Development of novel multiplexed systems for in situ PLA

Broberg, John

January 2011

The in situ proximity ligation assay (in situ PLA) is an immunoassay that enables directvisualisation of single protein targets or protein interactions in cell or tissue samples. This project revolves around designing and introducing several novel multiplexable components tobe used in conjunction with Olink Bioscience's Duolink product line. In this report, a novel in silico approach to DNA oligomer interaction design is presented. Using this in silico method, a multiplexed system of DNA oligomers has been designed andevaluated using in situ PLA and fluorescence microscopy.

Proximity ligation assay

PLA

Multiplex

Immunoassay

Rolling circle amplification

RCA

in situ

DNA sequence design

Validation of a method for analyzing urinary Cystatin C and analysis of ULSAM-77 urine samples

Härmä, Johan

January 2012

Objective New biomarkers for acute kidney injury are needed and urinary Cystatin C is one alternative. The objective was to validate a urinary Cystatin C method on Mindray BS-380 comparing urine samples from the Uppsala Longitudinal Study of Adult Men (ULSAM-77) and urine samples from a reference group for Cystatin C. A visual control for a relationship between Cystatin C and C-reactive protein (CRP) and interleukin 6 (IL-6) respectively was made. Methods Precision, linearity, recovery, interference, and stability of the urine cystatin C method were investigated. Comparisons were made between ULSAM-77 samples and a reference group samples consisting of ordinary people. Results The highest total imprecision was 10.24 % for the sample with the lowest concentration. The second lowest concentration had 4.21 % total variation coefficient. The linearity equation was y = 0.99x – 0.01 with an R2-value of 0.99. The recovery for all concentrations was always 91 % or more. No interference from hemoglobin at a concentration of 10 g/L was found. The samples were stable at +5°C for seven days. The median for the samples from ULSAM-77 was 0.09 mg/L and the median for the reference samples was 0.06 mg/L. There was no obvious relationship between Cystatin C and CRP/IL-6 from ULSAM-77. Conclusion   Reliable data of urinary Cystatin C can be analyzed on a Mindray BS-380. The level of urinary Cystatin C was higher for people age 77 than for those with a median age of 49. There was no correlation between the concentration of Cystatin C in urine and the levels of CRP and IL-6.

acute kidney injury

biomarker

human

mindray bs-380

Measurement and validation of urinary cystatin C by particle-enhanced turbidimetric immunoassay on Architect ci8200

Hikmet Noraddin, Feria

January 2011

Cystatin C, a 13 kDa low molecular weight protein is an inhibitor of cysteine proteases. Due to its low molecular weight and positive charge at physiological pH, it is freely filtered by the glomerulus and catabolized after reabsorption by proximal tubular cells with a low concentration (0.03-0.3 mg/L) in urine amongst healthy subjects. Urinary cystatin C is a potential biomarker detection of acute kidney injury (AKI) in the acute phase when patients are submitted to the intensive care unit. The aim in this report was to perform a full method validation of urinary analysis of cystatin C on a high throughput chemical analyzer by particle-enhanced turbidimetric immunoassay (PETIA) at the University Hospital in Uppsala, Sweden. The antigen excess, linearity, lower limit of quantification (LoQ), recovery, assay precision, stability and interference caused by haemoglobin was evaluated. No hook effect was observed, the assay was linear over the studied interval <0.001-0.950 mg/L with a regression of R2=0.9994. The LoQ was calculated to 0.020 mg/L with a coefficient of variation (CV) ≤10% which was considered acceptable. The assay had a recovery between 93-100% and the assay precision had a total CV <3.5%. Cystatin C is stable for 3 days in room temperature and 14 days in +4C. The assay did not show any major interference with haemoglobin. The urinary cystatin C showed good precision and performance characteristics by measurements using PETIA all of which is a necessary qualification for a biomarker at a 24-h running routine laboratory.

avian antibodies

cystatin C

method validation

urine

Clinical chemistry

Klinisk kemi

Design and verification of a surface plasmon resonance biosensor

Sommers, Daniel R.

18 August 2004

The Microelectronics Group has been researching sensors useful for detecting and quantifying events in biological molecular chemistry, for example, binding events. Our previous research has been based primarily on quartz resonators. This thesis describes the results of our initial research of Surface Plasmon Resonance (SPR) based technology. This study contains the design and implementation of a fully functional SPR biosensor with detailed disclosure of monolayer construction, digital hardware interfaces and software algorithms for process the SPR sensors output. An antibody monolayer was constructed on the biosensor surface with the goal of setting the strengths, weaknesses and limitation of measuring molecular events with SPR technology. We documented several characteristics of molecular chemistry that directly effect any measurements made using Surface Plasmon Resonance technology including pH, free ions, viscosity and temperature. Furthermore, the component used in our study introduced additional limitations due to wide variations amongst parts, the constraint of a liquid medium and the large surface area used for molecular interrogation. We have identified viable applications for this sensor by either eliminating or compensating for the factors that affect the measured results. This research has been published at the inaugural IEEE sensors conference and to our knowledge is the first time a biosensor has been constructed by attaching a sensor to a PDA and performing all signal processing, waveform analysis and display in the PDAs core processor.

