Entwicklung eines Biosensors für das online-Monitoring des akuten Koronarsyndroms

Tannenberg, Robert

17 June 2024

Herz-Kreislauf-Erkrankungen sind weltweit die häufigste Todesursache. Im Falle eines akuten myokardialen Infarkts ist eine schnelle und präzise Diagnostik notwendig, um ggf. die entsprechend überlebenswichtigen Maßnahmen in die Wege zu leiten. Einer der wichtigsten Biomarker für die Herzinfarkt-Diagnostik ist das kardiale Troponin I (cTnI), welches durch das Absterben der Myokardzellen (Herzmuskel) in den Blutkreislauf gelangt und sich dessen Konzentration über die Zeit ändert. Diese Konzentrationsänderung ist entscheidend für die Diagnostik und letztendlich für weitere lebensrettende medizinische Schritte. Entsprechend wurden in dieser Arbeit verschiedene Messmethoden entwickelt, um cTnI-Konzentrationen zu bestimmen. Zunächst wurden mehrere Enzyme-linked Immunosorbent Assays (ELISA) im Sandwich-Format entwickelt, um eine höchstmögliche Sensitivität zur Detektion von cTnI zu ermöglichen. Um eine schnelle und kostengünstige Detektion von cTnI zu ermöglichen, wurde außerdem ein Lateral-Flow-Assay (LFA) entwickelt. Dabei wurden Gold-Nanoshells für die optische Auswertung verwendet, welche eine empfindlichere Detektion als übliche Gold-Nanopartikel ermöglichen. Des Weiteren wurden verschiedene Immunisierungen mit unterschiedlichen Strategien durchgeführt, um neue Antikörper gegen humanes cTnI zu entwickeln. Für das Online-Monitoring von cTnI wurde der Prototyp eines Biosensors entwickelt, welcher auf Chemilumineszenz-Detektion basiert. Für cTnI wurde mit dem Biosensor eine Nachweisgrenze von 0,6 μg/L (25 pM) in Puffer, 1,8 μg/L (73 pM) in Serum und 1,5 μg/L (63 pM) erzielt. / Cardiovascular diseases are the most common cause of death worldwide. In the event of an acute myocardial infarction, rapid and precise diagnostics are necessary in order to initiate the appropriate vital measures if necessary. One of the most important biomarkers for heart attack diagnostics is cardiac troponin I (cTnI), which enters the bloodstream when the myocardial cells (heart muscle) undergo necrosis after an infarction and whose concentration changes over time. This change in concentration is crucial for diagnostics and ultimately for further lifesaving medical steps. Accordingly, various measurement methods were developed in this work to determine cTnI concentrations. Initially, several enzyme-linked immunosorbent assays (ELISA) were developed in a sandwich format to enable the highest possible sensitivity for the detection of cTnI. A lateral flow assay (LFA) was also developed to enable rapid and cost-effective detection of cTnI. Gold nanoshells were used for optical evaluation, which enable more sensitive detection than conventional gold nanoparticles. Furthermore, different immunizations with different strategies were performed to develop new antibodies against human cTnI. A prototype biosensor based on chemiluminescence detection was developed for the online monitoring of cTnI. For cTnI, a detection limit of 0.6 μg/L (25 pM) in buffer, 1.8 μg/L (73 pM) in serum and 1.5 μg/L (63 pM) was achieved with the biosensor.

Biosensor

Troponin

Herzinfarkt

Lateral Flow Assay

Online-Detektion

Biosensor

Troponin

Heart attack

Lateral Flow Assay

Online-detection

543 Analytische Chemie

ddc:543

Enzyme-linked immunosorbent assay to measure serum ferritin in toucans (Ramphastidae sp.)

Meindel, Mandy J.

