Imaging and Control of Engineered Cells using Magnetic Fields

Making cells magnetic is a long-standing goal of synthetic biology, aiming to enable the separation of cells from complex biological samples and their non-invasive visualization in vivo using Magnetic Resonance Imaging (MRI). Previous efforts towards this goal, focused on engineering cells to biomineralize superparamagnetic or ferromagnetic iron oxides, have largely been unsuccessful due to the stringent required chemical conditions. In this thesis, we introduce an alternative approach to making cells magnetic, focusing on biochemically maximizing cellular paramagnetism. Here, we show that a novel genetic construct combining the functions of ferroxidation and iron-chelation enables engineered bacteria to accumulate iron in 'ultraparamagnetic' macromolecular complexes, which subsequently allows for these cells to be trapped using strong magnetic field gradients and imaged using MRI in vitro and in vivo. We characterize the properties of these cells and complexes using magnetometry, an array of spectroscopic techniques, biochemical assays, and computational modeling to elucidate the unique mechanisms and implications of this 'ultraparamagnetic' concept. In addition to making cells magnetic, remote control of cellular localization in deep tissue is another long-standing goal of synthetic biology. Such an ability to non-invasively direct cells to sites of interest will not only improve therapeutic outcomes by minimizing off-target activity, but more broadly enable new research on complex cellular communities, such as the gut microbiome, in living animals. Given their deep penetrance through tissues, magnetic fields are ideally suited for facilitating non-invasive targeting of cells; however, the rapid decay of magnetic flux density from its source currently limits the depths to which magnetic targeting can be employed to within 1-2 mm from the surface. Here, we demonstrate a new approach wherein the retention of orally-administered and synthetically magnetized cell-like-particles is selectively enhanced within the murine intestinal tract to depths of up to 13 mm from the surface. Our cellular localization assisted by magnetic particles (CLAMP) strategy can potentially be generalized to any cell (bacterial, mammalian) or drug-containing nanoparticle of interest, and can be combined with existing non-invasive imaging modalities thereby facilitating remote environmental sensing at sites of interest. Finally, while magnetic fields in MRI scanners are widely used today to safely and non-invasively image anatomical structures in living animals, much of the image contrast in MRI is the result of microscale magnetic-field variations in tissues. However, the connection between these microscopic patterns and the appearance of macroscopic MR images has not been the subject of direct experimental studies due to a lack of methods to map microscopic fields in biological samples under ambient conditions. Here, we optically probed magnetic fields in mammalian cells and tissues with submicron resolution and nanotesla sensitivity using nitrogen-vacancy (NV) diamond magnetometry and combined these measurements with simulations of nuclear-spin precession to predict the corresponding MRI contrast. Additionally, we demonstrate the broad utility of this technology for imaging an in vitro model of cellular iron uptake, as well as imaging histological samples from a mouse model of hepatic iron overload. Taken together, our approach bridges a fundamental intellectual gap between a macroscopic MRI voxel and its microscopic constituents.</p

61st Annual Rocky Mountain Conference on Magnetic Resonance

Final program, abstracts, and information about the 61st annual meeting of the Rocky Mountain Conference on Magnetic Resonance, co-endorsed by the Colorado Section of the American Chemical Society and the Society for Applied Spectroscopy. Held in Copper Mountain, Colorado, July 25-29, 2022

Understanding Quantum Technologies 2022

Understanding Quantum Technologies 2022 is a creative-commons ebook that provides a unique 360 degrees overview of quantum technologies from science and technology to geopolitical and societal issues. It covers quantum physics history, quantum physics 101, gate-based quantum computing, quantum computing engineering (including quantum error corrections and quantum computing energetics), quantum computing hardware (all qubit types, including quantum annealing and quantum simulation paradigms, history, science, research, implementation and vendors), quantum enabling technologies (cryogenics, control electronics, photonics, components fabs, raw materials), quantum computing algorithms, software development tools and use cases, unconventional computing (potential alternatives to quantum and classical computing), quantum telecommunications and cryptography, quantum sensing, quantum technologies around the world, quantum technologies societal impact and even quantum fake sciences. The main audience are computer science engineers, developers and IT specialists as well as quantum scientists and students who want to acquire a global view of how quantum technologies work, and particularly quantum computing. This version is an extensive update to the 2021 edition published in October 2021.Comment: 1132 pages, 920 figures, Letter forma

Sewage sludge heavy metal analysis and agricultural prospects for Fiji

Insoluble residues produced in Waste Water Treatment Plants (WWTP) as by products are known as sewage sludge (SS). Land application of SS, particularly in agricultural lands, is becoming an alternative disposal method in Fiji. However, currently there is no legislative framework governing its use. SS together with its high nutrient and organic matter contents, constitutes some undesired pollutants such as heavy metals, which may limit its extensive use. The focus of this study therefore was to determine the total concentrations of Pb, Zn, Cd, Cu, Cr, Ni and Mn in the SS produced at the Kinoya WWTP (Fiji) and in the non-fertile soil amended with the SS at 20, 40, 60, 80% application rates and in the control (100% Soil). The bioavailable heavy metals were also determined as it depicts the true extent of metal contamination. The treatment mixtures were then used to cultivate cabbage plants in which the total heavy metal uptake was investigated. Total Zn (695.6 mg/kg) was present in the highest amounts in the 100% SS (control), followed by Pb (370.9 mg/kg), Mn (35.0 mg/kg), Cu (65.5 mg/kg), Cr (20.5 mg/kg) and finally Cd (13.5 mg/kg) and hence a similar trend was seen in all treatment mixtures. The potential mobility of sludgeborne heavy metals can be classified as Ni > Cu > Cd > Zn > Mn > Cr > Pb. Total metal uptake in plant leaves and stems showed only the bioavailable metals Cu, Cd, Zn and Mn, with maximum uptake occurring in the leaves. Ni, despite being highly mobile was not detected, due to minute concentrations in the SS treatments. Optimum growth occurred in the 20 and 40% SS treatments. However maximum Cu and Mn uptake occurred in the 40% SS treatment thereby making the 20% treatment the most feasible. Furthermore the total and bioavailable metal concentrations observed were within the safe and permitted limits of the EEC and USEPA legislations