Min-Chiao Liao scite author profile

Abnormal cerebral oxygenation and vessel structure is a crucial feature of stroke. An imaging method with structural and functional information is necessary for diagnosis of stroke. This study applies QSM-mMRV (quantitative susceptibility mapping-based microscopic magnetic resonance venography) for noninvasively detecting small cerebral venous vessels in rat stroke model. First, susceptibility mapping is optimized and calculated from magnetic resonance (MR) phase images of a rat brain. Subsequently, QSM-mMRV is used to simultaneously provide information on microvascular architecture and venous oxygen saturation (SvO2), both of which can be used to evaluate the physiological and functional characteristics of microvascular changes for longitudinally monitoring and therapeutically evaluating a disease model. Morphologically, the quantification of vessel sizes using QSM-mMRV was 30% smaller than that of susceptibility-weighted imaging (SWI), which eliminated the overestimation of conventional SWI. Functionally, QSM-mMRV estimated an average SvO2 ranging from 73% to 85% for healthy rats. Finally, we also applied QSM to monitor the revascularization of post-stroke vessels from 3 to 10 days after reperfusion. QSM estimations of SvO2 were comparable to those calculated using the pulse oximeter standard metric. We conclude that QSM-mMRV is useful for longitudinally monitoring blood oxygen and might become clinically useful for assessing cerebrovascular diseases.

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Magnetic, biocompatible FeCO3 nanoparticles for T2-weighted magnetic resonance imaging of in vivo lung tumors

Thangudu

Lee

et al. 2022

J Nanobiotechnol

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Background Late diagnosis of lung cancer is one of the leading causes of higher mortality in lung cancer patients worldwide. Significant research attention has focused on the use of magnetic resonance imaging (MRI) based nano contrast agents to efficiently locate cancer tumors for surgical removal or disease diagnostics. Although contrast agents offer significant advantages, further clinical applications require improvements in biocompatibility, biosafety and efficacy. Results To address these challenges, we fabricated ultra-fine Iron Carbonate Nanoparticles (FeCO3 NPs) for the first time via modified literature method. Synthesized NPs exhibit ultra-fine size (~ 17 nm), good dispersibility and excellent stability in both aqueous and biological media. We evaluated the MR contrast abilities of FeCO3 NPs and observed remarkable T2 weighted MRI contrast in a concentration dependent manner, with a transverse relaxivity (r2) value of 730.9 ± 4.8 mM−1 S−1at 9.4 T. Moreover, the r2 values of present FeCO3 NPs are respectively 1.95 and 2.3 times higher than the clinically approved contrast agents Resovist® and Friedx at same 9.4 T MR scanner. FeCO3 NPs demonstrate an enhanced T2 weighted contrast for in vivo lung tumors within 5 h of post intravenous administration with no apparent systemic toxicity or induction of inflammation observed in in vivo mice models. Conclusion The excellent biocompatibility and T2 weighted contrast abilities of FeCO3 NPs suggest potential for future clinical use in early diagnosis of lung tumors. Graphical Abstract

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Chemical Structure and Shape Enhance MR Imaging-Guided X-ray Therapy Following Marginative Delivery

Wang

Chang

et al. 2022

ACS Appl. Mater. Interfaces

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Ineffective site-specific delivery has seriously impeded the efficacy of nanoparticle-based drugs to a disease site. Here, we report the preparation of three different shapes (sphere, scroll, and oblate) to systematically evaluate the impact of the marginative delivery on the efficacy of magnetic resonance (MR) imaging-guided X-ray irradiation at a low dose of 1 Gy. In addition to the shape effect, the therapeutic efficacy is investigated for the first time to be strongly related to the structure effect that is associated with the chemical activity. The enhanced particle–vessel wall interaction of both the flat scroll and oblate following margination dynamics leads to greater accumulation in the lungs, resulting in superior performance over the sphere against lung tumor growth and suppression of lung metastasis. Furthermore, the impact of the structural discrepancy in nanoparticles on therapeutic efficacy is considered. The tetragonal oblate reveals that the feasibility of the charge-transfer process outperforms the orthorhombic scroll and cubic sphere to suppress tumors. Finally, surface area is also a crucial factor affecting the efficacy of X-ray treatments from the as-prepared particles.

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Single Nucleotide Polymorphism of TCF7L2 and Adiponectin Genes for Type 2 Diabetes Mellitus in Taiwan

Tsao

Huang

Chang

et al. 2009

Fooyin Journal of Health Sciences

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Ligand free FeSn₂ alloy nanoparticles for safe T₂-weighted MR imaging of in vivo lung tumors

et al. 2023

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Min-Chiao Liao

Quantitative Susceptibility Mapping-Based Microscopy of Magnetic Resonance Venography (QSM-mMRV) for In Vivo Morphologically and Functionally Assessing Cerebromicrovasculature in Rat Stroke Model

Magnetic, biocompatible FeCO3 nanoparticles for T2-weighted magnetic resonance imaging of in vivo lung tumors

Chemical Structure and Shape Enhance MR Imaging-Guided X-ray Therapy Following Marginative Delivery

Single Nucleotide Polymorphism of TCF7L2 and Adiponectin Genes for Type 2 Diabetes Mellitus in Taiwan

Ligand free FeSn₂ alloy nanoparticles for safe T₂-weighted MR imaging of in vivo lung tumors

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Min-Chiao Liao

Quantitative Susceptibility Mapping-Based Microscopy of Magnetic Resonance Venography (QSM-mMRV) for In Vivo Morphologically and Functionally Assessing Cerebromicrovasculature in Rat Stroke Model

Magnetic, biocompatible FeCO3 nanoparticles for T2-weighted magnetic resonance imaging of in vivo lung tumors

Chemical Structure and Shape Enhance MR Imaging-Guided X-ray Therapy Following Marginative Delivery

Single Nucleotide Polymorphism of TCF7L2 and Adiponectin Genes for Type 2 Diabetes Mellitus in Taiwan

Ligand free FeSn2 alloy nanoparticles for safe T2-weighted MR imaging of in vivo lung tumors

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Ligand free FeSn₂ alloy nanoparticles for safe T₂-weighted MR imaging of in vivo lung tumors