ACADEMIC RESEARCH • 學術研究 53 2024 UMAGAZINE 30 • 澳大新語 Nuclear magnetic resonance (NMR) is a cornerstone technique in chemistry, physics, and biology, pivotal for non‑invasive study of the structure and dynamics of molecules within the human body. Among its primary applications is magnetic resonance imaging (MRI), an indispensable tool in modern medicine that allows doctors to easily observe pathological changes in patients. Our research team in the Institute of Microelectronics (IME) at the University of Macau (UM) has recently developed a compact MRI scanner based on complementary metal‑oxide‑semiconductor (CMOS) technology, aiming to advance personalised medicine. The Advent of Multi-Nuclei MRI Technology With the advent of multi-nuclei MRI technology, we can now perform medical imaging using various nuclei, such as hydrogen-1 (1H) and fluorine-19 (19F), to improve the effectiveness of diagnosis and treatment monitoring. Hydrogen-1, which is abundant in biological tissues, allows for clear anatomical MRI images. However, its ubiquity limits its effectiveness in tracking specific substances within the body. In contrast, fluorine-19 is extremely rare in biological tissues, making it an excellent marker for tracking targeted drugs and other specific substances with high precision, thereby allowing a more accurate assessment of disease progression and treatment efficacy. Innovations in the Miniaturisation of MRI Technology Traditional MRI machines, which use superconducting magnets and discrete electronic components, are bulky, expensive, and have limited applications. However, the advent of miniaturised NMR/MRI systems is changing the landscape. These new systems are powered by CMOS application-specific integrated circuits (ASICs) and more affordable permanent magnets. In the initial stages, our research team focused on miniaturising NMR spectroscopy and relaxometry, known as NMR-on-a-chip. In 2023, we developed the first three-dimensional MRI-on-a-chip platform, and introduced the miniaturised MRI scanner. Creating a Miniaturised Multi-Nuclei NMR/MRI Platform Over the past decade, the research team in the State Key Laboratory of Analog and Mixed-Signal VLSI at UM has been working on the miniaturisation of NMR/ MRI systems and has developed several generations of portable NMR/MRI platforms, each with unique and innovative features. Among these platforms, the latest generation is the first miniaturised multi-nuclei NMR/MRI platform with a customised silicon chip for ex vivo 19F MRI tracking. The scanner on this platform is equipped with a 0.52 Tesla permanent magnet and a highly integrated high-voltage insulated silicon ASIC. It is designed to be compact and lightweight, with optimised size, weight, imaging area, image resolution, and signal-to-noise ratio. At the core of this miniaturised NMR/MRI system is a customised CMOS ASIC chip. The compact core area is only 4.1mm², which enhances the portability and sensitivity of the miniaturised multi-nuclei NMR/MRI platform. Its components include: 1) an arbitrary pulse sequence synthesiser (equipped with 32kb of memory and a state coordinator to instruct the operation of each module); 2) a high-voltage transmitter (TX, which sends RF signals to the coil to excite the nuclei in the sample); 3) a low-noise receiver (RX, which captures and processes signals from the nuclei); 4) a pair of high-voltage-tolerant switches (which protect RX from TX); and 5) a three-dimensional gradient controller (comprising three sets of 12-bit digital-to-analogue converters used to programme the necessary gradients for spatial encoding of the nuclei). Pushing Technological Boundaries The miniaturised multi-nuclei NMR/MRI platform employs composite radio-frequency (RF) pulses. These pulses are a combination of RF signals with precisely adjusted phases and amplitudes, designed to minimise off-resonance effects, which is critical for multi-nuclei NMR/MRI. In addition, these pulses can mitigate the effects of inhomogeneous static and RF magnetic field strengths, such as image quality degradation. It is worth noting that such composite pulses require a phase resolution of less than 1°, which most compact NMR/ MRI systems are unable to achieve. To address this limitation, we have integrated a multi-phase generator based on a phase-interpolated dual-DLL architecture and improved the accuracy of the NMR spectrum amplitude by 28 per cent, significantly enhancing the quality and capabilities of our low-field NMR platform. This transformative technology not only revolutionises the generation of composite RF pulses but also improves the power transmission mechanism within the system. By leveraging a class-D power amplifier equipped with a sophisticated high-voltage NMOS array, the system can deliver the high-power capacity required for large FOV MRI applications (20.5W into a 100-Ω load). The
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