January 1900

Master of Science / Department of Diagnostic Medicine/ Pathobiology / Lisa M. Pohlman / Background: Iron storage disease has proven to be a serious health concern for captive toucans. Physiologic mechanisms to efficiently extract iron from naturally iron-deficient diets appear the likely cause of iron overload when fed iron-sufficient diets in captivity. Iron overload can result in diabetes, heart failure, and even death. Serum ferritin concentrations are considered the most reliable screening tool to predict total body iron stores in many species, but an assay has not been available to measure serum ferritin in toucans. Objective: The purpose of this study was to develop an enzyme-linked immunosorbent assay (ELISA) to measure serum ferritin in toucans using a polyclonal antibody in a sandwich arrangement. Methods: Ferritin was isolated from toucan liver and used as a standard. A rabbit polyclonal anti-toucan antibody was used as the capture antibody and as a detection antibody conjugated to horseradish peroxidase. Linearity of toucan ferritin standards, effect of serum dilution, recovery of added ferritin standards, and intra- and inter-assay variability were determined. Results: Ferritin standards were linear from 0 to 50 ng/ml. The relationship between serum dilution and serum ferritin concentration was also linear. When 10, 20, 30, 40, or 50 ng/ml of purified toucan ferritin were added to diluted serum, the recoveries varied from 69% to 104%. The intra-assay variability for four test serum samples averaged 11% and the inter-assay variability for the same four samples averaged 11%. Conclusions: Although the results from the linearity and recovery studies are promising for assay development when viewed independently, preliminary ferritin concentrations from all toucans studied are much higher than expected. Upon further evaluation including Dot blot assays, Western blot assays, SDS-PAGE, and protein determination of the ferritin stock solution, it was determined that the ferritin stock solution did not contain a pure protein and therefore likely renders the assay invalid. Further testing is needed to confirm these findings.

Ferritin

Iron storage disease

Toucans

Enzyme-linked immunosorbent assay

Veterinary Medicine (0778)

The effect of fumigants on earthworms (Eisenia andrei) and soil microbial communities / Tanya Christina Fouché

Fouché, Tanya Christina

January 2015

Biofumigation is an important crop protection practice that uses a plant’s natural defence mechanisms to control agricultural crop pathogens and diseases. Glucosinolates are volatile compounds found in most Brassica species and when hydrolysed, it forms a range of natural toxins including isothiocyanates that act as biofumigants. Research suggests that biofumigation is a good alternative to chemical fumigants as it is effective in controlling plant pests but with lower health and environmental risks. Several studies have confirmed the effectiveness of the breakdown products, especially isothiocyanates, as fungicidal, bactericidal and nematicidal products against a series of plant pests. However, very little information is available on the effects of glucosinolates and its breakdown products on non-target and beneficial soil organisms. Negative effects on beneficial soil organisms can have serious negative impacts on soil quality especially when essential ecosystem functions such as nutrient cycling and soil bioturbation are affected. Three biofumigants, broccoli, mustard and oilseed radish, and two chemical fumigants, metham sodium and cadusafos, were investigated for possible effects on non-target and essential soil organisms such as earthworms and the soil microbial community. Sublethal endpoints, including growth and reproductive success of the earthworms, were monitored. The genotoxicity of the biologically active compounds found in the fumigants, towards earthworms, was evaluated by means of the comet assay. The DNA damage was quantified by tail intensity parameters. Furthermore, the changes in the soil microbial community function and structure were evaluated by means of community level physiological profiling (CLPP) and phospholipid fatty acid (PLFA) analyses respectively. All exposures were done in artificial soil prepared according to the OECD standard guidelines. In the biofumigant treated soils, results varied and different effects were observed on the non-target soil organisms. Broccoli reduced cocoon production and the number of hatchlings while mustard induced more DNA strand breaks in earthworm cells compared to the control. All the biofumigants stimulated microbial growth but broccoli and oilseed radish changed the microbial functional diversity. Mustard had no lasting effect on the functional diversity but altered the microbial community structure. The chemical fumigants had a marked negative impact on the survival, growth, reproduction and the genotoxicity of the earthworms with metham sodium causing greater harm than cadusafos. The effects on the microbial community varied. Both chemicals had an inhibitory effect on the microbial growth in terms of the viable biomass determined by PLFA and the average well colour development in the Biolog™ Ecoplates. No lasting effects were observed in the community structure. Overall, cadusafos had a more pronounced effect on the microbial community functional diversity than metham sodium. Results indicated that each bioindicator species illustrates effects at their own level of organisation / MSc (Environmental Sciences), North-West University, Potchefstroom Campus, 2015