SPR

Wireless biosensor

Immunoassay sensors

Monoclonal antibody

Surface plasmon resonance

Surface plasmon resonance

Biosensors Design and construction

Biosensor Development for Environmental Monitoring, Food Safety, and Secondary Education Applications

Liang, Pei-Shih

January 2013

This dissertation develops biosensors for rapid detection of pathogens for environmental monitoring and food safety applications and utilizes the multidisciplinary and multi-application characteristics of biosensors to develop a lesson plan that can be implemented in secondary education classrooms. The detection methods evolve from particle immunoagglutination assay, PDMS optofluidic lab-on-a-chip, and spectrum analysis to smartphone and image analysis without any reagent; the potential application in secondary education also underlines the extended value of biosensors. In the first paper presented here, an optofluidic lab-on-a-chip system and subsequent sampling procedure were developed for detecting bacteria from soil samples utilizing Mie scattering detection of particle immunoagglutination assay. This system and protocol detected the presence of Escherichia coli K12 from soil particles in near real-time (10 min) with a detection limit down to 1 CFU mL⁻¹ and has the potential to be implemented in the field. We also compared the interaction between E. coli and soil particles to the two-step protein-surface interaction. In the second paper, a smartphone-utilized biosensor consisting of a near-infrared (NIR) LED (wavelength of 880 nm) and a digital camera of a smartphone was developed for detecting microbial spoilage on ground beef, without using any reagents. The method was further improved by programming a smartphone application that allows the user to position the smartphone at an optimum distance and a range of angles utilizing its internal gyro sensor to measure a series of scatter intensities against the detection angle. This handheld device can be used as a preliminary screening tool to monitor microbial contamination on meat products. In the third paper, we designed a lesson plan for secondary education classrooms using biosensors as a core and branching out to different applications and fields of study with the goal of heightening students' interest and motivation toward attaining degrees and careers in STEM fields. Results revealed that the lesson was more effective in affecting younger students than older students, and more effective in teaching about the applications of biosensors than about the techniques of biosensor development.

immunoassay

lab-on-a-chip

optofluidics

pathogen detections

smartphone

biosensors

Lab-on-a-Chip Biosensors for the Rapid Detection of Pathogens in Clinical and Field Samples

Fronczek, Christopher F.

January 2013

In the United States and other developed countries, despite great efforts in time and funding for the prevention of foodborne and airborne diseases, there is still an unacceptable level of common pathogens spread via food, water, and air. To this end, lab-on-a-chip (LOC) technologies were developed for field-deployable assays and point of care diagnostics. These devices have potential applications in hospitals, agricultural farms, processing plants, and even on fields of battle. Two successful types of assays in the recent years towards point of care diagnostics are immunoassays and nucleic acid detection assays. In the Appendix A, we demonstrated a complete, field-deployable particle immunoassay encased within a microfluidic chip that detects small quantities of Salmonella Typhimurium in poultry fluid samples. Because the necessary reagents are pre-loaded and the test and negative control channels are fed by a single sample inlet, single pipetting of sample is possible. This assay demonstrated a 10 CFU/mL limit of detection, which is considerably lower than PCR and enzyme-linked immunosorbent assay (ELISA). Total assay time, including sample reading in an integrated handheld device, was 10 minutes, which was much lower than conventional methods. Because of the simplified protocol and assay time, this biosensor has potential in clinical and field diagnostic applications. In Appendix B, we fit the particle immunoassay to test for Influenza A H1N1/2009 virus and included aerosol sampling from a scaled-down mock classroom. To make the assay field deployable, we used an iPhone for signal detection. The detection limit of the assay was 1 pg/mL (10 pg/mL using the iPhone), which is well below the limit of detection for RT-PCR. This protocol demonstrated that immunoassays can be effective in the presence of interfering dust particles and that viruses can be collected from aerosol with minimal sample preparation. In Appendix C, we demonstrated that paper microfluidics, a newer vision of microfluidics, is a cheap and easy method to extract nucleic acid from S. Typhimurium in a variety of samples, including poultry packaging liquid, whole blood, and feces. Fluorescent detection with an iPhone allows for field and clinical testing. This protocol interfaces with rapid PCR and is a true diagnostic tool.

