, water quality monitoring, inorganic and organic pollutants, Biotechnology, TP248.13-248.65

Abstract

Water security is an important global issue that is pivotal in the pursuit of sustainable resources for future generations. It is a multifaceted concept that combines water availability with the quality of the water’s chemical, biological, and physical characteristics to ensure its suitability and safety. Water quality is a focal aspect of water security. Quality index data are determined and provided via laboratory testing using expensive instrumentation with high maintenance costs and expertise. Due to increased practices in this sector that can compromise water quality, innovative technologies such as microfluidics are necessary to accelerate the timeline of test procedures. Microfluidic technology demonstrates sophisticated functionality in various applications due to the chip’s miniaturization system that can control the movement of fluids in tiny amounts and be used for onsite testing when integrated with smart applications. This review aims to highlight the basics of microfluidic technology starting from the component system to the properties of the chip’s fabricated materials. The published research on developing microfluidic sensor devices for monitoring chemical and biological contaminants in water is summarized to understand the obstacles and challenges and explore future opportunities for advancement in water quality monitoring.

Published

2024

75. Editorial: Next generation in vitro models of the human blood - brain/cerebrospinal fluid barrier

Author

Randy S. Daughters, Lisa Julian, Erin Knock, and Stephanie M. Willerth

Subjects

neuroscience, drug discovery, lab-on-a-chip, stem cells, neurodegenerative diseases, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Published

2024

76. FTA-LAMP based biosensor for a rapid in-field detection of Globodera pallida—the pale potato cyst nematode

Author

Maria João Camacho, Débora C. Albuquerque, Maria L. Inácio, Verónica C. Martins, Manuel Mota, Paulo P. Freitas, and Eugénia de Andrade

Subjects

LAMP, magnetoresistive biochips, PCN, FTA-card ®, Lab-on-a-chip, Biotechnology, TP248.13-248.65

Abstract

The combination of a sensitive and specific magnetoresistive sensing device with an easy DNA extraction method and a rapid isothermal amplification is presented here targeting the on-site detection of Globodera pallida, a potato endoparasitic nematode. FTA-cards were used for DNA extraction, LAMP was the method developed for DNA amplification and a nanoparticle functionalized magnetic-biosensor was used for the detection. The combinatorial effect of these three emerging technologies has the capacity to detect G. pallida with a detection limit of one juvenile, even when mixed with other related species. This combined system is far more interesting than what a single technology can provide. Magnetic biosensors can be combined with any DNA extraction protocol and LAMP forming a new solution to target G. pallida. The probe designed in this study consistently distinguished G. pallida (∆Vacbinding/Vacsensor above 1%) from other cyst nematodes (∆Vacbinding/Vacsensor below 1%). It was confirmed that DNA either extracted with FTA-cards or Lab extraction Kit was of enough quantity and quality to detect G. pallida whenever present (alone or in mixed samples), ensuring probe specificity and sensitivity. This work provides insights for a new strategy to construct advanced devices for pathogens in-field diagnostics. LAMP runs separately but can be easily integrated into a single device.

Published

2024

77. Molecular Separation by Using Active and Passive Microfluidic chip Designs: A Comprehensive Review

Author

Aliakbar Ebrahimi, Kutay Icoz, Reza Didarian, Chih‐Hsin Shih, E. Alperay Tarim, Behzad Nasseri, Ali Akpek, Berivan Cecen, Ayca Bal‐Ozturk, Kadri Güleç, Yi‐Chen Ethan Li, Steven Shih, Burcu Sirma Tarim, H. Cumhur Tekin, Emine Alarçin, Mehdi Tayybi‐Azar, Hamed Ghorbanpoor, Ceren Özel, Ayla Eker Sarıboyacı, Fatma Dogan Guzel, Nicole Bassous, Su Ryon Shin, and Huseyin Avci

Subjects

active separation, biomolecule separation, hybrid separation, lab‐on‐a‐chip, microfluidics, passive separation, Physics, QC1-999, Technology

Abstract

Abstract Separation and identification of molecules and biomolecules such as nucleic acids, proteins, and polysaccharides from complex fluids are known to be important due to unmet needs in various applications. Generally, many different separation techniques, including chromatography, electrophoresis, and magnetophoresis, have been developed to identify the target molecules precisely. However, these techniques are expensive and time consuming. “Lab‐on‐a‐chip” systems with low cost per device, quick analysis capabilities, and minimal sample consumption seem to be ideal candidates for separating particles, cells, blood samples, and molecules. From this perspective, different microfluidic‐based techniques have been extensively developed in the past two decades to separate samples with different origins. In this review, “lab‐on‐a‐chip” methods by passive, active, and hybrid approaches for the separation of biomolecules developed in the past decade are comprehensively discussed. Due to the wide variety in the field, it will be impossible to cover every facet of the subject. Therefore, this review paper covers passive and active methods generally used for biomolecule separation. Then, an investigation of the combined sophisticated methods is highlighted. The spotlight also will be shined on the elegance of separation successes in recent years, and the remainder of the article explores how these permit the development of novel techniques.

