32 Works

High hydrostatic pressure (30 atm) enhances the apoptosis and inhibits the proteoglycan synthesis and extracellular matrix level of human nucleus pulposus cells via promoting the Wnt/β-catenin pathway

Zongting Shi, Jun He, Jian He & Yuan Xu
Hydrostatic pressure is known to regulate bovine nucleus pulposus cell metabolism, but its mechanism in human nucleus pulposus cells (HNPCs) remains obscure, which attracts our attention and becomes the focus in this study. Specifically, HNPCs were treated with SKL2001 (an agonist in the Wnt/β-catenin pathway) or XAV-939 (an inhibitor of the Wnt/β-catenin pathway), and pressurized under the hydrostatic pressure of 1, 3 and 30 atm. The viability, apoptosis and proteoglycan synthesis of treated HNPC were...

Additional file 4 of Genome-wide profiling of retroviral DNA integration and its effect on clinical pre-infusion CAR T-cell products

Lipei Shao, Rongye Shi, Yingdong Zhao, Hui Liu, Alexander Lu, Jinxia Ma, Yihua Cai, Tatyana Fuksenko, Alejandra Pelayo, Nirali N. Shah, James N. Kochenderfer, Scott M. Norberg, Christian Hinrichs, Steven L. Highfill, Robert P Somerville, Sandhya R. Panch, Ping Jin & David F. Stroncek
Additional file 4: Figure S4. Percentage of integration events at each genomic features based on gender and transduction efficiency. Related to Figure 6.

Additional file 7 of Evolution and functional analysis of the GRAS family genes in six Rosaceae species

Yibo Bai, Hui Liu, Kaikai Zhu & Zong-Ming Cheng
Additional file 7: Fig. S7. Mapchart shown the distribution of GRAS genes on 7 chromosomes in Chinese rosa.

Systemic immune–inflammation index predicts prognosis of cancer immunotherapy: systemic review and meta-analysis. Supplementary materials.

Tao Li, Xin-Cheng Mao, Cheng-Long Han, Dong-Xu Wang, Jian-Guo Hong, Zhi-Qiang Chen, Zhao-Ru Dong, Jun-Shuai Xue, Hui Liu, Zi-Niu Ding, Lun-Jie Yan, Chun-Cheng Yang, Ya-Fei Yang & Bao-Wen Tian
Supplementary retrieval methods Supplementary tables 1-2 Supplementary figures 1-10 PRISMA

Systemic immune–inflammation index predicts prognosis of cancer immunotherapy: systemic review and meta-analysis. Supplementary materials.

Tao Li, Xin-Cheng Mao, Cheng-Long Han, Dong-Xu Wang, Jian-Guo Hong, Zhi-Qiang Chen, Zhao-Ru Dong, Jun-Shuai Xue, Hui Liu, Zi-Niu Ding, Lun-Jie Yan, Chun-Cheng Yang, Ya-Fei Yang & Bao-Wen Tian
Supplementary retrieval methods Supplementary tables 1-2 Supplementary figures 1-10 PRISMA

Additional file 1 of Genome-wide profiling of retroviral DNA integration and its effect on clinical pre-infusion CAR T-cell products

Lipei Shao, Rongye Shi, Yingdong Zhao, Hui Liu, Alexander Lu, Jinxia Ma, Yihua Cai, Tatyana Fuksenko, Alejandra Pelayo, Nirali N. Shah, James N. Kochenderfer, Scott M. Norberg, Christian Hinrichs, Steven L. Highfill, Robert P Somerville, Sandhya R. Panch, Ping Jin & David F. Stroncek
Additional file 1: Figure S1. Bioinformatic workflow and positive control for VISA pipeline. Related to Figure 1.

