Xin Liu scite author profile

Complicated vessels pervade almost all body tissues and influence the pathophysiology of the human body significantly. However, current fabrication strategies have limited success at multiscale vascular biofabrication. This study reports a methodology to fabricate soft vascularized tissue at centimeter scale using multimaterial bioprinting by a customized multistage-temperature-control printer. The printed constructs can be perfused via the branched endothelialized vasculatures to support the well-formed 3D capillary networks, which ensure cellular activities with sufficient nutrient supply and then mimic a mature and functional liver tissue in terms of synthesis of liver-specific proteins. Moreover, an inner and external pressure-bearing layer is printed to support the direct surgical anastomosis of the carotid artery to the jugular vein. In summary, a versatile platform to recapitulate the vasculature network is presented, in which case sustaining the optimal cellularization in engineered tissues is achievable.

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Whole dystrophin gene analysis by next-generation sequencing: a comprehensive genetic diagnosis of Duchenne and Becker muscular dystrophy

Wang¹,

Yang²,

Liu

et al. 2014

Mol Genet Genomics

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Duchenne/Becker muscular dystrophies are the most frequent inherited neuromuscular diseases caused by mutations of the dystrophin gene. However, approximately 30% of patients with the disease do not receive a molecular diagnosis because of the complex mutational spectrum and the large size of the gene. The introduction and use of next-generation sequencing have advanced clinical genetic research and might be a suitable method for the detection of various types of mutations in the dystrophin gene. To identify the mutational spectrum using a single platform, whole dystrophin gene sequencing was performed using next-generation sequencing. The entire dystrophin gene, including all exons, introns and promoter regions, was target enriched using a DMD whole gene enrichment kit. The enrichment libraries were sequenced on an Illumina HiSeq 2000 sequencer using paired read 100 bp sequencing. We studied 26 patients: 21 had known large deletion/duplications and 5 did not have detectable large deletion/duplications by multiplex ligation-dependent probe amplification technology (MLPA). We applied whole dystrophin gene analysis by next-generation sequencing to the five patients who did not have detectable large deletion/duplications and to five randomly chosen patients from the 21 who did have large deletion/duplications. The sequencing data covered almost 100% of the exonic region of the dystrophin gene by ≥10 reads with a mean read depth of 147. Five small mutations were identified in the first five patients, of which four variants were unreported in the dmd.nl database. The deleted or duplicated exons and the breakpoints in the five large deletion/duplication patients were precisely identified. Whole dystrophin gene sequencing by next-generation sequencing may be a useful tool for the genetic diagnosis of Duchenne and Becker muscular dystrophies.

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Dual-ended readout small animal PET detector by using 0.5 mm pixelated LYSO crystal arrays and SiPMs

Kuang

Wang

et al. 2019

Nuclear Instruments and Methods in Physics Research Section A:

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Characterization of the HMW glutenin subunits from Aegilops searsii and identification of a novel variant HMW glutenin subunit

Sun

Liu

et al. 2006

Theor Appl Genet

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High molecular weight (HMW) glutenin subunits are conserved seed storage proteins in wheat and related species. Here we describe a more detailed characterization of the HMW glutenin subunits from Aegilops searsii, which is diploid and contains the S(s) genome related to the S genome of Aegilops speltoides and the A, B and D genomes of hexaploid wheat. SDS-PAGE experiments revealed two subunits (one x and one y) for each of the nine Ae. searsii accessions analyzed, indicating that the HMW glutenin subunit gene locus of Ae. searsii is similar to the Glu-1 locus found in wheat in containing both x and y genes. The primary structure of the four molecularly cloned subunits (from two Ae. searsii accessions) was highly similar to that of the previously reported x and y subunits. However, in one accession (IG49077), the last 159 residues of the x subunit (1S(s)x49077), which contained the sequence element GHCPTSPQQ, were identical to those of the y subunit (1S(s)y49077) from the same accession. Consequently, 1S(s)x49077 contains an extra cysteine residue located at the C-terminal part of its repetitive domain, which is novel compared to the x-type subunits reported so far. Based on this and previous studies, the structure and expression of the Glu-1 locus in Ae. searsii is discussed. A hypothesis on the genetic mechanism generating the coding sequence for the novel 1S(s)x49077 subunit is presented.

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Xin Liu

3D Liver Tissue Model with Branched Vascular Networks by Multimaterial Bioprinting

Whole dystrophin gene analysis by next-generation sequencing: a comprehensive genetic diagnosis of Duchenne and Becker muscular dystrophy

Dual-ended readout small animal PET detector by using 0.5 mm pixelated LYSO crystal arrays and SiPMs

Characterization of the HMW glutenin subunits from Aegilops searsii and identification of a novel variant HMW glutenin subunit

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