Published

2024

78. Improved longevity of actomyosin in vitro motility assays for sustainable lab-on-a-chip applications

Author

Melbacke, Andreas, Salhotra, Aseem, Ušaj, Marko, and Månsson, Alf

Published

2024

79. Low-cost inertial microfluidic device for microparticle separation: A laser-Ablated PMMA lab-on-a-chip approach without a cleanroom

Author

Cristian F. Rodríguez, Paula Guzmán-Sastoque, Mónica Gantiva-Diaz, Saúl C. Gómez, Valentina Quezada, Carolina Muñoz-Camargo, Johann F. Osma, Luis H. Reyes, and Juan C. Cruz

Subjects

Lab-on-a-chip, Microfluidic-device, Microparticle-separator, COMSOL, Low-cost, Science (General), Q1-390

Abstract

Although microparticles are frequently used in chemistry and biology, their effectiveness largely depends on the homogeneity of their particle size distribution. Microfluidic devices to separate and purify particles based on their size have been developed, but many require expensive cleanroom manufacturing processes. A cost-effective, passive microfluidic separator is presented, capable of efficiently sorting and purifying particles spanning the size range of 15 µm to 40 µm. Fabricated from Polymethyl Methacrylate (PMMA) substrates using laser ablation, this device circumvents the need for cleanroom facilities. Prior to fabrication, rigorous optimization of the device's design was carried out through computational simulations conducted in COMSOL Multiphysics. To gauge its performance, chitosan microparticles were employed as a test case. The results were notably promising, achieving a precision of 96.14 %. This quantitative metric underscores the device's precision and effectiveness in size-based particle separation.This low-cost and accessible microfluidic separator offers a pragmatic solution for laboratories and researchers seeking precise control over particle sizes, without the constraints of expensive manufacturing environments. This innovation not only mitigates the limitations tied to traditional cleanroom-based fabrication but also widens the horizons for various applications within the realms of chemistry and biology.

Published

2023

80. Microdevices for cancer stem cell culture as a predictive chemotherapeutic response platform.

Author

Agüero, Eduardo Imanol, Belgorosky, Denise, García-Silva, Julio Israel, Booth, Ross, Lerner, Betiana, Pérez, Maximiliano Sebastián, and Eiján, Ana María

Subjects

*STEM cell culture, *CANCER cell culture, *CANCER stem cells, *CANCER chemotherapy, *MICROFLUIDIC devices

Abstract

Microfluidic platforms for clinical use are a promising translational strategy for cancer research specially for drug screening. Identifying cancer stem cells (CSC) using sphere culture techniques in microfluidic devices (MDs) showed to be better reproducing physiological responses than other in vitro models and allow the optimization of samples and reagents. We evaluated individual sphere proliferation and stemness toward chemotherapeutic treatment (CT) with doxorubicin and cisplatin in bladder cancer cell lines (MB49-I and J82) cultured in MDs used as CSC treatment response platform. Our results confirm the usefulness of this device to evaluate the CT effect in sphere-forming efficiency, size, and growth rate from individual spheres within MDs and robust information comparable to conventional culture plates was obtained. The expression of pluripotency genetic markers (Oct4, Sox2, Nanog, and CD44) could be analyzed by qPCR and immunofluorescence in spheres growing directly in MDs. MDs are a suitable platform for sphere isolation from tumor samples and can provide information about CT response. Microfluidic-based CSC studies could provide information about treatment response of cancer patients from small samples and can be a promising tool for CSC-targeted specific treatment with potential in precision medicine. Key messages: We have designed a microfluidic platform for CSC enriched culture by tumor sphere formation. Using MDs, we could quantify and determine sphere response after CT using murine and human cell lines as a proof of concept. MDs can be used as a tumor-derived sphere isolation platform to test the effect of antitumoral compounds in sphere proliferation. [ABSTRACT FROM AUTHOR]

Published

2023

81. Quantitative analysis of respiratory viruses based on lab-on-a-chip platform.

Author

Zhang, Ning, Yue, Chao, Zhan, Xiaobo, Cheng, Zhi, Li, Chao, Du, Yaohua, and Tian, Feng

Subjects

*NUCLEIC acid isolation methods, *CORONAVIRUSES, *LABS on a chip, *AUTOMATIC control systems, *QUANTITATIVE research, *COVID-19

Abstract

The quantitative analysis of respiratory viruses is of great importance for rapid diagnosis, precision medicine, and prognosis. Several current quantitative analysis systems have been proposed and commercialized. Although they have been proven in trials, quantitative analyzes based on real samples are still complex, time-consuming, and expensive. Therefore, they are not able to directly quantify real samples. In this work, we presented a lab-on-a-chip platform combined with an automated control system to achieve quantitative analysis from samples to results. We developed a multilayer integrated chip to rapidly extract and quantify RNA of coronavirus disease 2019 (COVID-19) pseudovirus from large-volume nasal swab samples. The dependence of the magnetic bead size and the interfacial effect was studied for the first time, and the conditions of immiscible filtration assisted by surface tension (IFAST) method for nucleic acid extraction were optimized to increase the nucleic acid recovery rate up to 85%. Inside the chip, a pneumatic valve was developed for automatic opening and closing of the liquid channel. The integrated chip platform and automatic control system presented here are advantageous for use in resource-limited settings (RLS). In addition, our method can be extended to other respiratory viruses and other sample types. [ABSTRACT FROM AUTHOR]

