Your search keyword '"Ebrahim Ghafar‐Zadeh"' showing total 251 results

1. Performance Analysis of Open-Gate Junction FET: A New Foundry-Based Silicon Transistor for Biochemical Sensing Applications

Author

Abbas Panahi and Ebrahim Ghafar-Zadeh

Subjects

Field-effect transistor (FET), semiconductor, simulation, COMSOL, biosensor, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper investigates the performance and parametric design of a new foundry-based silicon field-effect transistor (FET) sensing platform known as the open-gate junction field-effect transistor (OG-JFET) for bio/chemical sensing applications. The fabrication process of the OG-JFET relies on a standard foundry process, requiring the establishment of parametric design rules to understand the effect of crucial sensor performance factors, including transconductance (g $_{\mathrm {m}}$ ) and device efficiency ( $\eta =$ gm/I $_{\mathrm {ds}}$ ). The study examines the impact of various geometric parameters (e.g., channel length and thickness) and material-related parameters (such as boron and phosphorous impurity doping levels) on sensor performance. Simulations provide insights and guidelines for the efficient design and characterization of the OG-JFET, focusing on enhancing gm and maximizing $\eta $ for biosensing applications. Experimental measurements of the OG-JFET demonstrate a current range of $\sim ~200~\mu $ A/ $\mu $ m, a high gm of approximately $\sim ~1700~\mu $ S ( $340~\mu $ S/ $\mu $ m), and $\eta $ of $\sim ~4.5$ V−1 (for a channel length of $5~\mu $ m), which are of importance for circuit design and biosensing application of OG-JFET. These results showcase the performance of this sensor compared to other silicon-based FET platforms for internal signal amplification in sensing applications of OG-JFET. The findings of this paper offer valuable guidelines for the design of sensors based on OG-JFET technology, enabling gaining insights into the impact of sensor structure on sensing performance. Also, we have demonstrated how two performance parameters can be utilized to compare two different designs of OG-JFET, which is useful for future designers.

Published

2024

2. CMOS Point-of-Care Diagnostics Technologies: Recent Advances and Future Prospects

Author

Tania Moeinfard, Ebrahim Ghafar-Zadeh, and Sebastian Magierowski

Subjects

point-of-care (PoC), CMOS technology, biomedical integrated circuits (ICs), bioimpedance spectroscopy, SARS-CoV-2 diagnostics, glucose monitoring, Mechanical engineering and machinery, TJ1-1570

Abstract

This review provides a comprehensive overview of point-of-care (PoC) devices across several key diagnostic applications, including blood analysis, infectious disease detection, neural interfaces, and commercialized integrated circuits (ICs). In the blood analysis section, the focus is on biomarkers such as glucose, dopamine, and aptamers, and their respective detection techniques. The infectious disease section explores PoC technologies for detecting pathogens, RNA, and DNA, highlighting innovations in molecular diagnostics. The neural interface section reviews advancements in neural recording and stimulation for therapeutic applications. Finally, a survey of commercialized ICs from companies such as Abbott and Medtronic is presented, showcasing existing PoC devices already in widespread clinical use. This review emphasizes the role of complementary metal-oxide-semiconductor (CMOS) technology in enabling compact, efficient diagnostic systems and offers insights into the current and future landscape of PoC devices.

Published

2024

3. Complementary Metal–Oxide–Semiconductor-Based Magnetic and Optical Sensors for Life Science Applications

Author

Tayebeh Azadmousavi and Ebrahim Ghafar-Zadeh

Subjects

CMOS, optical sensors, magnetic sensors, PoC diagnostic, Chemical technology, TP1-1185

Abstract

Optical and magnetic sensing methods are integral to both research and clinical applications in biological laboratories. The ongoing miniaturization of these sensors has paved the way for the development of point-of-care (PoC) diagnostics and handheld sensing devices, which are crucial for timely and efficient healthcare delivery. Among the various competing sensing and circuit technologies, CMOS (complementary metal–oxide–semiconductor) stands out due to its distinct cost-effectiveness, scalability, and high precision. By leveraging the inherent advantages of CMOS technology, recent developments in optical and magnetic biosensors have significantly advanced their application in life sciences, offering improved sensitivity, integration capabilities, and reduced power consumption. This paper provides a comprehensive review of recent advancements, focusing on innovations in CMOS-based optical and magnetic sensors and their transformative impact on biomedical research and diagnostics.

Published

2024

4. Toward Digital Periodontal Health: Recent Advances and Future Perspectives

Author

Fatemeh Soheili, Niloufar Delfan, Negin Masoudifar, Shahin Ebrahimni, Behzad Moshiri, Michael Glogauer, and Ebrahim Ghafar-Zadeh

Subjects

periodontal disease, periodontitis, systemic disorders, artificial intelligence, deep neural network, medical imaging, Technology, Biology (General), QH301-705.5

Abstract

Periodontal diseases, ranging from gingivitis to periodontitis, are prevalent oral diseases affecting over 50% of the global population. These diseases arise from infections and inflammation of the gums and supporting bones, significantly impacting oral health. The established link between periodontal diseases and systemic diseases, such as cardiovascular diseases, underscores their importance as a public health concern. Consequently, the early detection and prevention of periodontal diseases have become critical objectives in healthcare, particularly through the integration of advanced artificial intelligence (AI) technologies. This paper aims to bridge the gap between clinical practices and cutting-edge technologies by providing a comprehensive review of current research. We examine the identification of causative factors, disease progression, and the role of AI in enhancing early detection and treatment. Our goal is to underscore the importance of early intervention in improving patient outcomes and to stimulate further interest among researchers, bioengineers, and AI specialists in the ongoing exploration of AI applications in periodontal disease diagnosis.

Published

2024

5. A Multidisciplinary Approach toward CMOS Capacitive Sensor Array for Droplet Analysis

Author

Hamed Osouli Tabrizi, Saghi Forouhi, Tayebeh Azadmousavi, and Ebrahim Ghafar-Zadeh

Subjects

CMOS, capacitive sensor, droplet analysis, life science applications, time of evaporation, Mechanical engineering and machinery, TJ1-1570

Abstract

This paper introduces an innovative method for the analysis of alcohol–water droplets on a CMOS capacitive sensor, leveraging the controlled thermal behavior of the droplets. Using this sensing method, the capacitive sensor measures the total time of evaporation (ToE), which can be influenced by the droplet volume, temperature, and chemical composition. We explored this sensing method by introducing binary mixtures of water and ethanol or methanol across a range of concentrations (0–100%, with 10% increments). The experimental results indicate that while the capacitive sensor is effective in measuring both the total ToE and dielectric properties, a higher dynamic range and resolution are observed in the former. Additionally, an array of sensing electrodes successfully monitors the droplet–sensor surface interaction. However practical considerations such as the creation of parasitic capacitance due to mismatch, arise from the large sensing area in the proposed capacitive sensors and other similar devices. In this paper, we discuss this non-ideality and propose a solution. Also, this paper showcases the benefits of utilizing a CMOS capacitive sensing method for accurately measuring ToE.

