IMMOBILIZATION AND CHARACTERIZATION OF FLEXIBLE DNAzyme-BASED BIOSENSORS FOR ON-THE SHELF FOOD MONITORING

Yousefi, Hanie

11 1900

While the Canadian food supply is among the healthiest in the world, almost 4 million (1 in 8) Canadians are affected by food-borne illnesses, resulting in 11,600 hospitalizations and 238 deaths per year. Microbial pathogens are one of the major causes of foodborne sicknesses that can grow in food before or following packaging. Food distribution is an important part of the food processing chain, in which food supplies are at a higher risk of contamination due to lack of proper monitoring. Among myriad of research around biosensors, current devices focusing on packaged food monitoring, such as leakage indicators or time temperature sensors are not efficient for real-time food monitoring without separating the sample from the stock. Packaged food such as meat and juice are directly in touch with the surface of their containers or covers. Therefore, real-time sensing mechanisms, installed inside the food packaging and capable of tracing the presence of pathogens, are of great interest to ensure food safety. This work involves developing thin, transparent, flexible and durable sensing surfaces using DNA biosensors, which report the presence of a target bacterium in food or water samples by generating a fluorescence signal that can be detected by simple fluorescence detecting devices. The covalently-attached DNA probes generate the signal upon contact with the target bacteria with as low as 103 CFU/mL of Escherichia coli in meat and apple juice. The fabricated sensing surfaces remained stable up to several days under varying pH conditions (pH 5 to 9). In addition to detecting pathogens on packaged food or drinking bottles, these surfaces have the potential to be used for a variety of other applications in health care settings, environmental monitoring, food production chain, and biomaterials like wound dressing. / Thesis / Master of Science (MSc) / Microbial pathogens can grow in food following packaging and preceding consumption. Current biosensors are not efficient for post-packaging real-time food monitoring without separating the sample from the stock. Packaged food such as meat and juice are directly in touch with the surface of their containers or covers. Therefore, real-time sensing mechanisms, installed inside the food packaging, tracing the presence of pathogens, are much useful to ensure the food safety. Here we report on developing thin, transparent, flexible and durable sensing surfaces using DNA biosensors, which generate a fluorescence signal in the presence of a target bacterium in food or water samples. The covalentlyattached DNA probes can detect as low as 103 CFU/mL of Escherichia coli in meat, sliced apple and apple juice. The fabricated sensing surfaces remained stable up to several days under varying pH conditions (pH 5 to 9). In addition to pathogen monitoring in packaged food or drinking bottles, these surfaces are promising for a variety of other applications in health care settings, environmental monitoring, and biomaterials like wound dressing.

DNAzyme

Biosensors

Surface Immobilization

Epoxy

Amine

NHS

DNA

E.Coli

Bacteria Detection

Food Monitoring

Packaging Biosensors

Elucidation of Membrane Protein Interactions Under Native and Ligand Stimulated Conditions Using Fluorescence Correlation Spectroscopy

Christie, Shaun Michael

25 August 2020

No description available.

Biophysics

Biochemistry

Chemistry

membrane proteins

plexin

neuropilin

semaphorin

interferon gamma

transmembrane domain

surface immobilization

Photochemical Surface Functionalization : Synthesis, Nanochemistry and Glycobiological Studies

Deng, Lingquan

January 2011

This thesis mainly deals with the development of photochemical approaches to immobilize carbohydrates on surfaces for glycobiological studies. These approaches have been incorporated into a number of state-of-the-art nanobio-platforms, including carbohydrate microarrays, surface plasmon resonance (SPR), quartz crystal microbalance (QCM), atomic force microscopy (AFM), and glyconanomaterials. All the surfaces have displayed good binding capabilities and selectivities after functionalization with carbohydrates, and a range of important data have been obtained concerning surface characteristics and carbohydrate-protein interactions, based on the platforms established. Besides, a variety of non-carbohydrate and carbohydrate-based molecules have been synthesized, during which process the mutarotation of 1-glycosyl thiols and the stereocontrol in 1-S-glycosylation reactions have been thoroughly studied. / QC 20111004

Carbohydrates

Glycobiology

Carbohydrate-protein interactions

Perfluorophenylazide (PFPA)

Photochemistry

Carbohydrate surface immobilization

Carbohydrate microarrays

Surface plasmon resonance (SPR)

Quartz crystal microbalance (QCM)

Atomic force microscopy (AFM)

Glyconanomaterials

Concanavalin A (Con A)

Cyanovirin-N (CV-N)

1-Glycosyl thiols; Mutarotation

1-S-glycosylation

Stereocontrol