Published

2023

82. Design and Fabrication of Digital Microfluidics Device for Lab-on-a-Chip Applications.

Author

Ullah, Hammas, Shoaib, Faraz, Zahid, Syed Danyal, Mahmood, Mohammad Iymaan, Ali, Mubashar, Ali, Moazzam, Abbas, Hamza, and Jafry, Ali Turab

Subjects

MICROFLUIDICS, FLOW control (Data transmission systems), DIELECTRIC devices, DNA analysis, NUCLEIC acid analysis

Abstract

In digital microfluidics, discrete liquid droplets move on a dielectric surface with the help of AC or DC voltage. Digital microfluidics system has extended the scope of microfluidics by providing automated, precise flow control for point-of-care devices capable of medical diagnostics, environmental, and chemical sensing platforms. In this paper, we introduce a digital microfluidics platform based on electrowetting on a dielectric using PCB substrate designed on Easy EDA software. The platform's performance was analyzed at various DC voltages between 200 V and 400 V for droplet actuation. PCB fabrication, the utilization of easily accessible and cheap materials such as cooking oil and grafting tape as a dielectric layer, allowed the fabrication to be affordable and simple. The results indicate that droplet actuation takes place at 220 V. The droplet velocity obtained was 2.6 mm/s and 1.51 mm/s using silicon oil and cooking oil, respectively, at 400 V. Our proposed digital microfluidics platform will play a vital role in droplet actuation and can be used for diagnostic applications such as DNA analysis and cell culture due to its simple fabrication and cost-effective technique. [ABSTRACT FROM AUTHOR]

Published

2023

83. Microfluidic Blood Separation: Key Technologies and Critical Figures of Merit.

Author

Torres-Castro, Karina, Acuña-Umaña, Katherine, Lesser-Rojas, Leonardo, and Reyes, Darwin R.

Subjects

MICROFLUIDIC devices, SEPARATION (Technology), ROAD maps, BLOOD volume, BLOOD cells

Abstract

Blood is a complex sample comprised mostly of plasma, red blood cells (RBCs), and other cells whose concentrations correlate to physiological or pathological health conditions. There are also many blood-circulating biomarkers, such as circulating tumor cells (CTCs) and various pathogens, that can be used as measurands to diagnose certain diseases. Microfluidic devices are attractive analytical tools for separating blood components in point-of-care (POC) applications. These platforms have the potential advantage of, among other features, being compact and portable. These features can eventually be exploited in clinics and rapid tests performed in households and low-income scenarios. Microfluidic systems have the added benefit of only needing small volumes of blood drawn from patients (from nanoliters to milliliters) while integrating (within the devices) the steps required before detecting analytes. Hence, these systems will reduce the associated costs of purifying blood components of interest (e.g., specific groups of cells or blood biomarkers) for studying and quantifying collected blood fractions. The microfluidic blood separation field has grown since the 2000s, and important advances have been reported in the last few years. Nonetheless, real POC microfluidic blood separation platforms are still elusive. A widespread consensus on what key figures of merit should be reported to assess the quality and yield of these platforms has not been achieved. Knowing what parameters should be reported for microfluidic blood separations will help achieve that consensus and establish a clear road map to promote further commercialization of these devices and attain real POC applications. This review provides an overview of the separation techniques currently used to separate blood components for higher throughput separations (number of cells or particles per minute). We present a summary of the critical parameters that should be considered when designing such devices and the figures of merit that should be explicitly reported when presenting a device's separation capabilities. Ultimately, reporting the relevant figures of merit will benefit this growing community and help pave the road toward commercialization of these microfluidic systems. [ABSTRACT FROM AUTHOR]

Published

2023

84. Deployable Lab-on-a-Chip Sensor for Colorimetric Measurements.

Author

Gassmann, Stefan, Schleifer, Till, and Schuette, Helmut

Subjects

LABS on a chip, DETECTORS, HEAVY metals, POLLUTANTS

Abstract

The infield measurement of nutrients, heavy metals, and other contaminants in water is still a needed tool in environmental sciences. The Lab-on-a-chip approach can develop deployable instruments that use the standardized analytical assay in a miniaturized manner in the field. This paper presents a Lab-on-a-chip platform for colorimetric measurements that can be deployed for nutrient monitoring in open water (oceans, rivers, lakes, etc.). Nitrite was selected as an analyte. Change to other analytes is possible by changing the reagents and the detection wavelength. In this paper, the principle of the sensor, technical realization, setup of the sensor, and test deployment are described. The sensor prototype was deployed at the Jade Bay (German Bight) for 9 h, measuring the nitrite value every 20 min. Reference samples were taken and processed in the lab. The work presented here shows that an infield measurement using a colorimetric assay is possible by applying Lab-on-a-chip principles. [ABSTRACT FROM AUTHOR]