Published

2024

6. CoVSense: Ultrasensitive Nucleocapsid Antigen Immunosensor for Rapid Clinical Detection of Wildtype and Variant SARS‐CoV‐2

Author

Razieh Salahandish, Jae Eun Hyun, Fatemeh Haghayegh, Hamed Osouli Tabrizi, Shirin Moossavi, Sultan Khetani, Giancarlo Ayala‐Charca, Byron M. Berenger, Yan Dong Niu, Ebrahim Ghafar‐Zadeh, and Amir Sanati Nezhad

Subjects

clinical investigation, electrochemical nanobiosensors, graphene nanosheets, point‐of‐care diagnostics, Science

Abstract

Abstract The widespread accessibility of commercial/clinically‐viable electrochemical diagnostic systems for rapid quantification of viral proteins demands translational/preclinical investigations. Here, Covid‐Sense (CoVSense) antigen testing platform; an all‐in‐one electrochemical nano‐immunosensor for sample‐to‐result, self‐validated, and accurate quantification of the severe acute respiratory syndrome coronavirus 2 (SARS‐CoV‐2) nucleocapsid (N)‐proteins in clinical examinations is developed. The platform's sensing strips benefit from a highly‐sensitive, nanostructured surface, created through the incorporation of carboxyl‐functionalized graphene nanosheets, and poly(3,4‐ethylenedioxythiophene) polystyrene sulfonate (PEDOT:PSS) conductive polymers, enhancing the overall conductivity of the system. The nanoengineered surface chemistry allows for compatible direct assembly of bioreceptor molecules. CoVSense offers an inexpensive (

Published

2023

7. Design and Analysis of a Low-Voltage VCO: Reliability and Variability Performance

Author

Tayebeh Azadmousavi and Ebrahim Ghafar-Zadeh

Subjects

VCO, threshold voltage, electron mobility, low voltage, phase noise, Mechanical engineering and machinery, TJ1-1570

Abstract

This paper investigates an adaptive body biasing (ABB) circuit to improve the reliability and variability of a low-voltage inductor–capacitor (LC) voltage-controlled oscillator (VCO). The ABB circuit provides VCO resilience to process variability and reliability variation through the threshold voltage adjustment of VCO’s transistors. Analytical equations considering the body bias effect are derived for the most important relations of the VCO and then the performance is verified using the post-layout simulation results. Under a 0.16% threshold voltage shift, the sensitivity of the normalized phase noise and transconductance of the VCO with the ABB circuit compared to the constant body bias (CBB) decreases by around 8.4 times and 3.1 times, respectively. Also, the sensitivity of the normalized phase noise and transconductance of the proposed VCO under 0.16% mobility variations decreases by around 1.5 times and 1.7 times compared to the CBB, respectively. The robustness of the VCO is also examined using process variation analysis through Monte Carlo and corner case simulations. The post-layout results in the 180 nm CMOS process indicate that the proposed VCO draws a power consumption of only 398 µW from a 0.6 V supply when the VCO frequency is 2.4 GHz. It achieves a phase noise of −123.19 dBc/Hz at a 1 MHz offset and provides a figure of merit (FoM) of −194.82 dBc/Hz.

Published

2023

8. Emerging Field-Effect Transistor Biosensors for Life Science Applications

Author

Abbas Panahi and Ebrahim Ghafar-Zadeh

Subjects

n/a, Technology, Biology (General), QH301-705.5

Abstract

Field-effect transistors (FETs) have gained significant interest and hold great potential as groundbreaking sensing technology in the fields of biosensing and life science research [...]

Published

2023

9. A Scalable Discrete-Time Integrated CMOS Readout Array for Nanopore Based DNA Sequencing

Author

Yunus Dawji, Mehdi Habibi, Ebrahim Ghafar-Zadeh, and Sebastian Magierowski

Subjects

DNA, nanopore, continuous-time, ammeter, low noise, amplifier, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper introduces a high-speed mixed-signal readout array in 130-nm CMOS for the amplification and digitization of picoampere-range signals. Its design is inspired by the needs of emerging DNA sequencing technologies based on biological nanopore sensors. To overcome switching and substrate noise this system adopts an in-pixel analog-to-digital converter (ADC) architecture and a novel readout technique while consuming 10x less power than similar designs described in the literature. The in-pixel ADC architecture is inherently scalable and immune to electrical interference which can be extended to 100s of channels. With a 5 pF input capacitance, the amplifiers achieve a maximum bandwidth of 100 kHz and demonstrate a noise floor as low as 4 fA/ $\sqrt {\text{Hz}}$ and a gain in the range of $\text{G}\Omega $ at 10 kHz. Circuit noise behaviour and theoretical maximum performance estimates using behavioural models are also discussed.

Published

2021

10. Oral Cells-On-Chip: Design, Modeling and Experimental Results

Author

Hamed Osouli Tabrizi, Abbas Panahi, Saghi Forouhi, Deniz Sadighbayan, Fatemeh Soheili, Mohammad Reza Haji Hosseini Khani, Sebastian Magierowski, and Ebrahim Ghafar-Zadeh

Subjects

capacitive sensor, complementary metal-oxide-semiconductor, oral epithelial cells, oral neutrophils, saliva, Technology, Biology (General), QH301-705.5

Abstract

Recent advances in periodontal studies have attracted the attention of researchers to the relation between oral cells and gum diseases, which is a real threat to overall human health. Among various microfabrication technologies, Complementary Metal Oxide Semiconductors (CMOSs) enable the development of low-cost integrated sensors and circuits for rapid and accurate assessment of living cells that can be employed for the early detection and control of periodontal diseases. This paper presents a CMOS capacitive sensing platform that can be considered as an alternative for the analysis of salivatory cells such as oral neutrophils. This platform consists of two sensing electrodes connected to a read-out capacitive circuitry designed and fabricated on the same chip using Austria Mikro Systeme (AMS) 0.35 µm CMOS process. A graphical user interface (GUI) was also developed to interact with the capacitive read-out system and the computer to monitor the capacitance changes due to the presence of saliva cells on top of the chip. Thanks to the wide input dynamic range (IDR) of more than 400 femto farad (fF) and high resolution of 416 atto farad (aF), the experimental and simulation results demonstrate the functionality and applicability of the proposed sensor for monitoring cells in a small volume of 1 µL saliva samples. As per these results, the hydrophilic adhesion of oral cells on the chip varies the capacitance of interdigitated electrodes (IDEs). These capacitance changes then give an assessment of the oral cells existing in the sample. In this paper, the simulation and experimental results set a new stage for emerging sensing platforms for testing oral samples.