Biofumigation

Biolog™

Cadusafos

Comet assay

Earthworm biomarkers

Metham sodium

Microbial community

Phospholipid fatty acid

Potential pathogenicity of heterotrophic plate count bacteria isolated from untreated drinking water / Rachel Magrietha Petronella Prinsloo

Prinsloo, Rachel Magrietha Petronella

January 2014

Water is considered the most vital resource on earth and its quality is deteriorating. Not all residents living in South Africa‘s rural areas have access to treated drinking water, and use water from rivers, dams, and wells. The quality of these resources is unknown, as well as the effects of the bacteria in the water on human health. The heterotrophic plate count (HPC) method is a globally used test to evaluate microbial water quality. According to South African water quality guidelines, water of good quality may not contain more than a 1 000 coliforming units (CFU)/mℓ. There is mounting evidence that HPC bacteria may be hazardous to humans with compromised, underdeveloped, and weakened immune systems. In this study the pathogenic potential of HPC bacteria was investigated. Samples were collected from boreholes in the North West Province and HPCs were enumerated with a culture-based method. Standard physico-chemical parameters were measured for the water. Different HPC bacteria were isolated and purified and tested for α- or β-haemolysis, as well as the production of extracellular enzymes such as DNase, proteinase, lecithinase, chondroitinase, hyaluronidase and lipase, as these are pathogenic characteristics. The isolates were identified with 16S rRNA gene sequencing. The model for the human intestine, Hutu-80 cells, were exposed to the potentially pathogenic HPC isolates to determine their effects on the viability of the human cells. The isolates were also exposed to different dilutions of simulated gastric fluid (SGF) to evaluate its effect on the viability of bacteria. Antibiotic resistant potential of each isolate was determined by the Kirby-Bauer disk diffusion method. Three borehole samples did not comply with the physico-chemical guidelines. Half of the samples exceeded the microbial water quality guideline and the greatest CFU was 292 350 CFU/mℓ. 27% of the isolate HPC bacteria were α- or β- haemolytic. Subsequent analysis revealed the production of: DNase in 72%, proteinase in 40%, lipase and lecithinase in 29%, hyaluronidase in 25% and least produced was chondroitinase in 25%. The HPC isolates identified included: Alcaligenes faecalis, Aeromonas hydrophila and A. taiwanesis, Bacillus sp., Bacillus thuringiensis, Bacillus subtilis, Bacillus pumilus, Brevibacillus sp., Bacillus cereus and Pseudomonas sp. All the isolates, except Alcaligenes faecalis, were toxic to the human intestinal cells to varying degrees. Seven isolates survived exposure to the most diluted SGF and of these, four isolates also survived the intermediate dilution but, only one survived the highest SGF concentration. Some isolates were resistant to selected antibiotics, but none to neomycin and vancomycin. Amoxillin and oxytetracycline were the least effective of the antibiotics tested. A pathogen score was calculated for each isolate based on the results of this study. Bacillus cereus had the highest pathogen index with declining pathogenicity as follows: Alcaligenes faecalis > B. thuringiensis > Bacillus pumilus > Pseudomonas sp. > Brevibacillus > Aeromonas taiwanesis > Aeromonas hydrophila > Bacillus subtilis > Bacillus sp. The results of this study prove that standard water quality tests such as the physico-chemical and the HPC methods are insufficient to provide protection against the effects of certain pathogenic HPC bacteria. / MSc (Environmental Sciences), North-West University, Potchefstroom Campus, 2014