Influenza A H1N1/2009

Microfluidics

Paper Microfluidics

Particle Immunoassay

Salmonella Typhimurium

Biomedical Engineering

Biosensors

Biosensor Development for Environmental Monitoring, Food Safety, and Secondary Education Applications

Liang, Pei-Shih

January 2013

This dissertation develops biosensors for rapid detection of pathogens for environmental monitoring and food safety applications and utilizes the multidisciplinary and multi-application characteristics of biosensors to develop a lesson plan that can be implemented in secondary education classrooms. The detection methods evolve from particle immunoagglutination assay, PDMS optofluidic lab-on-a-chip, and spectrum analysis to smartphone and image analysis without any reagent; the potential application in secondary education also underlines the extended value of biosensors. In the first paper presented here, an optofluidic lab-on-a-chip system and subsequent sampling procedure were developed for detecting bacteria from soil samples utilizing Mie scattering detection of particle immunoagglutination assay. This system and protocol detected the presence of Escherichia coli K12 from soil particles in near real-time (10 min) with a detection limit down to 1 CFU mL⁻¹ and has the potential to be implemented in the field. We also compared the interaction between E. coli and soil particles to the two-step protein-surface interaction. In the second paper, a smartphone-utilized biosensor consisting of a near-infrared (NIR) LED (wavelength of 880 nm) and a digital camera of a smartphone was developed for detecting microbial spoilage on ground beef, without using any reagents. The method was further improved by programming a smartphone application that allows the user to position the smartphone at an optimum distance and a range of angles utilizing its internal gyro sensor to measure a series of scatter intensities against the detection angle. This handheld device can be used as a preliminary screening tool to monitor microbial contamination on meat products. In the third paper, we designed a lesson plan for secondary education classrooms using biosensors as a core and branching out to different applications and fields of study with the goal of heightening students' interest and motivation toward attaining degrees and careers in STEM fields. Results revealed that the lesson was more effective in affecting younger students than older students, and more effective in teaching about the applications of biosensors than about the techniques of biosensor development.

immunoassay

lab-on-a-chip

optofluidics

pathogen detections

smartphone

biosensors

Effects of forest fragmentation on brown spider monkeys (Ateles hybridus) and red howler monkeys (Alouatta seniculus)

Rimbach, Rebecca

04 September 2013

No description available.

570

Waldfragmentierung

Stress

Primaten

Glucocorticoide

Forest fragmentation

Hunting

Logging

Glucocorticoids

Stress

Enzyme-immunoassay

Biologie (PPN619462639)

Development and Characterization of Interfacial Chemistry for Biomolecule Immobilization in Surface Plasmon Resonance (SPR) Imaging Studies

Grant, Chris

Unknown Date

No description available.

Development and Characterization of Interfacial Chemistry for Biomolecule Immobilization in Surface Plasmon Resonance (SPR) Imaging Studies

Grant, Chris

11 1900

Surface immobilization of probe molecules in surface based assays is a key area of research in the continued development of immunoassay microarrays. Interest continues to grow in microarray based immunoassays given their potential as a high throughput technique for immunodiagnostics. Therefore, it is important to thoroughly study and understand the implications of interfacial chemistry and immobilization conditions on the performance of the assay. This thesis presents a body of work that examines the impact of probe density, interfacial chemistry, and enhancement factors for arrays read with surface plasmon resonance (SPR) imaging. An array of structurally similar Salmonella disaccharides was immobilized at varying densities and the interface formed was thoroughly investigated to determine the properties of the interface. The arrays were then used with SPR imaging to evaluate the binding of an antibody specific for one disaccharide of the three stereoisomers on the array. A dilute disaccharide surface was found to provide optimal antibody binding. Higher densities result in steric hindrance of antibody binding by not allowing the disaccharide to insert into the antibody binding pocket. The role of interfacial chemistry in antibody attachment was studied to determine optimum conditions. The study examined physical adsorption, covalent attachment, and affinity capture. It was found that covalent attachment provided the most stable attachment and resulted in the lowest levels of antigen detection. Both the physical adsorption and affinity capture provided larger antigen binding capacity and therefore more sensitive antigen detection. The covalent attachment was chosen to evaluate an enhanced assay with the incorporation of gold nanoparticles. These particles provided detection limits that were an order of magnitude improved over those excluding the nanoparticles. A novel surface chemistry for antibody immobilization in SPR imaging studies was evaluated. This involved the electrochemical driven formation of mono- to multilayers of diazonium benzoic acid films. The studies showed the ability to control the thickness of the films formed and also the ability of the antibody chips to capture antigen from solution.