Published

2023

85. Organic Electronics—Microfluidics/Lab on a Chip Integration in Analytical Applications.

Author

Shinar, Ruth and Shinar, Joseph

Subjects

*ORGANIC electronics, *LABS on a chip, *MICROFLUIDICS, *BIO-imaging sensors, *MICROFLUIDIC devices, *GLASS-reinforced plastics, *PHOTODETECTORS

Abstract

Organic electronics (OE) technology has matured in displays and is advancing in solid-state lighting applications. Other promising and growing uses of this technology are in (bio)chemical sensing, imaging, in vitro cell monitoring, and other biomedical diagnostics that can benefit from low-cost, efficient small devices, including wearable designs that can be fabricated on glass or flexible plastic. OE devices such as organic LEDs, organic and hybrid perovskite-based photodetectors, and organic thin-film transistors, notably organic electrochemical transistors, are utilized in such sensing and (bio)medical applications. The integration of compact and sensitive OE devices with microfluidic channels and lab-on-a-chip (LOC) structures is very promising. This survey focuses on studies that utilize this integration for a variety of OE tools. It is not intended to encompass all studies in the area, but to present examples of the advances and the potential of such OE technology, with a focus on microfluidics/LOC integration for efficient wide-ranging sensing and biomedical applications. [ABSTRACT FROM AUTHOR]

Published

2023

86. Electrophoretic Determination of L-Carnosine in Health Supplements Using an Integrated Lab-on-a-Chip Platform with Contactless Conductivity Detection.

Author

Pukleš, Iva, Páger, Csilla, Sakač, Nikola, Šarkanj, Bojan, Matasović, Brunislav, Samardžić, Mirela, Budetić, Mateja, Marković, Dean, and Jozanović, Marija

Subjects

*LABS on a chip, *RF values (Chromatography), *ANALYTICAL chemistry, *MICROCHIP electrophoresis, *INTEGRATED circuits

Abstract

The health supplement industry is one of the fastest growing industries in the world, but there is a lack of suitable analytical methods for the determination of active compounds in health supplements such as peptides. The present work describes an implementation of contactless conductivity detection on microchip technology as a new strategy for the electrophoretic determination of L-carnosine in complex health supplement formulations without pre-concentration and derivatization steps. The best results were obtained in the case of +1.00 kV applied for 20 s for injection and +2.75 kV applied for 260 s for the separation step. Under the selected conditions, a linear detector response of 5 × 10−6 to 5 × 10−5 M was achieved. L-carnosine retention time was 61 s. The excellent reproducibility of both migration time and detector response confirmed the high precision of the method. The applicability of the method was demonstrated by the determination of L-carnosine in three different samples of health supplements. The recoveries ranged from 91 to 105%. Subsequent analysis of the samples by CE-UV-VIS and HPLC-DAD confirmed the accuracy of the obtained results. [ABSTRACT FROM AUTHOR]

Published

2023

87. Electrochemical Sensors for Liquid Biopsy and Their Integration into Lab-on-Chip Platforms: Revolutionizing the Approach to Diseases.

Author

Umme, Salma, Siciliano, Giulia, Primiceri, Elisabetta, Turco, Antonio, Tarantini, Iolena, Ferrara, Francesco, and Chiriacò, Maria Serena

Subjects

ELECTROCHEMICAL sensors, TUMOR markers, BIOPSY, DIAGNOSIS, LIQUIDS, BODY fluids, BIOELECTROCHEMISTRY

Abstract

The screening and early diagnosis of diseases are crucial for a patient's treatment to be successful and to improve their survival rate, especially for cancer. The development of non-invasive analytical methods able to detect the biomarkers of pathologies is a critical point to define a successful treatment and a good outcome. This study extensively reviews the electrochemical methods used for the development of biosensors in a liquid biopsy, owing to their ability to provide a rapid response, precise detection, and low detection limits. We also discuss new developments in electrochemical biosensors, which can improve the specificity and sensitivity of standard analytical procedures. Electrochemical biosensors demonstrate remarkable sensitivity in detecting minute quantities of analytes, encompassing proteins, nucleic acids, and circulating tumor cells, even within challenging matrices such as urine, serum, blood, and various other body fluids. Among the various detection techniques used for the detection of cancer biomarkers, even in the picogram range, voltammetric sensors are deeply discussed in this review because of their advantages and technical characteristics. This widespread utilization stems from their ability to facilitate the quantitative detection of ions and molecules with exceptional precision. A comparison of each electrochemical technique is discussed to assist with the selection of appropriate analytical methods. [ABSTRACT FROM AUTHOR]

Published

2023

88. Emerging microfluidic platforms for crystallization process development.

Author

Chauhan, Rohit, Minocha, Nitin, Coliaie, Paria, Singh, Priyanka G., Korde, Akshay, Kelkar, Manish S., Langston, Marianne, Liu, Chengxiang, Nazemifard, Neda, Patience, Daniel, Skliar, Dimitri, Nere, Nandkishor K., and Singh, Meenesh R.