HPC bacteria

Extracellular enzymes

Cytotoxicity

Simulated gastric fluid

MTT assay

Antibiotic resistance

The effect of fumigants on earthworms (Eisenia andrei) and soil microbial communities / Tanya Christina Fouché

Fouché, Tanya Christina

January 2015

Biofumigation is an important crop protection practice that uses a plant’s natural defence mechanisms to control agricultural crop pathogens and diseases. Glucosinolates are volatile compounds found in most Brassica species and when hydrolysed, it forms a range of natural toxins including isothiocyanates that act as biofumigants. Research suggests that biofumigation is a good alternative to chemical fumigants as it is effective in controlling plant pests but with lower health and environmental risks. Several studies have confirmed the effectiveness of the breakdown products, especially isothiocyanates, as fungicidal, bactericidal and nematicidal products against a series of plant pests. However, very little information is available on the effects of glucosinolates and its breakdown products on non-target and beneficial soil organisms. Negative effects on beneficial soil organisms can have serious negative impacts on soil quality especially when essential ecosystem functions such as nutrient cycling and soil bioturbation are affected. Three biofumigants, broccoli, mustard and oilseed radish, and two chemical fumigants, metham sodium and cadusafos, were investigated for possible effects on non-target and essential soil organisms such as earthworms and the soil microbial community. Sublethal endpoints, including growth and reproductive success of the earthworms, were monitored. The genotoxicity of the biologically active compounds found in the fumigants, towards earthworms, was evaluated by means of the comet assay. The DNA damage was quantified by tail intensity parameters. Furthermore, the changes in the soil microbial community function and structure were evaluated by means of community level physiological profiling (CLPP) and phospholipid fatty acid (PLFA) analyses respectively. All exposures were done in artificial soil prepared according to the OECD standard guidelines. In the biofumigant treated soils, results varied and different effects were observed on the non-target soil organisms. Broccoli reduced cocoon production and the number of hatchlings while mustard induced more DNA strand breaks in earthworm cells compared to the control. All the biofumigants stimulated microbial growth but broccoli and oilseed radish changed the microbial functional diversity. Mustard had no lasting effect on the functional diversity but altered the microbial community structure. The chemical fumigants had a marked negative impact on the survival, growth, reproduction and the genotoxicity of the earthworms with metham sodium causing greater harm than cadusafos. The effects on the microbial community varied. Both chemicals had an inhibitory effect on the microbial growth in terms of the viable biomass determined by PLFA and the average well colour development in the Biolog™ Ecoplates. No lasting effects were observed in the community structure. Overall, cadusafos had a more pronounced effect on the microbial community functional diversity than metham sodium. Results indicated that each bioindicator species illustrates effects at their own level of organisation / MSc (Environmental Sciences), North-West University, Potchefstroom Campus, 2015

Biofumigation

Biolog™

Cadusafos

Comet assay

Earthworm biomarkers

Metham sodium

Microbial community

Phospholipid fatty acid

Characterization of grain sorghum for physiological and yield traits associated with drought tolerance

Mutava, Raymond N.