Published

2022

11. A Hybrid Microfluidic Electronic Sensing Platform for Life Science Applications

Author

Abbas Panahi and Ebrahim Ghafar-Zadeh

Subjects

microfluidics, biosensor, ISFET, field-effect transistor, integrated biosensor, packaging, Mechanical engineering and machinery, TJ1-1570

Abstract

This paper presents a novel hybrid microfluidic electronic sensing platform, featuring an electronic sensor incorporated with a microfluidic structure for life science applications. This sensor with a large sensing area of 0.7 mm2 is implemented through a foundry process called Open-Gate Junction FET (OG-JFET). The proposed OG-JFET sensor with a back gate enables the charge by directly introducing the biological and chemical samples on the top of the device. This paper puts forward the design and implementation of a PDMS microfluidic structure integrated with an OG-JFET chip to direct the samples toward the sensing site. At the same time, the sensor’s gain is controlled with a back gate electrical voltage. Herein, we demonstrate and discuss the functionality and applicability of the proposed sensing platform using a chemical solution with different pH values. Additionally, we introduce a mathematical model to describe the charge sensitivity of the OG-JFET sensor. Based on the results, the maximum value of transconductance gain of the sensor is ~1 mA/V at Vgs = 0, which is decreased to ~0.42 mA/V at Vgs = 1, all in Vds = 5. Furthermore, the variation of the back-gate voltage from 1.0 V to 0.0 V increases the sensitivity from ~40 mV/pH to ~55 mV/pH. As per the experimental and simulation results and discussions in this paper, the proposed hybrid microfluidic OG-JFET sensor is a reliable and high-precision measurement platform for various life science and industrial applications.

Published

2022

12. Electronic Sensing Platform (ESP) Based on Open-Gate Junction Field-Effect Transistor (OG-JFET) for Life Science Applications: Design, Modeling and Experimental Results

Author

Abbas Panahi, Deniz Sadighbayan, and Ebrahim Ghafar-Zadeh

Subjects

field-effect transistor (FET), biosensor, DNA sensor, oral neutrophil, ISFET, BioFET, Chemical technology, TP1-1185

Abstract

This paper presents a new field-effect sensor called open-gate junction gate field-effect transistor (OG-JFET) for biosensing applications. The OG-JFET consists of a p-type channel on top of an n-type layer in which the p-type serves as the sensing conductive layer between two ohmic contacted sources and drain electrodes. The structure is novel as it is based on a junction field-effect transistor with a subtle difference in that the top gate (n-type contact) has been removed to open the space for introducing the biomaterial and solution. The channel can be controlled through a back gate, enabling the sensor’s operation without a bulky electrode inside the solution. In this research, in order to demonstrate the sensor’s functionality for chemical and biosensing, we tested OG-JFET with varying pH solutions, cell adhesion (human oral neutrophils), human exhalation, and DNA molecules. Moreover, the sensor was simulated with COMSOL Multiphysics to gain insight into the sensor operation and its ion-sensitive capability. The complete simulation procedures and the physics of pH modeling is presented here, being numerically solved in COMSOL Multiphysics software. The outcome of the current study puts forward OG-JFET as a new platform for biosensing applications.

Published

2021

13. UV-Vis Spectrophotometric Analysis of DNA Retrieval for DNA Storage Applications

Author

Aamir Minhas-Khan, Morteza Ghafar-Zadeh, Tina Shaffaf, Saghi Forouhi, Anthony Scime, Sebastian Magierowski, and Ebrahim Ghafar-Zadeh

Subjects

DNA storage, UV-Vis spectrophotometer, DNA retrieval, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

Informational Deoxyribonucleic Acid (iDNA) has gained the attention of many researchers and pioneer companies for the development of novel storage systems for the long-term and high-density storing of information. This research focuses on the physical storage of iDNA strands to address some of the current challenges by evaluating the accuracy of the process of iDNA retrieval from the surface after the dehydration process. For this aim, a UV-Vis spectrophotometric technique was used to measure the concentration of the DNA samples. Although spectroscopy has been widely employed for the evaluation of DNA concentration and contamination in a solution, it has not been used to investigate dry-state DNA, which is one of the preferred storage formats for the long-term retention of information. These results demonstrate that the UV-Vis spectrophotometric technique can be used to accurately measure dry-state DNA before the retrieval and its residues after the DNA retrieval process. This paper further examines the storage/retrieval process by investigating the relationship between the storage time and the amount of retrieved DNA or the DNA residue left on various surfaces. Based on the experimental results demonstrated and discussed in this paper, UV-Vis spectrophotometry can be used for monitoring dry-state DNA with a high accuracy larger than 98%. Moreover, these results reveal that the hydrophilicity and hydrophobicity of the surface do not significantly affect DNA retrieval over a one-month time period.

Published

2021

14. Towards Fully Integrated Portable Sensing Devices for COVID-19 and Future Global Hazards: Recent Advances, Challenges, and Prospects

Author

Tina Shaffaf, Saghi Forouhi, and Ebrahim Ghafar-Zadeh

Subjects

CMOS technology, COVID-19, point-of-care, portable sensing devices, Mechanical engineering and machinery, TJ1-1570

Abstract

Since the onset of the coronavirus disease 2019 (COVID-19) pandemic, this fatal disease has been the leading cause of the death of more than 3.9 million people around the world. This tragedy taught us that we should be well-prepared to control the spread of such infectious diseases and prevent future hazards. As a consequence, this pandemic has drawn the attention of many researchers to the development of portable platforms with short hands-on and turnaround time suitable for batch production in urgent pandemic situations such as that of COVID-19. Two main groups of diagnostic assays have been reported for the detection of Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) including nucleic acid-based and protein-based assays. The main focus of this paper is on the latter, which requires a shorter time duration, less skilled technicians, and faces lower contamination. Furthermore, this paper gives an overview of the complementary metal-oxide-semiconductor (CMOS) biosensors, which are potentially useful for implementing point-of-care (PoC) platforms based on such assays. CMOS technology, as a predominant technology for the fabrication of integrated circuits, is a promising candidate for the development of PoC devices by offering the advantages of reliability, accessibility, scalability, low power consumption, and distinct cost.