Subjects

*MICROFLUIDIC devices, *CRYSTALLIZATION, *DRUG discovery, *CRYSTAL growth, *HIGH throughput screening (Drug development), *MICROFLUIDICS

Abstract

The microfluidic platform offers an exclusive environment compatible with different analytical tools to investigate crystallization processes. Moreover, microfluidic devices allow precise and convenient control of crystallization conditions at nano or meso scales, making them suitable for pharmaceutical and energy applications. These miniaturized screening devices can be effective during drug discovery stages for screening active ingredients available on micro/milligram scales. In this review, we discuss the advancements and applications of microfluidics platforms in the development of crystallization processes, including measurement of crystal growth and nucleation rates, screening of co-crystals, polymorphs and morphology, synthesis of nanocrystals, and determination of metastable zones and solubility. In addition, the latest microfluidics setups for high-throughput screening and lab-on-chip enhancements with sensors and automation are presented in this review. Lastly, an outlook on how microfluidic platforms can be adapted to improve workflow in crystallization process development is presented. [Display omitted] • Droplet-based microfluidics and microtiters cannot maintain supersaturation. • Continuous microfluidics with cyclonic flow can maintain supersaturation. • State-of-the-art of microfluidic platforms for crystallization is presented. • Parallel processing can improve the throughput of integrated microfluidics. • Microfluidics can be automated by hybridization with instrumentation and sensors. [ABSTRACT FROM AUTHOR]

Published

2023

89. Early detection and metabolic pathway identification of T cell activation by in-process intracellular mass spectrometry.

Author

Culberson, Austin L., Bowles-Welch, Annie C., Wang, Bryan, Kottke, Peter A., Jimenez, Angela C., Roy, Krishnendu, and Fedorov, Andrei G.

Subjects

*MASS spectrometry, *PSYCHOLOGICAL feedback, *T cells, *CELL differentiation

Abstract

In-process monitoring and control of biomanufacturing workflows remains a significant challenge in the development, production, and application of cell therapies. New process analytical technologies must be developed to identify and control the critical process parameters that govern ex vivo cell growth and differentiation to ensure consistent and predictable safety, efficacy, and potency of clinical products. This study demonstrates a new platform for at-line intracellular analysis of T-cells. Untargeted mass spectrometry analyses via the platform are correlated to conventional methods of T-cell assessment. Spectral markers and metabolic pathways correlated with T-cell activation and differentiation are detected at early time points via rapid, label-free metabolic measurements from a minimal number of cells as enabled by the platform. This is achieved while reducing the analytical time and resources as compared to conventional methods of T-cell assessment. In addition to opportunities for fundamental insight into the dynamics of T-cell processes, this work highlights the potential of in-process monitoring and dynamic feedback control strategies via metabolic modulation to drive T-cell activation, proliferation, and differentiation throughout biomanufacturing. [ABSTRACT FROM AUTHOR]

Published

2023

90. Bio–Microfabrication of 2D and 3D Biomimetic Gut-on-a-Chip.

Author

Jang, Yeongseok, Jung, Jinmu, and Oh, Jonghyun

Subjects

LARGE intestine, SOFT lithography, BIOMIMETIC materials, MANUFACTURING processes, SILICON wafers, SEMICONDUCTOR technology, SEMICONDUCTOR manufacturing

Abstract

Traditional goal of microfabrication was to limitedly construct nano- and micro-geometries on silicon or quartz wafers using various semiconductor manufacturing technologies, such as photolithography, soft lithography, etching, deposition, and so on. However, recent integration with biotechnologies has led to a wide expansion of microfabrication. In particular, many researchers studying pharmacology and pathology are very interested in producing in vitro models that mimic the actual intestine to study the effectiveness of new drug testing and interactions between organs. Various bio–microfabrication techniques have been developed while solving inherent problems when developing in vitro micromodels that mimic the real large intestine. This intensive review introduces various bio–microfabrication techniques that have been used, until recently, to realize two-dimensional and three-dimensional biomimetic experimental models. Regarding the topic of gut chips, two major review subtopics and two-dimensional and three-dimensional gut chips were employed, focusing on the membrane-based manufacturing process for two-dimensional gut chips and the scaffold-based manufacturing process for three-dimensional gut chips, respectively. [ABSTRACT FROM AUTHOR]

Published

2023

91. Advancing Healthcare: Synergizing Biosensors and Machine Learning for Early Cancer Diagnosis.

Author

Kokabi, Mahtab, Tahir, Muhammad Nabeel, Singh, Darshan, and Javanmard, Mehdi

Subjects

BIOSENSORS, CANCER diagnosis, MACHINE learning, EARLY diagnosis, POINT-of-care testing, EARLY detection of cancer, COST control

