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Molecular Tools for Biomarker DetectionChen, Lei January 2017 (has links)
The advance of biological research promotes the emerging of new methods and solutions to answer the biological questions. This thesis describes several new molecular tools and their applications for the detection of genomic and proteomic information with extremely high sensitivity and specificity or simplify such detection procedures without compromising the performance. In paper I, we described a general method namely super RCA, for highly specific counting of single DNA molecules. Individual products of a range of molecular detection reactions are magnified to Giga-Dalton levels that are easily detected for counting one by one, using methods such as low-magnification microscopy, flow cytometry, or using a mobile phone camera. The sRCA-flow cytometry readout presents extremely high counting precision and the assay’s coefficient of variation can be as low as 0.5%. sRCA-flow cytometry readout can be applied to detect the tumor mutations down to 1/100,000 in the circulating tumor cell-free DNA. In paper II, we applied the super RCA method into the in situ sequencing protocol to enhance the amplified mRNA detection tags for better signal-to-noise ratios. The sRCA products co-localize with primary RCA products generated from the gene specific padlock probes and remain as a single individual object in during the sequencing step. The enhanced sRCA products is 100% brighter than regular RCA products and the detection efficiency at least doubled with preserved specificity using sRCA compared to standard RCA. In paper III, we described a highly specific and efficient molecular switch mechanism namely RCA reporter. The switch will initiate the rolling circle amplification only in the presence of correct target sequences. The RCA reporter mechanism can be applied to recognize single stranded DNA sequences, mRNA sequences and sequences embedded in the RCA products. In paper IV, we established the solid phase Proximity Ligation Assay against the SOX10 protein using poly clonal antibodies. Using this assay, we found elevated SOX10 in serum at high frequency among vitiligo and melanoma patients. While the healthy donors below the threshold.
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Padlock Probe-Based Assays for Molecular DiagnosticsMezger, Anja January 2015 (has links)
Treatment success often depends on the availability of accurate and reliable diagnostic assays to guide clinical practitioners in their treatment choices. An optimal test must excel in specificity and sensitivity, and depending on the application area time, low-cost and simplicity are equally important. For instance, time is essential in infectious diagnostics but this is less important in non-invasive prenatal testing (NIPT). In NIPT, specificity and sensitivity are the most important parameters. In this thesis I describe the development of four different methods, all based on padlock probes and rolling circle amplification, intended for molecular diagnostics. Application areas range from infectious disease diagnostics to NIPT and oncology. The methods described have in common that they overcome certain limitations of currently available assays. This thesis includes two new assays targeting infectious agents: one assay specifically detecting a highly variable double stranded RNA virus and the second assay demonstrating a new format of antibiotic susceptibility testing, which is rapid and generally applicable to different pathogens. Furthermore, I describe the development of a method that uses methylation markers to enrich fetal DNA, accurately quantify chromosome ratios and thus, detecting trisomy 21 and 18. The fourth method described in this thesis uses gap-fill ligation of padlock probes to detect diagnostic relevant point mutations with high specificity in situ. The assays presented have the potential, after automation and successful validation and verification studies, to be implemented into clinical practice. Furthermore, these assays demonstrate the wide applicability of padlock probes which, due to their properties in regard to specificity and multiplexity, are useful tools for nucleic acid detection in vitro as well as in situ. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 3: Manuscript. Paper 4: Manuscript.</p>
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Elektroniskt släpvagnslåsGyllenberg, Marcus, Werngren, Filip January 2020 (has links)
To create a more effective society for everyone by develop an unique product for society, this can be done through various steps. In this report, the projekt team has chosen to move forward with a product that is currently ineffective. Together with the company MiAB, which currently uses a common bicycle lock for its trailers, manufactures an electronic trailer lock. The purpose of this lock is to streamline the rental and to facilitate the user ergonomically. The aim is the report is to make the essential part of Freddy Olsson methodology as well as Stanford d.school: The Bootcamp Bootleg to take the already existing product and enhance its design and take into account of human needs and limitations. The report has produced a number of different product proposals that have later have been weighted with the company's requirements and wishes. The report has also made the necessary calculations to check that the new product meets all the different requirement that have been set up. The report has concluded that the new product is more ergonomic and smoother then the previous product and can confirm that all the requirements and wishes in this report has been fulfilled. This report will not deal with the electronics parts in this product and leaves that for another report and directs all the focus solely on the mechanical and design aspects.
