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Virtual Electrode-induced Spiral Reentry in Ventricular Myocardium Perfused in-vitroArafune, Tatsuhiko, Mishima, Akira, Sakuma, Ichiro, Inada, Hiroshi, Shibata, Nitaro, Nakagawa, Harumichi, Yamazaki, Masatoshi, Honjo, Haruo, Kodama, Itsuo 12 1900 (has links)
国立情報学研究所で電子化したコンテンツを使用している。
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Virtual Electrode Polarization-Induced Reentrant ActivityNakagawa, Harumichi, Yamazaki, Masatoshi, Nihei, Motoki, Niwa, Ryoko, Arafune, Tatsuhiko, Mishima, Akira, Nashimoto, Shiho, Shibata, Nitaro, Honjo, Haruo, Sakuma, Ichiro, Kamiya, Kaichiro, Kodama, Itsuo 12 1900 (has links)
国立情報学研究所で電子化したコンテンツを使用している。
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Optical imaging and stimulation systems for engineered human cardiac tissuesSun, Jingyi (Jenny) 26 January 2022 (has links)
Heart disease is the leading cause of death in the world. Finding future therapeutics for heart disease requires the development of mature 3D engineered human cardiac tissues that can serve as reliable models for biological studies and drug development. The ability to measure and stimulate cardiac action potentials (APs) is key to the development of these 3D tissue models.
Optical measurement and stimulation methods offer an enticing solution to longstanding tissue development testbed needs. However, existing optical measurement methods have relied on toxic voltage dyes and motion inhibiting drugs, and existing optical stimulation methods have mainly focused on optogenetic modification techniques.
In this dissertation, I present two related optical systems built for 3D engineered human cardiac microtissues, organized into two chapters: 1) a dual-mode voltage and contraction imaging optical microscope for tracking action potential metrics with fluorescent genetically encoded voltage indicator Archon1, and 2) an all optical cardiac stimulation system for unmodified engineered human cardiac micro-tissues with red and blue laser pulse options. These systems offer cardiac researchers less invasive optical solutions for cardiac action potential visualization and pacing: the microscope system allows direct action potential measurements without the use of toxic dyes, and the stimulation system allows ex-vivo pacing without any modification to the sample, genetic or otherwise. I will discuss the system design motivations, challenges, results, and mechanisms of this work.
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Utility and limitations of cardiac tissue slices for the study of cardiac electrophysiologyWang, Ken January 2015 (has links)
Cardiac tissue slices, a rarely used pseudo two-dimensional preparation, have gained increasing popularity for applications such as drug testing over the last ten years as they combine ease of handling with patho-physiologically relevant cell-type representation, distribution and inter-connection. The most well-established methods to measure electrophysiology in cardiac tissue are sharp electrodes and multi-electrode-arrays, techniques which are limited in spatial resolution or signal content. In this work, we have applied dual voltage Ca<sup>2+</sup> optical mapping on cardiac slices, allowing us to record these two key parameters simultaneously at high spatio-temporal resolution, yielding better visualisation of conduction waves, spatial dispersion in action potential (AP) characteristics, and intracellular Ca<sup>2+</sup> transient (CaT). The slice preparation method and the measurement protocols were refined to yield good reproducibility. Data analysis routines were developed to extract relevant parameters reliably. Despite being a promising candidate for drug testing, little is known about how slice and intact whole-heart AP properties are interrelated, and how to scale-up from observations in two dimensions (2D) to the three dimensional (3D) heart. In this thesis, we present a method to compare directly AP properties of intact whole-heart and tissue slices, and show the extent to which slices preserve AP characteristics. We have explored the suitability of tissue slices as an experimental model to study stretch induced changes in AP and CaT. During axial stretch, a dynamic profile of both AP and CaT was observed with an initial shortening of both AP and CaT duration, followed by a gradual recovery/prolongation. We have also used tissue slices to study spatial heterogeneity of AP and CaT properties in the rabbit left ventricular free wall. A transmural gradient can be captured in CaT and AP (with the longest APD and CaT durations being captured in the subendocardium). No large AP prolongation was found in the mid-myocardium. We conclude that the cardiac tissue slice preparation preserves some key functional parameters of the whole heart and is a promising model to study cardiac electrophysiology.