Published

2021

15. Recent Advances of Field-Effect Transistor Technology for Infectious Diseases

Author

Abbas Panahi, Deniz Sadighbayan, Saghi Forouhi, and Ebrahim Ghafar-Zadeh

Subjects

field effect transistor, biosensor, infectious disease, COVID-19, label-free detection, CMOS-based readout circuit, Biotechnology, TP248.13-248.65

Abstract

Field-effect transistor (FET) biosensors have been intensively researched toward label-free biomolecule sensing for different disease screening applications. High sensitivity, incredible miniaturization capability, promising extremely low minimum limit of detection (LoD) at the molecular level, integration with complementary metal oxide semiconductor (CMOS) technology and last but not least label-free operation were amongst the predominant motives for highlighting these sensors in the biosensor community. Although there are various diseases targeted by FET sensors for detection, infectious diseases are still the most demanding sector that needs higher precision in detection and integration for the realization of the diagnosis at the point of care (PoC). The COVID-19 pandemic, nevertheless, was an example of the escalated situation in terms of worldwide desperate need for fast, specific and reliable home test PoC devices for the timely screening of huge numbers of people to restrict the disease from further spread. This need spawned a wave of innovative approaches for early detection of COVID-19 antibodies in human swab or blood amongst which the FET biosensing gained much more attention due to their extraordinary LoD down to femtomolar (fM) with the comparatively faster response time. As the FET sensors are promising novel PoC devices with application in early diagnosis of various diseases and especially infectious diseases, in this research, we have reviewed the recent progress on developing FET sensors for infectious diseases diagnosis accompanied with a thorough discussion on the structure of Chem/BioFET sensors and the readout circuitry for output signal processing. This approach would help engineers and biologists to gain enough knowledge to initiate their design for accelerated innovations in response to the need for more efficient management of infectious diseases like COVID-19.

Published

2021

16. COVID-19 Diagnostic Strategies. Part I: Nucleic Acid-Based Technologies

Author

Tina Shaffaf and Ebrahim Ghafar-Zadeh

Subjects

COVID-19 diagnostics, NA-based tests, SARS-CoV-2, point-of-care (PoC) detection, polymerase chain reaction (PCR), sequencing, microarray, Technology, Biology (General), QH301-705.5

Abstract

The novel Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) has caused respiratory infection, resulting in more than two million deaths globally and hospitalizing thousands of people by March 2021. A considerable percentage of the SARS-CoV-2 positive patients are asymptomatic or pre-symptomatic carriers, facilitating the viral spread in the community by their social activities. Hence, it is critical to have access to commercialized diagnostic tests to detect the infection in the earliest stages, monitor the disease, and follow up the patients. Various technologies have been proposed to develop more promising assays and move toward the mass production of fast, reliable, cost-effective, and portable PoC diagnostic tests for COVID-19 detection. Not only COVID-19 but also many other pathogens will be able to spread and attach to human bodies in the future. These technologies enable the fast identification of high-risk individuals during future hazards to support the public in such outbreaks. This paper provides a comprehensive review of current technologies, the progress in the development of molecular diagnostic tests, and the potential strategies to facilitate innovative developments in unprecedented pandemics.

Published

2021

17. COVID-19 Diagnostic Strategies Part II: Protein-Based Technologies

Author

Tina Shaffaf and Ebrahim Ghafar-Zadeh

Subjects

COVID-19 detection, protein-based tests, SARS-CoV-2, point-of-care (POC) detection, serological tests, antigenic tests, Technology, Biology (General), QH301-705.5

Abstract

After the initiation of the current outbreak, humans’ lives have been profoundly impacted by COVID-19. During the first months, no rapid and reliable detecting tool was readily available to sufficiently respond to the requirement of massive testing. In this situation, when the development of an effective vaccine requires at least a few months, it is crucial to be prepared by developing and commercializing affordable, accurate, rapid and adaptable biosensors not only to fight Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) but also to be armed to avoid the pandemic in the earliest stages in the future. The COVID-19 diagnostic tools are categorized into two main groups of Nucleic Acid (NA)-based and protein-based tests. To date, nucleic acid-based detection has been announced as the gold-standard strategy for coronavirus detection; however, protein-based tests are promising alternatives for rapid and large-scale screening of susceptible groups. In this review, we discuss the current protein-based biosensing tools, the research advances and the potential protein-detecting strategies for COVID-19 detection. This narrative review aims to highlight the importance of the diagnostic tests, encourage the academic research groups and the companies to eliminate the shortcomings of the current techniques and step forward to mass-producing reliable point-of-care (POC) and point-of-need (PON) adaptable diagnostic tools for large-scale screening in the future outbreaks.

Published

2021

18. Biointerface Materials for Cellular Adhesion: Recent Progress and Future Prospects

Author

John V. L. Nguyen and Ebrahim Ghafar-Zadeh

Subjects

analytical instrumentation, bioactuator, biointerface, biological adhesion, biomaterials, biosensor, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

While many natural instances of adhesion between cells and biological macromolecules have been elucidated, understanding how to mimic these adhesion events remains to be a challenge. Discovering new biointerface materials that can provide an appropriate environment, and in some cases, also providing function similar to the body’s own extracellular matrix, would be highly beneficial to multiple existing applications in biomedical and biological engineering, and provide the necessary insight for the advancement of new technology. Such examples of current applications that would benefit include biosensors, high-throughput screening and tissue engineering. From a mechanical perspective, these biointerfaces would function as bioactuators that apply focal adhesion points onto cells, allowing them to move and migrate along a surface, making biointerfaces a very relevant application in the field of actuators. While it is evident that great strides in progress have been made in the area of synthetic biointerfaces, we must also acknowledge their current limitations as described in the literature, leading to an inability to completely function and dynamically respond like natural biointerfaces. In this review, we discuss the methods, materials and, possible applications of biointerface materials used in the current literature, and the trends for future research in this area.