Abstract

Cancer is a fatal disease and a significant cause of millions of deaths. Traditional methods for cancer detection often have limitations in identifying the disease in its early stages, and they can be expensive and time-consuming. Since cancer typically lacks symptoms and is often only detected at advanced stages, it is crucial to use affordable technologies that can provide quick results at the point of care for early diagnosis. Biosensors that target specific biomarkers associated with different types of cancer offer an alternative diagnostic approach at the point of care. Recent advancements in manufacturing and design technologies have enabled the miniaturization and cost reduction of point-of-care devices, making them practical for diagnosing various cancer diseases. Furthermore, machine learning (ML) algorithms have been employed to analyze sensor data and extract valuable information through the use of statistical techniques. In this review paper, we provide details on how various machine learning algorithms contribute to the ongoing development of advanced data processing techniques for biosensors, which are continually emerging. We also provide information on the various technologies used in point-of-care cancer diagnostic biosensors, along with a comparison of the performance of different ML algorithms and sensing modalities in terms of classification accuracy. [ABSTRACT FROM AUTHOR]

Published

2023

92. Microfluidic devices for the detection of pesticide residues.

Author

Murugesan, Pramila, Raj, Gokul, and Moses, J. A.

Subjects

PESTICIDE residues in food, MICROFLUIDIC devices, PESTICIDE pollution, ENVIRONMENTAL health, PESTICIDES, FLUID flow

Abstract

Pesticides, in various forms, are used for the protection of crops. However, their residues are detrimental to human, animal, and environmental health. Therefore, their detection, monitoring, and control have gained prominent research focus. While most conventional detection techniques demand sophisticated analytical instrumentation, longer processing times, and skill sets, microfluidic devices are increasingly being recognized, given their inherent benefits of miniaturization, lesser sample requirements, portability, and ease of integration, in addition to sensitivity and selectivity. This review provides advances in state-of-the-art microfluidic devices for pesticide detection applications. While key findings of recent studies have been highlighted to better explain their widening application range, the article also provides information on fundamental aspects of fluid flow in microfluidic channels, device fabrication, and system considerations. As a versatile technology, there is ample scope for their integration with other sensing systems, all of which are need-specific. This work also throws light into the techno-economic feasibility, research needs, and prospects for the commercialization of microfluidic systems for pesticide detection applications. [ABSTRACT FROM AUTHOR]

Published

2023

93. Digital twin of surface acoustic wave transceivers for a computational design of an optimal wave guiding layer thickness

Author

Baler, Ufuk Tan, Okyar, Ali Fethi, and Abali, Bilen Emek

Published

2024

94. Maturation of Microfluidic Organic Chemical Analyzers for Sensitive and Selective Detection of Biosignatures and Application to Terrestrial Models of Ocean Worlds

Author

Golozar, Matin

Subjects

Biophysics, Biochemistry, Mechanical engineering, Astrobiology, Biosignature detection, Capillary electrophoresis, Lab-on-a-chip, Microfluidics

Abstract

The potential discovery of extraterrestrial biosignatures within our solar system would represent a transformative milestone, reshaping our understanding of life and our place in the universe. Such a finding would imply that life is not unique to Earth, but is potentially a widespread phenomenon. It would expand our biological knowledge by exploring alternative biochemistries, the evolution of biochemical pathways, and revealing how life adapts to extreme environments. Moreover, it would guide the direction of future space exploration, refining the methodologies used to detect extraterrestrial biosignatures and informing the selection of mission targets.This dissertation contributes to these goals by advancing microfluidic technologies for the most sensitive detection of potential biosignatures in the solar system. Centered on the development, optimization, and application of the Microfluidic Organic Analyzer (MOA), this work introduces an advanced instrument in a compact form, tailored for space-based high-resolution, high-sensitivity chemical analyses. Integrating a Programmable Microfluidic Analyzer (PMA) with a microfabricated glass Capillary Electrophoresis (CE) wafer, the MOA is crafted in a flight-capable, low-mass format. This innovative design enables the precise and sensitive detection of organic biomarkers through laser-induced fluorescence, providing the necessary sensitivity and resolution for a meaningful analysis of habitability and the potential presence of biosignatures, for example, on icy moons such as Europa and Enceladus, as well as on Mars.Key advancements developed here include the refinement of microfabrication techniques for glass microfluidic and CE devices, aligning them with rigorous industrial standards and quality controls required for space flight instrumentation. To achieve high levels of sensitivity and resolution necessary for fluorescence analysis in capillary electrophoresis, excellent quality glass CE wafers need to be designed and fabricated. Stringent quality control protocols have been established to ensure that researchers can reliably achieve the highest precision in fabricating these glass microdevices, a crucial factor in space instrumentation development. Moreover, this dissertation details significant enhancements to the MOA’s fluorescent labeling and detection methodologies, pivotal for identifying trace biosignatures in extraterrestrial environments. The operational readiness of the MOA for space missions has been validated through testing in micro- and hyper-gravity conditions via Zero-G parabolic flights. These tests, along with developed automated protocols on the PMA, facilitate remote, autonomous operation, underscoring the MOA’s ability to perform under the challenging conditions encountered during space exploration.A variety of Earth-based analog sites and samples have been examined to establish a reference framework for interpreting biomarkers detected on icy worlds. By analyzing organic biosignatures in challenging terrestrial environments, such as Antarctic ice cores and geothermal hot springs, this work provides a comparative baseline for extraterrestrial biosignature detection by identifying the identities and concentrations of potential biosignatures that must be detected. The necessity for highly sensitive detection technologies, capable of detecting low picomolar concentrations, is emphasized to enable meaningful measurements even on Earth, where life is abundant in the ecosystem. This level of sensitivity is crucial because extraterrestrial sites that can be examined, much like the most challenging and biosignature-poor sites on Earth, may exhibit only trace amounts of biosignatures. Accordingly, the MOA is meticulously engineered to detect even the subtlest signs of life, aligning with the nuanced complexities of our current understanding of life’s potential distribution across the cosmos.This research enhances the technological readiness of microfluidic systems for planetary exploration, supporting the search for life beyond Earth and potentially changing our understanding of life and biochemical evolution across the cosmos.