Additional file 1 of Genome-wide profiling of retroviral DNA integration and its effect on clinical pre-infusion CAR T-cell products

Lipei Shao, Rongye Shi, Yingdong Zhao, Hui Liu, Alexander Lu, Jinxia Ma, Yihua Cai, Tatyana Fuksenko, Alejandra Pelayo, Nirali N. Shah, James N. Kochenderfer, Scott M. Norberg, Christian Hinrichs, Steven L. Highfill, Robert P Somerville, Sandhya R. Panch, Ping Jin & David F. Stroncek
Additional file 1: Figure S1. Bioinformatic workflow and positive control for VISA pipeline. Related to Figure 1.

Additional file 2 of Genome-wide profiling of retroviral DNA integration and its effect on clinical pre-infusion CAR T-cell products

Lipei Shao, Rongye Shi, Yingdong Zhao, Hui Liu, Alexander Lu, Jinxia Ma, Yihua Cai, Tatyana Fuksenko, Alejandra Pelayo, Nirali N. Shah, James N. Kochenderfer, Scott M. Norberg, Christian Hinrichs, Steven L. Highfill, Robert P Somerville, Sandhya R. Panch, Ping Jin & David F. Stroncek
Additional file 2: Figure S2. Viral integration sites on chromosomes in products with different CAR type and each individual. Related to Figure 2.

Additional file 6 of Evolution and functional analysis of the GRAS family genes in six Rosaceae species

Yibo Bai, Hui Liu, Kaikai Zhu & Zong-Ming Cheng
Additional file 6: Fig. S6. Mapchart shown the distribution of GRAS genes on 17 chromosomes in European pear.

Additional file 6 of Evolution and functional analysis of the GRAS family genes in six Rosaceae species

Yibo Bai, Hui Liu, Kaikai Zhu & Zong-Ming Cheng
Additional file 6: Fig. S6. Mapchart shown the distribution of GRAS genes on 17 chromosomes in European pear.

Additional file 7 of Evolution and functional analysis of the GRAS family genes in six Rosaceae species

Yibo Bai, Hui Liu, Kaikai Zhu & Zong-Ming Cheng
Additional file 7: Fig. S7. Mapchart shown the distribution of GRAS genes on 7 chromosomes in Chinese rosa.

Additional file 4 of Evolution and functional analysis of the GRAS family genes in six Rosaceae species

Yibo Bai, Hui Liu, Kaikai Zhu & Zong-Ming Cheng
Additional file 4: Fig. S4. Mapchart shown the distribution of GRAS genes on 17 chromosomes in apple.

Additional file 5 of Evolution and functional analysis of the GRAS family genes in six Rosaceae species

Yibo Bai, Hui Liu, Kaikai Zhu & Zong-Ming Cheng
Additional file 5: Fig. S5. Mapchart shown the distribution of GRAS genes on 8 chromosomes in peach.

Additional file 5 of CT radiomics-based long-term survival prediction for locally advanced non-small cell lung cancer patients treated with concurrent chemoradiotherapy using features from tumor and tumor organismal environment

Nai-Bin Chen, Mai Xiong, Rui Zhou, Yin Zhou, Bo Qiu, Yi-Feng Luo, Su Zhou, Chu Chu, Qi-Wen Li, Bin Wang, Hai-Hang Jiang, Jin-Yu Guo, Kang-Qiang Peng, Chuan-Miao Xie & Hui Liu
Additional File 5.

Additional file 3 of Genome-wide profiling of retroviral DNA integration and its effect on clinical pre-infusion CAR T-cell products

Lipei Shao, Rongye Shi, Yingdong Zhao, Hui Liu, Alexander Lu, Jinxia Ma, Yihua Cai, Tatyana Fuksenko, Alejandra Pelayo, Nirali N. Shah, James N. Kochenderfer, Scott M. Norberg, Christian Hinrichs, Steven L. Highfill, Robert P Somerville, Sandhya R. Panch, Ping Jin & David F. Stroncek
Additional file 3: Figure S3. Annotation of shared differentially expressed genes between lentiviral and γ-retroviral CAR T-cell products. Related to Figure 4.

