Kai Quan scite author profile

PurposeTo develop a cerebrospinal fluid (CSF) miRNA diagnostic biomarker for glioblastoma.Experimental DesignGlioblastoma tissue and matched CSF from the same patient (obtained prior to tumor manipulation) were profiled by TaqMan OpenArray® Human MicroRNA Panel. CSF miRNA profiles from glioblastoma patients and controls were created from three discovery cohorts and confirmed in two validation cohorts.ResultsmiRNA profiles from clinical CSF correlated with those found in glioblastoma tissues. Comparison of CSF miRNA profiles between glioblastoma patients and non-brain tumor patients yielded a tumor “signature” consisting of nine miRNAs. The “signature” correlated with glioblastoma tumor volume (p=0.008). When prospectively applied to cisternal CSF, the sensitivity and specificity of the ‘signature’ for glioblastoma detection were 67% and 80%, respectively. For lumbar CSF, the sensitivity and specificity of the signature were 28% and 95%, respectively. Comparable results were obtained from analyses of CSF extracellular vesicles (EVs) and crude CSF.ConclusionWe report a CSF miRNA signature as a “liquid biopsy” diagnostic platform for glioblastoma.

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Rapid preparation of rare ginsenosides by acid transformation and their structure-activity relationships against cancer cells

Quan

Wan

et al. 2015

Sci Rep

100

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The anticancer activities of ginsenosides are widely reported. The structure-activity relationship of ginsenosides against cancer is not well elucidated because of the unavailability of these compounds. In this work, we developed a transformation method to rapidly produce rare dehydroxylated ginsenosides by acid treatment. The optimized temperature, time course, and concentration of formic acid were 120°C, 4 h and 0.01%, respectively. From 100 mg of Rh1, 8.3 mg of Rk3 and 18.7 mg of Rh4 can be produced by acid transformation. Similarly, from 100 mg of Rg3, 7.4 mg of Rk1 and 15.1 mg of Rg5 can be produced. From 100 mg of Rh2, 8.3 mg of Rk2 and 12.7 mg of Rh3 can be generated. Next, the structure-activity relationships of 23 ginsenosides were investigated by comparing their cytotoxic effects on six human cancer cells, including HCT-116, HepG2, MCF-7, Hela, PANC-1, and A549. The results showed that: (1) the cytotoxic effect of ginsenosides is inversely related to the sugar numbers; (2) sugar linkages rank as C-3 > C-6 > C-20; (3) the protopanaxadiol-type has higher activities; (4) having the double bond at the terminal C20-21 exhibits stronger activity than that at C20-22; and (5) 20(S)-ginsenosides show stronger effects than their 20(R)-stereoisomers.

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Validation of Wall Enhancement as a New Imaging Biomarker of Unruptured Cerebral Aneurysm

Quan

Song

Yang

et al. 2019

Stroke

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Background and Purpose— High-resolution vessel wall magnetic resonance imaging is a promising technique for assessing wall structures of unruptured intracranial aneurysms (UIAs). However, the relationship between aneurysmal high-resolution vessel wall magnetic resonance imaging features and their histopathologic mechanism remains poorly understood. Methods— From February 2016 to February 2018, a total of 19 men and 28 women with 54 UIAs treated surgically were prospectively enrolled. The intraoperative observed gross pathology of the aneurysmal wall was compared with the enhancement features on high-resolution vessel wall magnetic resonance imaging. Specimens of the UIAs were harvested for histopathologic and immunohistochemistry analysis. Results— An irregular shape and large size was significantly related to UIA wall enhancement. Both uniform and focal wall enhancement may demonstrate the inflammation processes of UIA walls, although the latter may indicate more atherosclerotic plaque formation. Conclusions— Different high-resolution vessel wall magnetic resonance imaging enhancement features may represent variable inflammation status of a UIA wall, which may provide new insights into assessing the UIA wall structure and optimizing treatment.

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Kai Quan

A cerebrospinal fluid microRNA signature as biomarker for glioblastoma

Rapid preparation of rare ginsenosides by acid transformation and their structure-activity relationships against cancer cells

Validation of Wall Enhancement as a New Imaging Biomarker of Unruptured Cerebral Aneurysm

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