January 1900

Master of Science / Department of Agronomy / P. V. Vara Prasad / Grain sorghum (Sorghum bicolor L. Moench) is the fourth most important cereal crop grown throughout the semi-arid regions of the world. It is a staple food crop in Africa and Asia, while it is an important feed crop in the United States (US). More recently it is increasingly becoming important as a potential bioenergy feedstock crop around the world. The state of Kansas is the largest producer of grain sorghum in the US and contributes 40% of the total production. Drought is one of the major environmental factors limiting sorghum production in the semi-arid regions of the US, Asia and Africa. It is estimated that global crop losses due to drought stress exceed $10 billion annually. In crop production, drought stress can be classified into pre- or post-flowering. Even though the world collections of sorghum contain over 35,000 accessions, the genetic base currently used in breeding programs is very small (about 3%). Thus, it is important to identify diverse breeding lines for crop improvement. The diversity (association) panel consisting of 300 sorghum lines from all over the world was assembled for trait evaluation and association mapping. In this research these lines were grouped into the five major races (Figure 1) and 10 intermediate races of sorghum. The objectives of the research are to: (i) quantify the performance of the diversity panel under field conditions in Kansas, (ii) identify critical physiological traits affected by drought at both pre- and post-flowering stages of sorghum development, (iii) identify the most sensitive stage to drought stress during the reproductive phase of sorghum development and, (iv) test the feasibility of using a chlorophyll fluorescence assay (CVA) as a tool for identifying stay-green lines in grain sorghum during early stages of crop development. Field experiments were conducted in 2006 and 2007 in two locations in Kansas (Manhattan and Hays) under rain fed and irrigated conditions for the association panel. Objectives (iii) and (iv) were achieved with controlled environment experiments conducted in the greenhouse at the agronomy department, Kansas State University in 2006 and 2007. Results showed that there was large genetic variability among and within different races in the diversity panel for growth, physiological traits and yield components. Some genotypes showed yield stability across the different environments that were investigated. Drought significantly decreased seed number and harvest index across genotypes and races. In grain sorghum the period prior to flowering (panicle initiation) was the most sensitive stage to drought stress, in terms of its effect on seed-set, during reproductive development. A cell viability assay showed that there were significant differences in the loss of cell viability between leaf sample of stay green and non-stay green genotypes when leaf samples are collected in the morning and subjected to high respiratory demand. Therefore the chlorophyll fluorescence assay has potential as a tool for stay green trait screening at early stages of growth in grain sorghum.

Grain sorghum

Chlorophyll fluorescence assay

Drought tolerance

Yield

Stress

Physiological traits

Agriculture, Agronomy (0285)

Potential pathogenicity of heterotrophic plate count bacteria isolated from untreated drinking water / Rachel Magrietha Petronella Prinsloo

Prinsloo, Rachel Magrietha Petronella

January 2014

Water is considered the most vital resource on earth and its quality is deteriorating. Not all residents living in South Africa‘s rural areas have access to treated drinking water, and use water from rivers, dams, and wells. The quality of these resources is unknown, as well as the effects of the bacteria in the water on human health. The heterotrophic plate count (HPC) method is a globally used test to evaluate microbial water quality. According to South African water quality guidelines, water of good quality may not contain more than a 1 000 coliforming units (CFU)/mℓ. There is mounting evidence that HPC bacteria may be hazardous to humans with compromised, underdeveloped, and weakened immune systems. In this study the pathogenic potential of HPC bacteria was investigated. Samples were collected from boreholes in the North West Province and HPCs were enumerated with a culture-based method. Standard physico-chemical parameters were measured for the water. Different HPC bacteria were isolated and purified and tested for α- or β-haemolysis, as well as the production of extracellular enzymes such as DNase, proteinase, lecithinase, chondroitinase, hyaluronidase and lipase, as these are pathogenic characteristics. The isolates were identified with 16S rRNA gene sequencing. The model for the human intestine, Hutu-80 cells, were exposed to the potentially pathogenic HPC isolates to determine their effects on the viability of the human cells. The isolates were also exposed to different dilutions of simulated gastric fluid (SGF) to evaluate its effect on the viability of bacteria. Antibiotic resistant potential of each isolate was determined by the Kirby-Bauer disk diffusion method. Three borehole samples did not comply with the physico-chemical guidelines. Half of the samples exceeded the microbial water quality guideline and the greatest CFU was 292 350 CFU/mℓ. 27% of the isolate HPC bacteria were α- or β- haemolytic. Subsequent analysis revealed the production of: DNase in 72%, proteinase in 40%, lipase and lecithinase in 29%, hyaluronidase in 25% and least produced was chondroitinase in 25%. The HPC isolates identified included: Alcaligenes faecalis, Aeromonas hydrophila and A. taiwanesis, Bacillus sp., Bacillus thuringiensis, Bacillus subtilis, Bacillus pumilus, Brevibacillus sp., Bacillus cereus and Pseudomonas sp. All the isolates, except Alcaligenes faecalis, were toxic to the human intestinal cells to varying degrees. Seven isolates survived exposure to the most diluted SGF and of these, four isolates also survived the intermediate dilution but, only one survived the highest SGF concentration. Some isolates were resistant to selected antibiotics, but none to neomycin and vancomycin. Amoxillin and oxytetracycline were the least effective of the antibiotics tested. A pathogen score was calculated for each isolate based on the results of this study. Bacillus cereus had the highest pathogen index with declining pathogenicity as follows: Alcaligenes faecalis > B. thuringiensis > Bacillus pumilus > Pseudomonas sp. > Brevibacillus > Aeromonas taiwanesis > Aeromonas hydrophila > Bacillus subtilis > Bacillus sp. The results of this study prove that standard water quality tests such as the physico-chemical and the HPC methods are insufficient to provide protection against the effects of certain pathogenic HPC bacteria. / MSc (Environmental Sciences), North-West University, Potchefstroom Campus, 2014