Published

2020

19. Applications of CMOS Devices for the Diagnosis and Control of Infectious Diseases

Author

Saghi Forouhi and Ebrahim Ghafar-Zadeh

Subjects

infectious disease, CMOS technology, point-of-care, lab-on-chip, Mechanical engineering and machinery, TJ1-1570

Abstract

Emerging infectious diseases such as coronavirus disease of 2019 (COVID-19), Ebola, influenza A, severe acute respiratory syndrome (SARS) and Middle East respiratory syndrome (MERS) in recent years have threatened the health and security of the global community as one of the greatest factors of mortality in the world. Accurate and immediate diagnosis of infectious agents and symptoms is a key to control the outbreak of these diseases. Rapid advances in complementary metal-oxide-semiconductor (CMOS) technology offers great advantages like high accuracy, high throughput and rapid measurements in biomedical research and disease diagnosis. These features as well as low cost, low power and scalability of CMOS technology can pave the way for the development of powerful devices such as point-of-care (PoC) systems, lab-on-chip (LoC) platforms and symptom screening devices for accurate and timely diagnosis of infectious diseases. This paper is an overview of different CMOS-based devices such as optical, electrochemical, magnetic and mechanical sensors developed by researchers to mitigate the problems associated with these diseases.

Published

2020

20. A New Non-Invasive Air-Based Actuator for Characterizing and Testing MEMS Devices

Author

Abbas Panahi, Mohammad Hossein Sabour, and Ebrahim Ghafar-Zadeh

Subjects

MEMS, automatic testing equipment (ATE), MEMS Testing, characterization, MEMS sensors, microcantilever, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

This research explores a new ATE (Automatic Testing Equipment) method for Micro Electro Mechanical Systems (MEMS) devices. In this method, microscale aerodynamic drag force is generated on a movable part of a MEMS sensor from a micronozzle hole located a specific distance above the chip that will result in a measurable change in output. This approach has the potential to be generalized for the characterization of every MEMS device in mass production lines to test the functionality of devices rapidly and characterize important mechanical properties. The most important testing properties include the simultaneous application of controllable and non-invasive manipulative force, a single handler for multi-sensor, and non-contact characterization, which are relatively difficult to find with other contemporary approaches. Here we propose a custom-made sensing platform consisting of a microcantilever array interconnected to a data acquisition device to read the capacitive effects of each cantilever’s deflection caused by air drag force. This platform allows us to empirically prove the functionality and applicability of the proposed characterization method using airflow force stimuli. The results, stimulatingly, exhibited that air force from a hole of 5 µm radii located 25 µm above a 200 × 200 µm2 surface could be focused on a circular spot with radii of approximately 5 µm with surface sweep accuracy of

Published

2020

21. An Apta-Biosensor for Colon Cancer Diagnostics

Author

Mojgan Ahmadzadeh Raji, Ghasem Amoabediny, Parviz Tajik, Morteza Hosseini, and Ebrahim Ghafar-Zadeh

Subjects

aptasensor, aptamer, cyclic voltammetry (CV), colon cancer, biosensor, fluorescence labeling, Chemical technology, TP1-1185

Abstract

This paper reports the design and implementation of an aptasensor using a modified KCHA10a aptamer. This aptasensor consists of a functionalized electrodes using various materials including 11-mercaptoandecanoic acid (11-MUA) and modified KCHA10a aptamer. The HCT 116, HT 29 and HEp-2 cell lines are used in this study to demonstrate the functionality of aptasensor for colon cancer detection purposes. Flow cytometry, fluorescence microscopy and electrochemical cyclic voltammetry are used to verify the binding between the target cells and aptamer. The limit of detection (LOD) of this aptasensor is equal to seven cancer cells. Based on the experimental results, the proposed sensor can be employed for point-of-care cancer disease diagnostics.

Published

2015

22. Toward Epileptic Brain Region Detection Based on Magnetic Nanoparticle Patterning

Author

Maysam Z. Pedram, Amir Shamloo, Aria Alasty, and Ebrahim Ghafar-Zadeh

Subjects

epilepsy, brain magnetic field, magnetic nanoparticle, Chemical technology, TP1-1185

Abstract

Resection of the epilepsy foci is the best treatment for more than 15% of epileptic patients or 50% of patients who are refractory to all forms of medical treatment. Accurate mapping of the locations of epileptic neuronal networks can result in the complete resection of epileptic foci. Even though currently electroencephalography is the best technique for mapping the epileptic focus, it cannot define the boundary of epilepsy that accurately. Herein we put forward a new accurate brain mapping technique using superparamagnetic nanoparticles (SPMNs). The main hypothesis in this new approach is the creation of super-paramagnetic aggregates in the epileptic foci due to high electrical and magnetic activities. These aggregates may improve tissue contrast of magnetic resonance imaging (MRI) that results in improving the resection of epileptic foci. In this paper, we present the mathematical models before discussing the simulation results. Furthermore, we mimic the aggregation of SPMNs in a weak magnetic field using a low-cost microfabricated device. Based on these results, the SPMNs may play a crucial role in diagnostic epilepsy and the subsequent treatment of this disease.

Published

2015

23. Wireless Integrated Biosensors for Point-of-Care Diagnostic Applications

Author

Ebrahim Ghafar-Zadeh

Subjects

CMOS, point-of-care (POC), wireless biosensors (WBS), integrated electrochemical sensors, Chemical technology, TP1-1185

Abstract

Recent advances in integrated biosensors, wireless communication and power harvesting techniques are enticing researchers into spawning a new breed of point-of-care (POC) diagnostic devices that have attracted significant interest from industry. Among these, it is the ones equipped with wireless capabilities that drew our attention in this review paper. Indeed, wireless POC devices offer a great advantage, that of the possibility of exerting continuous monitoring of biologically relevant parameters, metabolites and other bio-molecules, relevant to the management of various morbid diseases such as diabetes, brain cancer, ischemia, and Alzheimer’s. In this review paper, we examine three major categories of miniaturized integrated devices, namely; the implantable Wireless Bio-Sensors (WBSs), the wearable WBSs and the handheld WBSs. In practice, despite the aforesaid progress made in developing wireless platforms, early detection of health imbalances remains a grand challenge from both the technological and the medical points of view. This paper addresses such challenges and reports the state-of-the-art in this interdisciplinary field.