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Electrical Coupling Between Cardiomyocytes and Unexcitable Cells: The Effect of Cardiac Fibroblasts and Genetically Engineered HEK-293 Cells on Cardiac Action Potential Shape and PropagationMcSpadden, Luke Christopher January 2011 (has links)
<p>Excess cardiac myofibroblasts in fibrotic heart diseases as well as cell-based therapies involving implantation of stem cells or genetically engineered somatic cells in the heart may all lead to a situation where a cardiomyocyte becomes electrically coupled to an unexcitable cell. In these settings, electrotonic loading of cardiomyocytes by unexcitable cells can affect cardiac action potential generation, propagation, and repolarization depending on the properties of both cardiomyocytes and unexcitable cells. The objective of this dissertation was to advance our understanding of the electrical interactions between cardiomyocytes and unexcitable cells using a variety of electrophysiological, molecular, and cell culture techniques.</p><p>First, we utilized aligned cardiomyocyte monolayers covered with unexcitable cardiac fibroblasts or human embryonic kidney-293 (HEK) cells that expressed similar levels of the gap junction protein connexin-45. These cells weakly coupled to cardiomyocytes and marginally slowed cardiac conduction only at high coverage density, while producing no other measurable electrophysiological changes in cardiomyocytes. In contrast, unexcitable HEK cells genetically engineered to stably express the more conductive connexin-43 channels (Cx43 HEK) strongly coupled to cardiomyocytes, depolarized cardiac resting membrane potential, significantly slowed impulse propagation, decreased maximum capture rate, and increased action potential duration (APD) at high coverage density. None of the studied unexcitable cells significantly altered conduction velocity anisotropy ratio or the relatively low incidence of pacemaking activity of cardiac monolayers at any coverage density.</p><p>Next, we utilized individual micropatterned cell pairs consisting of a cardiomyocyte and an unexcitable Cx43 HEK cell with or without stably overexpressed inward rectifier potassium channels (Kir2.1+Cx43 HEK). By systematically varying the relative sizes of micropatterned cells, we showed that Cx43 HEK cells significantly depolarized cardiomyocytes, reduced maximum upstroke velocity and action potential amplitude, prolonged APD, and modulated beating rate as a function of HEK:CM area ratio. In contrast, in cell pairs formed between cardiomyocytes and Kir2.1+Cx43 HEK cells we observed significant reduction in cardiomyocyte action potential amplitude, duration, and maximum upstroke velocity, but no change in other measured parameters.</p><p>Finally, we utilized a hybrid dynamic clamp setting consisting of a live micropatterned cardiomyocyte coupled in real time to a virtual model of capacitive and/or ionic current components of Cx43 HEK or Kir2.1+Cx43 HEK cells. We found that coupling of cardiomyocytes to the ionic current components of Cx43 HEK or Kir2.1+Cx43 HEK cells was sufficient to reproduce the dependence of cardiomyocyte maximal diastolic potential and pacemaking behavior on HEK:CM area ratio observed in micropatterned cell pairs, but did not replicate the observed changes in action potential upstroke or duration. The pure capacitance model with no ionic current, on the other hand, significantly decreased cardiomyocyte maximum upstroke velocity and prolonged cardiomyocyte APD as function of HEK:CM area ratio without affecting maximal diastolic potential or pacemaking behavior. When the unexcitable cell model containing both capacitive and ionic currents was connected to cardiomyocytes, all changes in action potential shape observed in micropatterned cell pairs were accurately reproduced. </p><p>These studies describe how coupling of unexcitable cells to cardiomyocytes can alter cardiomyocyte electrophysiological properties dependent on the unexcitable cell connexin isoform expression, ion channel expression, and cell size. This knowledge is expected to aid in the design of safe and efficient cell and gene therapies for myocardial infarction, fibrotic heart disease, and cardiac arrhythmias.</p> / Dissertation
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Evaluation of the Genetic Differences Between Two Subtypes of Campylobacter fetus (Fetus and Venerealis) in CanadaMukhtar, Lenah 19 August 2013 (has links)
The pathogen Campylobacter fetus (CF) is classified into two subspecies, Campylobacter fetus subspecies fetus (CFF) and Campylobacter fetus subspecies venerealis (CFV). Even though CFF and CFV are genetically closely related, they exhibit differences in their host adaptation; CFF inhabits the gastrointestinal tract of both humans and several animal species, while classical CFV is specific to the bovine genital tract and is of particular concern with respect to international bovine trade regulation. Traditionally, differentiation between the two subspecies has been achieved using a limited number of biochemical tests but more rapid and definitive genetic methods of discrimination are desired. A recent study suggested that the presence of a genomic island only in CFV could discriminate between the two sub- species but this hypothesis could not be confirmed on a collection of isolates originating in Canada.
To identify alternative gene targets that would support accurate subspecies discrimination, this study has applied several approaches including suppression subtractive hybridization and whole genome sequencing supplemented with optical mapping. A subtractive hybridization screen, using a well-characterized CFV isolate recovered during routine screening of bulls in an Artificial Insemination center in western Canada and that lacked much of the genomic island and a typical Canadian CFF isolate, yielded 50 clones; characterization of these clones by hybridization screening against selected CF isolates and by nucleotide sequence BLAST analysis identified three potentially CFV-specific clones that contained inserts originating from a second genomic island. Further screening using a larger CF sample set found that only Clone #35 was truly CFV-specific. Optical maps (NcoI digest) of the Canadian CFF and CFV isolates used for the subtractive hybridization showed that certain regions of these genomes were quite distinct from those of two reference strains. Whole genome sequencing of these two isolates identified two target genes (PICFV5_ORF548 and CFF_Feature #3) that appear to be selectively retained in the two subspecies. Screening of a collection of CF isolates by PCRs targeting these three loci (SSH_Clone #35, PICFV5_ORF548 and CFF_Feature #3) supported their use for subspecies discrimination. This work demonstrates the complex genomic diversity associated with these CF subtypes and the challenge posed by their discrimination using limited genetic loci.