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Padlock Probes and Rolling Circle Amplification : New Possibilities for Sensitive Gene DetectionMendel-Hartvig, Maritha January 2002 (has links)
<p>A series of novel methods for detection of known sequence variants in DNA, in particular single nucleotide polymorphism, using padlock probes and rolling circle replication are presented. DNA probes that can be circularized – padlock probes – are ideal for rolling circle replication. Circularized, but not unreacted probes, can generate powerful signal amplification by allowing the reacted probes to template a rolling circle replication (RCR) reaction. However, when hybridized and ligated to a target DNA molecule with no nearby ends, the probes are bound to the target sequence, inhibiting the RCR reaction is. This problem can be solved by generating a branched DNA probe with two 3’ arms such that the probes may be circularized while leaving the second 3’ arm as a primer for the RCR reaction. We describe how T4 DNA ligase can be used for efficient construction of DNA molecules having one 5’ end but two distinct 3’ ends that extend from the 2’ and 3’ carbons of an internal nucleotide. An even stronger approach to circumvent the topological problem that can inhibit RCR is to restriction digest the template downstream of the padlock recognition site. By using Phi 29 DNA polymerase with efficient 3’ exonuclease and strand displacement activity, the template strand can then be used to prime the RCR reaction. The amplified molecule is contiguous with the target DNA, generating an anchored localized signal. The kinetics of the reaction was investigated by following the reaction in real-time using molecular beacon probes. Localized RCR signal were obtained on DNA arrays, allowing detection of as little as 104-105 spotted molecules, of either single- or double-stranded M13 DNA, in a model experiment. We have also established a serial rolling circle amplification procedure. By converting rolling circle products to a second and even third generation of padlock probes the signal was amplified thousand-fold per generation. This procedure provides sufficient sensitivity for detection of single-copy gene sequences in 50 ng of human genomic DNA, and large numbers of probes were amplified in parallel with excellent quantitative resolution.</p>
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Biomolecular Analysis by Dual-Tag Microarrays and Single Molecule AmplificationEricsson, Olle January 2008 (has links)
<p>Padlock probes and proximity ligation are two powerful molecular tools for detection of nucleic acids and proteins, respectively. Both methods result in the formation of DNA reporter molecules upon recognition of specific target molecules. These reporter molecules can be designed to include tag sequences that can be analyzed by techniques for nucleic acid analysis. Herein, I present a dual-tag microarray (DTM) platform that is suitable for high-performance analyses of DNA reporter molecule libraries, generated by padlock and proximity probing reactions. The DTM platform was applied for analysis of mRNA transcripts using padlock probes, and of cytokines using proximity ligation. The platform drastically improved specificity of detection, and it allowed precise measurements of proteins and nucleic acids over wide dynamic ranges.</p><p>The thesis also presents two techniques for multi-probe analyses of biomolecules: the triple-specific proximity ligation assay (3PLA) for protein analyses, and the spliceotyping assay for mRNA analyses. 3PLA allows highly specific measurements of as little as hundreds of target protein molecules by interrogating three target epitopes simultaneously. In spliceotyping the exon composition of individual transcripts are represented as a series of tag sequences in DNA reporter molecules, via a series of target-dependent ligation reactions. Next, the splicing patterns along individual transcripts can be revealed by amplified single molecule detection and step-wise decoding.</p>
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Detection of Biomolecules Using Volume-Amplified Magnetic NanobeadsZardán Gómez de la Torre, Teresa January 2012 (has links)