Published

2015

24. Recent Advances of Computerized Graphical Methods for the Detection and Progress Assessment of Visual Distortion Caused by Macular Disorders

Author

Navid Mohaghegh, Ebrahim Ghafar-Zadeh, and Sebastian Magierowski

Subjects

macular disorders, central serous retinopathy (CSR), graphical macular interface system (GMIS), age-related macular degeneration (AMD), Biology (General), QH301-705.5

Abstract

Recent advances of computerized graphical methods have received significant attention for detection and home monitoring of various visual distortions caused by macular disorders such as macular edema, central serous chorioretinopathy, and age-related macular degeneration. After a brief review of macular disorders and their conventional diagnostic methods, this paper reviews such graphical interface methods including computerized Amsler Grid, Preferential Hyperacuity Perimeter, and Three-dimensional Computer-automated Threshold Amsler Grid. Thereafter, the challenges of these computerized methods for accurate and rapid detection of macular disorders are discussed. The early detection and progress assessment of macular disorders can significantly enhance the required clinical procedure for the diagnosis and treatment of macular disorders.

Published

2019

25. A Multidisciplinary Approach toward High Throughput Label-Free Cytotoxicity Monitoring of Superparamagnetic Iron Oxide Nanoparticles

Author

Sonia Abad Tan, Georg Zoidl, and Ebrahim Ghafar-Zadeh

Subjects

SPIONs, high-throughput, viability, neuroblastoma 2A, impedance-based assay, Technology, Biology (General), QH301-705.5

Abstract

This paper focuses on cytotoxicity examination of superparamagnetic iron oxide nanoparticles (SPIONs) using different methods, including impedance spectroscopy. Recent advances of SPIONs for clinical and research applications have triggered the need to understand their effects in cells. Despite the great advances in adapting various biological and chemical methods to assess in-vitro toxicity of SPIONs, less attention has been paid on the development of a high throughput label-free screening platform to study the interaction between the cells and nanoparticles including SPIONs. In this paper, we have taken the first step toward this goal by proposing a label-free impedimetric method for monitoring living cells treated with SPIONs. We demonstrate the effect of SPIONs on the adhesion, growth, proliferation, and viability of neuroblastoma 2A (N2a) cells using impedance spectroscopy as a label-free method, along with other standard microscopic and cell viability testing methods as control methods. Our results have shown a decreased viability of the cells as the concentration of SPIONs increases with percentages of 59%, 47%, and 40% for 100 µg/mL (C4), 200 µg/mL (C5), 300 µg/mL (C6), respectively. Although all SPIONs concentrations have allowed the growth of cells within 72 h, C4, C5, and C6 showed slower growth compared to the control (C1). The growth and proliferation of N2a cells are faster in the absence or low concentration of SPIONS. The percent coefficient of variation (% CV) was used to compare cell concentrations obtained by TBDE assay and a Scepter cell counter. Results also showed that the lower the SPIONs concentration, the lower the impedance is expected to be in the sensing electrodes without the cells. Meanwhile, the variation of surface area (∆S) was affected by the concentration of SPIONs. It was observed that the double layer capacitance was almost constant because of the higher attachment of cells, the lower surface area coated by SPIONs. In conclusion, impedance changes of electrodes exposed to the mixture of cells and SPIONs offer a wide dynamic range (>1 MΩ using Electric Cell-substrate Impedance electrodes) suitable for cytotoxicity studies. Based on impedance based, viability testing and microscopic methods’ results, SPIONs concentrations higher than 100 ug/mL and 300 ug/mL cause minor and major effects, respectively. We propose that a high throughput impedance-based label-free platform provides great advantages for studying SPIONs in a cell-based context, opening a window of opportunity to design and test the next generation of SPIONs with reduced toxicity for biomedical or medical applications.

Published

2019

26. Toward High Throughput Core-CBCM CMOS Capacitive Sensors for Life Science Applications: A Novel Current-Mode for High Dynamic Range Circuitry

Author

Saghi Forouhi, Rasoul Dehghani, and Ebrahim Ghafar-Zadeh

Subjects

CMOS, capacitive sensor, CBCM, dynamic range, bioengineering, Chemical technology, TP1-1185

Abstract

This paper proposes a novel charge-based Complementary Metal Oxide Semiconductor (CMOS) capacitive sensor for life science applications. Charge-based capacitance measurement (CBCM) has significantly attracted the attention of researchers for the design and implementation of high-precision CMOS capacitive biosensors. A conventional core-CBCM capacitive sensor consists of a capacitance-to-voltage converter (CVC), followed by a voltage-to-digital converter. In spite of their high accuracy and low complexity, their input dynamic range (IDR) limits the advantages of core-CBCM capacitive sensors for most biological applications, including cellular monitoring. In this paper, after a brief review of core-CBCM capacitive sensors, we address this challenge by proposing a new current-mode core-CBCM design. In this design, we combine CBCM and current-controlled oscillator (CCO) structures to improve the IDR of the capacitive readout circuit. Using a 0.18 μm CMOS process, we demonstrate and discuss the Cadence simulation results to demonstrate the high performance of the proposed circuitry. Based on these results, the proposed circuit offers an IDR ranging from 873 aF to 70 fF with a resolution of about 10 aF. This CMOS capacitive sensor with such a wide IDR can be employed for monitoring cellular and molecular activities that are suitable for biological research and clinical purposes.

Published

2018

27. An Improved Method for Magnetic Nanocarrier Drug Delivery across the Cell Membrane

Author

Behzad Mehrafrooz, Maysam Z. Pedram, and Ebrahim Ghafar-Zadeh

Subjects

magnetic nanocarrier, magnetic field, molecular dynamics simulations, drug delivery, magnetic resonance imaging (MRI), Chemical technology, TP1-1185

Abstract

One of the crucial issues in the pharmacological field is developing new drug delivery systems. The main concern is to develop new methods for improving the drug delivery efficiencies such as low disruptions, precise control of the target of delivery and drug sustainability. Nowadays, there are many various methods for drug delivery systems. Carbon-based nanocarriers are a new efficient tool for translocating drug into the defined area or cells inside the body. These nanocarriers can be functionalized with proteins, peptides and used to transport their freight to cells or defined areas. Since functionalized carbon-based nanocarriers show low toxicity and high biocompatibility, they are used in many nanobiotechnology fields. In this study, different shapes of nanocarrier are investigated, and the suitable magnetic field, which is applied using MRI for the delivery of the nanocarrier, is proposed. In this research, based on the force required to cross the membrane and MD simulations, the optimal magnetic field profile is designed. This optimal magnetic force field is derived from the mathematical model of the system and magnetic particle dynamics inside the nanocarrier. The results of this paper illustrate the effects of the nanocarrier’s shapes on the percentage of success in crossing the membrane and the optimal required magnetic field.