Published

2024

95. Towards electrochemical Lab-on-PCB microsystems for sepsis diagnosis

Author

Zupancic, Uros, Moschou, Despina, Estrela, Pedro, and Campbell, John

Subjects

Point of care diagnostics, Sepsis, Electrochemical biosensors, lab-on-a-chip, Lab-on-PCB

Abstract

Sepsis is a life-threatening condition in which the body's immune system becomes dysregulated in response to an infection. This disruption can cause severe organ failure but can be prevented by fast diagnosis and early treatment. Early diagnosis can be achieved by immune system monitoring through quantification of multiple protein biomarkers at the point of care. Electrochemical biosensors (such as diabetes glucose sensors) are a preferred technological solution for this challenge however, protein biomarker quantification often requires multiple sample processing steps which need to be integrated into a miniaturised microsystem to provide a sample-in-answer-out device. Such electrochemical microsystems are not widely available, due to high cost and complexity of their respected manufacturing techniques. In this thesis, this challenge is tackled by utilisation of Lab-on-PCB technology, which explores the integration of multiple sample processing steps with electrochemical biosensors constructed on the same printed circuit board (PCB) platform. The first study explores a new antifouling surface chemistry on planar gold electrodes, enabling detection of sepsis biomarker procalcitonin in whole blood which is validated using clinical samples. In the second study, sensors for two additional sepsis biomarkers were constructed and multiplexed detection was demonstrated in whole blood. In the next study, gold PCB electrodes were physically and electrochemically characterised to ensure electrochemical integrity and their capability to be coupled with biological assays. The following study explored label-free approaches for detection of protein biomarkers using PCB electrodes through redox active self-assembly monolayers as well as simplified surface chemistry. In the last study, the previously described assay, based on antifouling surface chemistry, was transferred to a PCB platform. A PCB-based procalcitonin sensor was integrated with microfluidics and detection in undiluted human serum was achieved in under 17 minutes, with the sensor's response in the clinically relevant concentration range. In conclusion, this thesis serves as a guide for future development of Lab-on-PCB based microsystems describing advantages, challenges, and opportunities associated with the presented technology in the specific case of sepsis diagnosis. Utilisation of this technology could enable low-cost and scalable manufacturing of such diagnostic microsystems, enabling wide adoption and accessibility of sepsis diagnostics tools.

Published

2021

96. A Diagnostic Chip for the Colorimetric Detection of Legionella pneumophila in Less than 3 h at the Point of Need

Author

Katerina Tsougeni, Anastasia Kanioura, Athina S. Kastania, Kosmas Ellinas, Antonios Stellas, Vassilios Constantoudis, Galatios Moschonas, Nikolaos D. Andritsos, Manolis Velonakis, Panagiota S. Petrou, Sotirios E. Kakabakos, Evangelos Gogolides, and Angeliki Tserepi

Subjects

lab-on-a-chip, DNA amplification, colorimetric detection, waterborne bacteria, L. pneumophila, capturing antibodies, Biotechnology, TP248.13-248.65

Abstract

Legionella pneumophila has been pinpointed by the World Health Organization as the highest health burden of all waterborne pathogens in the European Union and is responsible for many disease outbreaks around the globe. Today, standard analysis methods (based on bacteria culturing onto agar plates) need several days (~12) in specialized analytical laboratories to yield results, not allowing for timely actions to prevent outbreaks. Over the last decades, great efforts have been made to develop more efficient waterborne pathogen diagnostics and faster analysis methods, requiring further advancement of microfluidics and sensors for simple, rapid, accurate, inexpensive, real-time, and on-site methods. Herein, a lab-on-a-chip device integrating sample preparation by accommodating bacteria capture, lysis, and DNA isothermal amplification with fast (less than 3 h) and highly sensitive, colorimetric end-point detection of L. pneumophila in water samples is presented, for use at the point of need. The method is based on the selective capture of viable bacteria on on-chip-immobilized and -lyophilized antibodies, lysis, the loop-mediated amplification (LAMP) of DNA, and end-point detection by a color change, observable by the naked eye and semiquantified by computational image analysis. Competitive advantages are demonstrated, such as low reagent consumption, portability and disposability, color change, storage at RT, and compliance with current legislation.