HPC bacteria

Extracellular enzymes

Cytotoxicity

Simulated gastric fluid

MTT assay

Antibiotic resistance

Functional analysis of ovine herpesvirus 2 encoded microRNAs

Riaz, Aayesha

January 2014

Ovine herpesvirus 2 (OvHV-2) is a gamma herpesvirus and is the causative agent of lymphoproliferative disease – sheep-associated malignant catarrhal fever in susceptible ruminants, including cattle. Sheep become persistently infected but do not show apparent clinical infection. MCF is characterized by marked T cell hyperplasia and proliferation of unrestricted cytotoxic large granular lymphocytes (LGLs) which leads to necrosis of infiltrated tissues and generally causes death of the host. Little is known about the underlying molecular basis of MCF pathogenesis or what controls the differences in clinical outcome of infection in two closely-related host species. MicroRNAs (miRNAs) constitute a large family of small, ~22nt, noncoding RNA molecules that regulate gene expression by targeting messenger RNAs post-transcriptianally in eukaryotes and viruses. Herpesvirus encoded miRNAs have been shown to play a role in regulating viral and cellular processes including cell cycle and may have a role in pathogenesis. OvHV-2 has also been found to encode for at least 46 OvHV-2 miRNAs in an immortalized bovine LGL cell line. 23 of these miRNAs have also been validated by northern blot analysis and RT qPCR. It was hypothesised that these OvHV-2 miRNAs may regulate viral and cellular genes expression and may play a role in MCF pathogenesis. The aim of this project was to determine if OvHV-2 miRNAs have functional targets within viral and host cell genes. Bio-informatic analysis has predicted several targets for these OvHV2 miRNAs in the 5’ and 3’ UTRs of several virus genes. Luciferase inhibition assay confirmed that out of 13 selected predicted targets, three (two targets ORF73 and one within ORF50) were positive and functional. A fourth predicted target was also found functional (ORF20), but its functionality could not be confirmed by knocking out the target site. A newly developed technique Crosslinking, Ligation And Sequencing of Hybrids (CLASH) was also used to identify miRNAs bound targets within cattle and sheep genome. High throughput sequencing and analysis of the hybrid data revealed many target genes. Four of those targeted genes, were validated by luciferase inhibition assays and three were found to be targeted by OvHV-2 miRNAs. This study gives the first evidence of viral miRNAs bound to their targets in cattle and sheep cells, by a highly sensitive technique-CLASH and provides a tool for studying differences in pathogenesis of two closely-related host species.