Published

2018

28. Direct-Dispense Polymeric Waveguides Platform for Optical Chemical Sensors

Author

Mohamad Hajj-Hassan, Timothy Gonzalez, Ebrahim Ghafar-Zadeh, Hagop Djeghelian, Vamsy Chodavarapu, Daniel Therriault, and Mark Andrews

Subjects

Direct-Dispense, Direct-Write, Xerogels, Oxygen Sensors, Waveguides, Optical Sensors, Fluorescence, Chemical Sensors, Polymer Waveguides, Chemical technology, TP1-1185

Abstract

We describe an automated robotic technique called direct-dispense to fabricate a polymeric platform that supports optical sensor arrays. Direct-dispense, which is a type of the emerging direct-write microfabrication techniques, uses fugitive organic inks in combination with cross-linkable polymers to create microfluidic channels and other microstructures. Specifically, we describe an application of direct-dispensing to develop optical biochemical sensors by fabricating planar ridge waveguides that support sol-gelderived xerogel-based thin films. The xerogel-based sensor materials act as host media to house luminophore biochemical recognition elements. As a prototype implementation, we demonstrate gaseous oxygen (O2) responsive optical sensors that operate on the basis of monitoring luminescence intensity signals. The optical sensor employs a Light Emitting Diode (LED) excitation source and a standard silicon photodiode as the detector. The sensor operates over the full scale (0%-100%) of O2 concentrations with a response time of less than 1 second. This work has implications for the development of miniaturized multisensor platforms that can be cost-effectively and reliably mass-produced.

Published

2008

29. A Polypyrrole-based Strain Sensor Dedicated to Measure Bladder Volume in Patients with Urinary Dysfunction

Author

Vamsy P. Chodavarapu, Oumarou Savadogo, Ebrahim Ghafar-Zadeh, Mohamad Sawan, and Sumitra Rajagopalan

Subjects

Strain sensor, urinary bladder volume, polypyrrole, impedance spectroscopy, elastic properties, gauge factor, Chemical technology, TP1-1185

Abstract

This paper describes a new technique to measure urine volume in patients with urinary bladder dysfunction. Polypyrrole – an electronically conducting polymer - is chemically deposited on a highly elastic fabric. This fabric, when placed around a phantom bladder, produced a reproducible change in electrical resistance on stretching. The resistance response to stretching is linear in 20%-40% strain variation. This change in resistance is influenced by chemical fabrication conditions. We also demonstrate the dynamic mechanical testing of the patterned polypyrrole on fabric in order to show the feasibility of passive interrogation of the strain sensor for biomedical sensing applications.

Published

2008

30. Nanopore-CMOS Interfaces for DNA Sequencing

Author

Sebastian Magierowski, Yiyun Huang, Chengjie Wang, and Ebrahim Ghafar-Zadeh

Subjects

nanopore sensors, microelectronics, sequencing, CMOS, nanopore arrays, transimpedance amplification, Biotechnology, TP248.13-248.65

Abstract

DNA sequencers based on nanopore sensors present an opportunity for a significant break from the template-based incumbents of the last forty years. Key advantages ushered by nanopore technology include a simplified chemistry and the ability to interface to CMOS technology. The latter opportunity offers substantial promise for improvement in sequencing speed, size and cost. This paper reviews existing and emerging means of interfacing nanopores to CMOS technology with an emphasis on massively-arrayed structures. It presents this in the context of incumbent DNA sequencing techniques, reviews and quantifies nanopore characteristics and models and presents CMOS circuit methods for the amplification of low-current nanopore signals in such interfaces.

Published

2016

31. An Optically-Transparent Aptamer-Based Detection System for Colon Cancer Applications Using Gold Nanoparticles Electrodeposited on Indium Tin Oxide

Author

Mojgan Ahmadzadeh-Raji, Ebrahim Ghafar-Zadeh, and Ghasem Amoabediny

Subjects

apta-DS, Gold Nanoparticle (GNP), indium tin oxide (ITO), cyclic voltammetry (CV), colon cancer, chronopotentiometry (CP), Chemical technology, TP1-1185

Abstract

In this paper, a label-free aptamer based detection system (apta-DS) was investigated for detecting colon cancer cells. For this purpose, we employed an aptamer specific to colon cancer cells like HCT116 expressing carcinoembryonic antigen (CEA) on their surfaces. Capture aptamers were covalently immobilized on the surface of gold nanoparticles (GNPs) through self-assembly monolayer of 11-mercaptoundecanoic acid (11-MUA) activated with EDC (1-Ethyl-3-[3-dimethylaminopropyl]carbodiimide)/N-hydroxysuccinimide (NHS). The cyclic voltammetry (CV) and chronopotentiometry (CP) methods were used for electrodeposition of GNPs on the surface of indium tin oxide (ITO). In this work, the CV method was also used to demonstrate the conjugation of GNPs and aptamers and identify the cancer cell capturing events. Additionally, Field Emission Scanning Electron Microscopy (FE-SEM) confirmed the deposition of GNPs on ITO and the immobilization of aptamer on the apta-DS. The electrodeposited GNPs played the role of nanoprobes for cancer cell targeting without losing the optical transparency of the ITO substrate. A conventional optical microscope also verified the detection of captured cancer cells. Based on this study’s results relying on electrochemical and optical microscopic methods, the proposed apta-DS is reliable and high sensitive with a LOD equal to 6 cell/mL for colon cancer detection.

Published

2016

32. Optimal Magnetic Field for Crossing Super-Para-Magnetic Nanoparticles through the Brain Blood Barrier: A Computational Approach

Author

Maysam Z. Pedram, Amir Shamloo, Aria Alasty, and Ebrahim Ghafar-Zadeh

Subjects

Molecular Dynamics simulation, force steering, Blood Brain Barrier, superparamagnetic nanoparticles, Biotechnology, TP248.13-248.65

Abstract

This paper scrutinizes the magnetic field effect to deliver the superparamagnetic nanoparticles (SPMNs) through the Blood Brain Barrier (BBB). Herein we study the interaction between the nanoparticle (NP) and BBB membrane using Molecular Dynamic (MD) techniques. The MD model is used to enhance our understanding of the dynamic behavior of SPMNs crossing the endothelial cells in the presence of a gradient magnetic field. Actuation of NPs under weak magnetic field offers the great advantage of a non-invasive drug delivery without the risk of causing injury to the brain. Furthermore, a weak magnetic portable stimulator can be developed using low complexity prototyping techniques. Based on MD simulation results in this paper, SPMNs can cross the cell membrane while experiencing very weak mechanical forces in the range of pN. This study also derives guidelines for the design of the SPMNs dedicated to crossing the BBB using external magnetic fields.