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Vliv pracovní zátěže na rané stádium vývoje převodního systému srdečního / Effects of Mechanical Loading on Early Conduction System DifferentiationMachálek, Jakub January 2011 (has links)
6 ABSTRAKT Kardiovaskulární onemocnění představují celosvětově nejčastější příčinu úmrtí. Arytmie neboli poruchy srdečního rytmu k této mortalitě přispívají nemalou měrou. Výzkum v oblasti morfologie převodního systému srdečního má více jak stoletou historii, ale oblast ontogeneze není ani v dnešní době dostatečně prozkoumána. Přitom pochopení mechanismů indukce pracovního myokardu ve specializovanou tkáň by mohl být jeden z klíčů k otevření dveří nových možností diagnostiky a terapie onemocnění v této oblasti. Cílem této práce je pochopení vlivu mechanické zátěže na vznik a vývoj převodního systému srdečního. Chci prokázat, že mechanické zatížení srdce krevním oběhem hraje v embryonálním vývoji nezastupitelnou roli v diferenciaci převodního systému srdečního (PSS). Jako model pozorování jsem si vybral kuřecí srdce. Při porovnání dat získaných na srdci ptáků a savců můžeme najít drobné odlišnosti v detailech, nicméně hlavní principy a mechanismy se zdají být stejné. Kuřecí embryo se vyvíjí 21 dní, přičemž toto časové údobí lze podle Hamburgera a Hamiltona rozdělit do 46 stádií. Zpočátku představuje srdce pouze primitivní trubici, která se stáčí v srdeční kličku. Posléze je přeměněna na zralý čtyřoddílový orgán charakteristický pro vyšší obratlovce. Tyto morfologické změny korelují i se změnami šíření...
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Evaluation of the Genetic Differences Between Two Subtypes of Campylobacter fetus (Fetus and Venerealis) in CanadaMukhtar, Lenah January 2013 (has links)
The pathogen Campylobacter fetus (CF) is classified into two subspecies, Campylobacter fetus subspecies fetus (CFF) and Campylobacter fetus subspecies venerealis (CFV). Even though CFF and CFV are genetically closely related, they exhibit differences in their host adaptation; CFF inhabits the gastrointestinal tract of both humans and several animal species, while classical CFV is specific to the bovine genital tract and is of particular concern with respect to international bovine trade regulation. Traditionally, differentiation between the two subspecies has been achieved using a limited number of biochemical tests but more rapid and definitive genetic methods of discrimination are desired. A recent study suggested that the presence of a genomic island only in CFV could discriminate between the two sub- species but this hypothesis could not be confirmed on a collection of isolates originating in Canada.
To identify alternative gene targets that would support accurate subspecies discrimination, this study has applied several approaches including suppression subtractive hybridization and whole genome sequencing supplemented with optical mapping. A subtractive hybridization screen, using a well-characterized CFV isolate recovered during routine screening of bulls in an Artificial Insemination center in western Canada and that lacked much of the genomic island and a typical Canadian CFF isolate, yielded 50 clones; characterization of these clones by hybridization screening against selected CF isolates and by nucleotide sequence BLAST analysis identified three potentially CFV-specific clones that contained inserts originating from a second genomic island. Further screening using a larger CF sample set found that only Clone #35 was truly CFV-specific. Optical maps (NcoI digest) of the Canadian CFF and CFV isolates used for the subtractive hybridization showed that certain regions of these genomes were quite distinct from those of two reference strains. Whole genome sequencing of these two isolates identified two target genes (PICFV5_ORF548 and CFF_Feature #3) that appear to be selectively retained in the two subspecies. Screening of a collection of CF isolates by PCRs targeting these three loci (SSH_Clone #35, PICFV5_ORF548 and CFF_Feature #3) supported their use for subspecies discrimination. This work demonstrates the complex genomic diversity associated with these CF subtypes and the challenge posed by their discrimination using limited genetic loci.
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Ratiometric fluorescence imaging and marker-free motion tracking of Langendorff perfused beating rabbit heartsKappadan, Vineesh 14 July 2020 (has links)
No description available.
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Genomic Structural Variation Across Five Continental Populations of Drosophila melanogasterLong, Evan Michael 01 April 2018 (has links)
Chromosomal structure variations (SV) including insertions, deletions, inversions, and translocations occur within the genome and can have a significant effect on organismalphenotype. Some of these effects are caused by structural variations containing genes. Modern sequencing using short reads makes the detection of large structural variations (> 1kb) very difficult. Large structural variations represent a significant amount of the genetic diversity within a population. We used a global sampling of Drosophila melanogaster (Ithaca, Zimbabwe, Beijing, Tasmania, and Netherlands) to represent diverse populations. We used long-read sequencing and optical mapping technologies to identify SVs in these genomes. Because the average read length used for these approaches are much longer than traditional short read sequencing, these maps facilitate the identification of chromosomal SVs of greater size and with more clarity. We found a wide diversity of structural variations in each of the five strains. These structural variations varied greatly in size and location, and significantly affected exonic regions of the genome. Structural variations accounted for a much larger difference in number of base pairs between strains than single nucleotide polymorphisms (SNPs).
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