636.3

Thyroid Endocrine Disruption of Propylparaben Assessed Using an Optimized Individual Xenopus tropicalis Metamorphosing Tadpole Exposure System

Pohl, Johannes

January 2015

The anuran Xenopus tropicalis tadpole is an attractive model animal in toxicological evaluation of suspected thyroid disrupting xenobiotics. Due to its reliance of a functioning hypothalamic-pituitary-thyroid (HPT) axis for normal metamorphosis, effects on the HPT axis produces apical endpoints, which are easy to measure. More sensitive endpoints of mRNA expression and histological evaluation of the thyroid gland itself provide strong indications of in vivo thyroid endocrine disruption. X. tropicalis is traditionally exposed in groups of 20 animals in four replicates for each treatment group. However, exposing tadpoles individually can provide stronger statistics and a reduction of total animal sacrifice. In this study we have developed and optimized an individual exposure system by a method development study. This method was then applied in an exposure experiment of a suspected thyroid endocrine disruptor, propylparaben (PrP). Prometamorphotic (NF stage 51) X. tropicalis tadpoles were distributed in three treatment groups (0.05, 0.5 and 5.0 mg PrP/L water) and maintained semi-statically for 14 days. Afterwards, apical measurements (body weight (BW), total body length (BL), snout to vent length (SVL) and hind limb length (HLL)) and reached developmental stage were assessed. In addition, mRNA expression of HPT axis relevant genes encoding deiodinase 2 (D2, hepatic tissue), deiodinase 3 (D3, hepatic and tail tissue) and transthyretin (Ttr, hepatic tissue) were measured by quantitative reverse transcription PCR (qRT-PCR). The PrP exposure did not affect general growth and development, but it did cause a downregulation of dio3 and ttr. The downregulation of dio3 could possibly be associated with a reduced serum content of thyroid hormone, while ttr might be connected to a previously described xenoestrogenic effect of PrP in vitro and in fish.

Xenopus

Thyroid hormones

Endocrine disruption

Amphibian metamorphosis assay

Propylparaben

Hormonstörande ämnen

Propylparaben

Xenopus

Sköldkörtelhormoner

Process monitoring and control using live cell imaging for the manufacturing of cell therapies

Smith, David

January 2014

Regenerative medicine (RM) represents a promising enabling technology to revolutionize healthcare. This said there are still major gaps between the commercial promise and the reality of the cell therapy sector of regenerative medicine. There is consensus to develop high through-put, automated technologies for the manufacture of RM products. Imaging methods will have the capacity to contribute to this technological gap for cell therapies and are particularly attractive to provide non-destructive monitoring with high spatial and temporal resolution. This work applied an automated, non-invasive phase contrast imaging platform (Cell-IQ) to measure, analyse and ultimately quantify image derived metrics for human embryonic stem cells (hESCs) and haematopoietic stem cells (HSCs) as part of the colony forming unit (CFU) assay. This work has shown through thresholding and machine vision identification technology, imaging has the ability to improve the precision of current evaluation methods for cell culture, providing novel information regarding culture state and show image derived metrics to be predictive of future culture state. Building on this, differentiation through the addition of a growth factor cocktail highlighted how in-process monitoring enables protocol optimisation. After equilibrating the Cell-IQ incubator to a standard incubator, the progress of the CFU assay was monitored and image metrics representative of colony phenotype were analysed. Cell count, distance between cells and cell migration within individual colonies were identified to be informative and provide a degree of colony phenotype separation. Quantitative, novel, image derived metrics were identified that improve reliability through computer automation, cost by removing user verification and time by reducing the assay time from 14 days to 7 days. Non-invasive imaging provides a fantastic opportunity to create bespoke sampling frequencies to achieve desired precision for manufacturing cell therapies, this work has developed and shown improvement and a level of control to current culture process for ESCs and HSCs.

616.02