Published

2016

33. A Multidisciplinary Approach to High Throughput Nuclear Magnetic Resonance Spectroscopy

Author

Hossein Pourmodheji, Ebrahim Ghafar-Zadeh, and Sebastian Magierowski

Subjects

CMOS, low noise amplifier (LNA), Nuclear Magnetic Resonance, Chemical technology, TP1-1185

Abstract

Nuclear Magnetic Resonance (NMR) is a non-contact, powerful structure-elucidation technique for biochemical analysis. NMR spectroscopy is used extensively in a variety of life science applications including drug discovery. However, existing NMR technology is limited in that it cannot run a large number of experiments simultaneously in one unit. Recent advances in micro-fabrication technologies have attracted the attention of researchers to overcome these limitations and significantly accelerate the drug discovery process by developing the next generation of high-throughput NMR spectrometers using Complementary Metal Oxide Semiconductor (CMOS). In this paper, we examine this paradigm shift and explore new design strategies for the development of the next generation of high-throughput NMR spectrometers using CMOS technology. A CMOS NMR system consists of an array of high sensitivity micro-coils integrated with interfacing radio-frequency circuits on the same chip. Herein, we first discuss the key challenges and recent advances in the field of CMOS NMR technology, and then a new design strategy is put forward for the design and implementation of highly sensitive and high-throughput CMOS NMR spectrometers. We thereafter discuss the functionality and applicability of the proposed techniques by demonstrating the results. For microelectronic researchers starting to work in the field of CMOS NMR technology, this paper serves as a tutorial with comprehensive review of state-of-the-art technologies and their performance levels. Based on these levels, the CMOS NMR approach offers unique advantages for high resolution, time-sensitive and high-throughput bimolecular analysis required in a variety of life science applications including drug discovery.

Published

2016

34. Novel CMOS Thermo-Capacitive Sensing Method for Lab-on-Chip Applications.

Author

Saghi Forouhi, Hamed Osouli Tabrizi, Abbas Panahi, Sebastian Magierowski, and Ebrahim Ghafar-Zadeh

Published

2023

35. RISC-V Multicore for Miniature DNA Sequencers.

Author

Abel Beyene, Zhongpan Wu, Karim Hammad, Ebrahim Ghafar-Zadeh, and Sebastian Magierowski

Published

2023

36. DNA Storage Monitoring with a CMOS Capacitive Sensor.

Author

Hamed Osouli Tabrizi, Saghi Forouhi, Morteza Ghafar-Zadeh, Omid Farhanieh, Tina Shaffaf, Sebastian Magierowski, and Ebrahim Ghafar-Zadeh

Published

2022

37. An FPGA Implementation of A Portable DNA Sequencing Device Based on RISC-V.

Author

Zhongpan Wu, Karim Hammad, Abel Beyene, Yunus Dawji, Ebrahim Ghafar-Zadeh, and Sebastian Magierowski

Published

2022

38. A New Field-Effect Transistor Based Sensor for Biosensing Applications.

Author

Abbas Panahi and Ebrahim Ghafar-Zadeh

Published

2022

39. A New Foundry-Based Open-Gate Junction Field-Effect Transistor (OG-JFET) as Electronic Sensing Platform (ESP) for Life Science Applications.

Author

Abbas Panahi, Hamed Osouli Tabrizi, Priyadarshini Mangannavar, Oleg Chebotarev, Andrew Fung, and Ebrahim Ghafar-Zadeh

Published

2021

40. A Novel Calibration-Free Fully Integrated CMOS Capacitive Sensor for Life Science Applications.

Author

Hamed Osouli Tabrizi, Saghi Forouhi, Omid Farhanieh, Sebastian Magierowski, and Ebrahim Ghafar-Zadeh

Published

2021

41. CMOS Capacitive DNA Nano-Mass Measurement for DNA Storage Application.

Author

Hamed Osouli Tabrizi, Saghi Forouhi, Morteza Ghafar-Zadeh, Sebastian Magierowski, and Ebrahim Ghafar-Zadeh

Published

2021

42. A Visual Distortion Sensing Model for Early Detection of Macular Disorders.

Author

Parveen Zainab Fatima Ali and Ebrahim Ghafar-Zadeh

Published

2020

43. Smart Bedsheet for Baby Monitoring Application: Measurement and Characterization Results.

Author

Samal Munidasa, Parastoo Baghaei, Edward Shim, Olivia Lin, and Ebrahim Ghafar-Zadeh

Published

2020

44. Toward Versatile CMOS Capacitive Sensors for Cellular Monitoring.

Author

Hamed Osouli Tabrizi, Sebastian Magierowski, and Ebrahim Ghafar-Zadeh

Published

2020

45. A Non-Invasive Wireless Respiratory Monitoring System for Animals' Behavioural Studies.

Author

Kuanghua Qiao, Amanda Nickerson, Suzanne MacDonald, and Ebrahim Ghafar-Zadeh

Published

2020

46. Dynamics Targeting Through Cell Membrane: MD Simulation Approach in CNT-Based Drug Delivery Application.

Author

Nafiseh Sohrabi, Maysam Zamani Pedram, Ebrahim Ghafar-Zadeh, and Sebastian Magierowski

Published

2020

47. A New Capacitive MEMS Flow Sensor for Industrial Gas Transport Monitoring Applications.

Author

Abbas Panahi, Pouya Ghasemi, Sebastian Magierowski, and Ebrahim Ghafar-Zadeh

Published

2020

48. A Bedsheet for Baby Monitoring at Night: Measurement and Characterization Results.

Author

Samal Munidasa, Parastoo Baghaei, Edward Shim, Olivia Lin, and Ebrahim Ghafar-Zadeh

Published

2020

49. Novel Resonance-Like Impedance Spectroscopy for Life Science Applications.

Author

Giancarlo Ayala-Charca, Sebastian Magierowski, and Ebrahim Ghafar-Zadeh

Published

2019

50. FPGA-based DNA Basecalling Hardware Acceleration.

Author

Zhongpan Wu, Karim Hammad, Robinson Mittmann, Sebastian Magierowski, Ebrahim Ghafar-Zadeh, and Xiaoyong Zhong

Published

2018