Published

2024

97. Development of a Flexible Sensor-Integrated Tissue Patch to Monitor Early Organ Rejection Processes Using Impedance Spectroscopy

Author

Peter Ertl, Tibor Wladimir, Drago Sticker, Patrick Schuller, Mario Rothbauer, Georg Wieselthaler, and Martin Frauenlob

Subjects

environmental monitoring, nasal epithelial cells, nanotoxicology, lab-on-a-chip, impedance sensors, zinc oxide toxicity, Biotechnology, TP248.13-248.65

Abstract

Heart failure represents a primary cause of hospitalization and mortality in both developed and developing countries, often necessitating heart transplantation as the only viable recovery path. Despite advances in transplantation medicine, organ rejection remains a significant post-operative challenge, traditionally monitored through invasive endomyocardial biopsies (EMB). This study introduces a rapid prototyping approach to organ rejection monitoring via a sensor-integrated flexible patch, employing electrical impedance spectroscopy (EIS) for the non-invasive, continuous assessment of resistive and capacitive changes indicative of tissue rejection processes. Utilizing titanium-dioxide-coated electrodes for contactless impedance sensing, this method aims to mitigate the limitations associated with EMB, including procedural risks and the psychological burden on patients. The biosensor’s design features, including electrode passivation and three-dimensional microelectrode protrusions, facilitate effective monitoring of cardiac rejection by aligning with the heart’s curvature and responding to muscle contractions. Evaluation of sensor performance utilized SPICE simulations, scanning electron microscopy, and cyclic voltammetry, alongside experimental validation using chicken heart tissue to simulate healthy and rejected states. The study highlights the potential of EIS in reducing the need for invasive biopsy procedures and offering a promising avenue for early detection and monitoring of organ rejection, with implications for patient care and healthcare resource utilization.

Published

2024

98. Chitosan as an Alternative to Oil-Based Materials for the Fabrication of Lab-on-a-Chip

Author

Morgane Zimmer, Stéphane Trombotto, Emmanuelle Laurenceau, and Anne-Laure Deman

Subjects

chitosan, lab-on-a-chip, microfluidic, biomaterials, micro-drilling, hot embossing, Mechanical engineering and machinery, TJ1-1570

Abstract

Given the growing importance of lab-on-a-chip in a number of fields, such as medical diagnosis or environmental analysis, the fact that the current fabrication process relies mainly on oil-based polymers raises an ecological concern. As an eco-responsible alternative, we presented, in this article, a manufacturing process for microfluidic devices from chitosan, a bio-sourced, biodegradable, and biocompatible polysaccharide. From chitosan powder, we produced thick and rigid films. To prevent their dissolution and reduce their swelling when in contact with aqueous solutions, we investigated a film neutralization step and characterized the mechanical and physical properties of the resulting films. On these neutralized chitosan films, we compared two micropatterning methods, i.e., hot embossing and mechanical micro-drilling, based on the resolution of microchannels from 100 µm to 1000 µm wide. Then, chitosan films with micro-drilled channels were bonded using a biocompatible dry photoresist on a glass slide or another neutralized chitosan film. Thanks to this protocol, the first functional chitosan microfluidic devices were prepared. While some steps of the fabrication process remain to be improved, these preliminary results pave the way toward a sustainable fabrication of lab-on-a-chip.

Published

2024

99. Editorial: Next generation in vitro models of the human blood - brain/cerebrospinal fluid barrier.

Author

Daughters, Randy S., Julian, Lisa, Knock, Erin, and Willerth, Stephanie M.

Subjects

CEREBROSPINAL fluid, DRUG discovery, CEREBROSPINAL fluid examination, NEURODEGENERATION, HUMAN beings, STEM cells, BLOOD-brain barrier

Published

2024

100. Recent technological advances in lab-on-a-chip for bone remodeling

Author

Seoyeon Kim, Arun Kumar Rajendran, Sivashanmugam Amirthalingam, Jung Hun Kim, Kyoung-Ha So, and Nathaniel S. Hwang

Subjects

Lab-on-a-chip, Biosensors, 3D cell culture, Microfluidics, Imaging techniques, Bone-on-a-chip, Biotechnology, TP248.13-248.65

Abstract

Lab-on-a-chip (LOC) is a three-dimensional cell culture platform with a microfluidic flow that biomimics the physiological system of various organs. LOC emerged as a future replacement technology for in vitro cell-based models and in vivo animal models, gaining popularity in the field of physiology, pharmacology, and biology. Nowadays, sensors are incorporated into the LOC system to monitor real-time parameters of the cell and its microenvironment in response to biophysical and/or biochemical stimuli and maturation. A considerable amount of studies has been conducted to detect the mechanical, physical, electrical, and metabolic parameters of engineered organs. This paper aims to provide a comprehensive insight into how the biosensor-implemented LOC platform can be utilized for the analysis of tissue recapitulating systems with a focus on bone remodeling. We describe chip design, basic principles of sensors, and ongoing recent efforts to perform in-line analysis of engineered organoids. This review also presents various imaging techniques used as analytical tools for visualizing LOC.

Published

2023