This thesis describes a new approach to biomolecular analysis, called the volume-amplified magnetic nanobead detection assay (VAM-DNA). It is a sensitive, specific magnetic bioassay that offers a potential platform for the development of low-cost, easy-to-use diagnostic devices. The VAM-NDA consists of three basic steps: biomolecular target recognition, enzymatic amplification of the probe-target complex using the rolling circle amplification (RCA) technique, and addition of target complementary probe-tagged magnetic nanobeads which exhibit Brownian relaxation behavior. Target detection is demonstrated by measuring the frequency-dependent complex magnetization of the magnetic beads. The binding of the RCA products (target DNA-sequence coils) to the bead surface causes a dramatic increase in the bead size, corresponding essentially to the size of the DNA coil (typically around one micrometer). This causes a decrease in the Brownian relaxation frequency, since it is inversely proportional to the hydrodynamic size of the beads. The concentration of the DNA coils is monitored by measuring the decrease in amplitude of the Brownian relaxation peaks of free beads. The parameters oligonucleotide surface coverage, bead concentration, bead size and RCA times were investigated in this thesis to characterize features of the assay. It was found that all of these parameters affect the outcome and efficiency of the assay. The possibility of implementing the assay on a portable, highly sensitive AC susceptometer platform was also investigated. The performance of the assay under these circumstances was compared with that using a superconducting quantum interference device (SQUID); the sensitivity of the assay was similar for both platforms. It is concluded that, the VAM-NDA opens up the possibility to perform biomolecular detection in point-of-care and outpatient settings on portable platforms similar to the one tested in this thesis. Finally, the VAM-NDA was used to detect Escherichia coli bacteria and the spores of Bacillus globigii, the non-pathogenic simulant of Bacillus anthracis. A limit of detection of at least 50 bacteria or spores was achieved. This shows that the assay has great potential for sensitive detection of biomolecules in both environmental and biomedical applications.
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Padlock Probes and Rolling Circle Amplification : New Possibilities for Sensitive Gene DetectionMendel-Hartvig, Maritha January 2002 (has links)
A series of novel methods for detection of known sequence variants in DNA, in particular single nucleotide polymorphism, using padlock probes and rolling circle replication are presented. DNA probes that can be circularized – padlock probes – are ideal for rolling circle replication. Circularized, but not unreacted probes, can generate powerful signal amplification by allowing the reacted probes to template a rolling circle replication (RCR) reaction. However, when hybridized and ligated to a target DNA molecule with no nearby ends, the probes are bound to the target sequence, inhibiting the RCR reaction is. This problem can be solved by generating a branched DNA probe with two 3’ arms such that the probes may be circularized while leaving the second 3’ arm as a primer for the RCR reaction. We describe how T4 DNA ligase can be used for efficient construction of DNA molecules having one 5’ end but two distinct 3’ ends that extend from the 2’ and 3’ carbons of an internal nucleotide. An even stronger approach to circumvent the topological problem that can inhibit RCR is to restriction digest the template downstream of the padlock recognition site. By using Phi 29 DNA polymerase with efficient 3’ exonuclease and strand displacement activity, the template strand can then be used to prime the RCR reaction. The amplified molecule is contiguous with the target DNA, generating an anchored localized signal. The kinetics of the reaction was investigated by following the reaction in real-time using molecular beacon probes. Localized RCR signal were obtained on DNA arrays, allowing detection of as little as 104-105 spotted molecules, of either single- or double-stranded M13 DNA, in a model experiment. We have also established a serial rolling circle amplification procedure. By converting rolling circle products to a second and even third generation of padlock probes the signal was amplified thousand-fold per generation. This procedure provides sufficient sensitivity for detection of single-copy gene sequences in 50 ng of human genomic DNA, and large numbers of probes were amplified in parallel with excellent quantitative resolution.
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Biomolecular Analysis by Dual-Tag Microarrays and Single Molecule AmplificationEricsson, Olle January 2008 (has links)
Padlock probes and proximity ligation are two powerful molecular tools for detection of nucleic acids and proteins, respectively. Both methods result in the formation of DNA reporter molecules upon recognition of specific target molecules. These reporter molecules can be designed to include tag sequences that can be analyzed by techniques for nucleic acid analysis. Herein, I present a dual-tag microarray (DTM) platform that is suitable for high-performance analyses of DNA reporter molecule libraries, generated by padlock and proximity probing reactions. The DTM platform was applied for analysis of mRNA transcripts using padlock probes, and of cytokines using proximity ligation. The platform drastically improved specificity of detection, and it allowed precise measurements of proteins and nucleic acids over wide dynamic ranges. The thesis also presents two techniques for multi-probe analyses of biomolecules: the triple-specific proximity ligation assay (3PLA) for protein analyses, and the spliceotyping assay for mRNA analyses. 3PLA allows highly specific measurements of as little as hundreds of target protein molecules by interrogating three target epitopes simultaneously. In spliceotyping the exon composition of individual transcripts are represented as a series of tag sequences in DNA reporter molecules, via a series of target-dependent ligation reactions. Next, the splicing patterns along individual transcripts can be revealed by amplified single molecule detection and step-wise decoding.
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Expression and Mutation Analyses of Candidate Cancer Genes In SituKiflemariam, Sara January 2012 (has links)
Cancers display heterogeneity in genetic profiles of the individual cancer cells and in the composition of different malignant and non-malignant cell populations. Such intra-tumor heterogeneity plays a role in treatment response and the emergence of resistance to cancer therapies. Approaches that address this complexity and improve stratification of patients for treatment are therefore highly warranted. Thus, the aims of this thesis were to further develop and apply in situ technologies for expression and mutation analyses of candidate cancer genes to gain a deeper understanding of cancer biology and to study intra-tumor heterogeneity. In paper I, we established and validated a procedure for scalable in situ hybridization of large gene sets in human formalin-fixed paraffin-embedded tissues for analysis of gene expression. This method was used in paper II for large-scale expression analysis of the tyrosine kinome and phosphatome, two gene families whose members are frequently mutated in many forms of cancers. Systematic, compartment-specific expression mapping at cell type resolution enabled us to identify several novel vascular markers that have gone unnoticed in bulk transcriptomic analyses. In papers III and IV, we used padlock probes for in situ mutation detection in single cells for studies of genetic intra-tumor heterogeneity. In paper III, multiplex detection and genotyping of oncogenic point mutations was demonstrated in routinely processed tissue materials, whereas in paper IV we further the application by demonstrating multiplex detection of fusion gene transcripts. Collectively, the work presented in this thesis employs in situ-based methods to obtain spatial resolution of gene expression and mutation patterns in normal and cancer tissues, thereby broadening our understanding of the cancer genome.
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In situ Sequencing : Methods for spatially-resolved transcriptome analysisMignardi, Marco January 2014 (has links)
It is well known that cells in tissues display a large heterogeneity in gene expression due to differences in cell lineage origin and variation in the local environment at different sites in the tissue, a heterogeneity that is difficult to study by analyzing bulk RNA extracts from tissue. Recently, genome-wide transcriptome analysis technologies have enabled the analysis of this variation with single-cell resolution. In order to link the heterogeneity observed at molecular level with the morphological context of tissues, new methods are needed which achieve an additional level of information, such as spatial resolution. In this thesis I describe the development and application of padlock probes and rolling circle amplification (RCA) as molecular tools for spatially-resolved transcriptome analysis. Padlock probes allow in situ detection of individual mRNA molecules with single nucleotide resolution, visualizing the molecular information directly in the cell and tissue context. Detection of clinically relevant point mutations in tumor samples is achieved by using padlock probes in situ, allowing visualization of intra-tumor heterogeneity. To resolve more complex gene expression patterns, we developed in situ sequencing of RCA products combining padlock probes and next-generation sequencing methods. We demonstrated the use of this new method by, for the first time, sequencing short stretches of transcript molecules directly in cells and tissue. By using in situ sequencing as read-out for multiplexed padlock probe assays, we measured the expression of tens of genes in hundreds of thousands of cells, including point mutations, fusions transcripts and gene expression level. These molecular tools can complement genome-wide transcriptome analyses adding spatial resolution to the molecular information. This level of resolution is important for the understanding of many biological processes and potentially relevant for the clinical management of cancer patients. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 4: Manuscript.</p>
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