Additional file 2 of Chemotherapy induces ACE2 expression in breast cancer via the ROS-AKT-HIF-1α signaling pathway: a potential prognostic marker for breast cancer patients receiving chemotherapy

Xiaoyan Zuo, Sixin Ren, He Zhang, Jianfei Tian, Ruinan Tian, Baoai Han, Hui Liu, Qian Dong, Zhiyong Wang, Yanfen Cui, Ruifang Niu & Fei Zhang
Additional file 2: Figure S1. (A) qRT-PCR analysis showed no significant changes in ACE2 expression in colorectal and pancreatic cancer cells after exposure to EPI, PTX or 5-FU. All data are shown as mean ± SD; *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001, and ns P > 0.05 versus control, N = 3.

Additional file 5 of CT radiomics-based long-term survival prediction for locally advanced non-small cell lung cancer patients treated with concurrent chemoradiotherapy using features from tumor and tumor organismal environment

Nai-Bin Chen, Mai Xiong, Rui Zhou, Yin Zhou, Bo Qiu, Yi-Feng Luo, Su Zhou, Chu Chu, Qi-Wen Li, Bin Wang, Hai-Hang Jiang, Jin-Yu Guo, Kang-Qiang Peng, Chuan-Miao Xie & Hui Liu
Additional File 5.

Additional file 5 of Evolution and functional analysis of the GRAS family genes in six Rosaceae species

Yibo Bai, Hui Liu, Kaikai Zhu & Zong-Ming Cheng
Additional file 5: Fig. S5. Mapchart shown the distribution of GRAS genes on 8 chromosomes in peach.

Additional file 8 of Evolution and functional analysis of the GRAS family genes in six Rosaceae species

Yibo Bai, Hui Liu, Kaikai Zhu & Zong-Ming Cheng
Additional file 8: Fig. S8. Mapchart shown the distribution of GRAS genes on 7 chromosomes in black raspberry.

Additional file 6 of CT radiomics-based long-term survival prediction for locally advanced non-small cell lung cancer patients treated with concurrent chemoradiotherapy using features from tumor and tumor organismal environment

Nai-Bin Chen, Mai Xiong, Rui Zhou, Yin Zhou, Bo Qiu, Yi-Feng Luo, Su Zhou, Chu Chu, Qi-Wen Li, Bin Wang, Hai-Hang Jiang, Jin-Yu Guo, Kang-Qiang Peng, Chuan-Miao Xie & Hui Liu
Additional File 6.

Additional file 2 of Genome-wide profiling of retroviral DNA integration and its effect on clinical pre-infusion CAR T-cell products

Lipei Shao, Rongye Shi, Yingdong Zhao, Hui Liu, Alexander Lu, Jinxia Ma, Yihua Cai, Tatyana Fuksenko, Alejandra Pelayo, Nirali N. Shah, James N. Kochenderfer, Scott M. Norberg, Christian Hinrichs, Steven L. Highfill, Robert P Somerville, Sandhya R. Panch, Ping Jin & David F. Stroncek
Additional file 2: Figure S2. Viral integration sites on chromosomes in products with different CAR type and each individual. Related to Figure 2.

Additional file 3 of Genome-wide profiling of retroviral DNA integration and its effect on clinical pre-infusion CAR T-cell products

Lipei Shao, Rongye Shi, Yingdong Zhao, Hui Liu, Alexander Lu, Jinxia Ma, Yihua Cai, Tatyana Fuksenko, Alejandra Pelayo, Nirali N. Shah, James N. Kochenderfer, Scott M. Norberg, Christian Hinrichs, Steven L. Highfill, Robert P Somerville, Sandhya R. Panch, Ping Jin & David F. Stroncek
Additional file 3: Figure S3. Annotation of shared differentially expressed genes between lentiviral and γ-retroviral CAR T-cell products. Related to Figure 4.

Additional file 5 of Genome-wide profiling of retroviral DNA integration and its effect on clinical pre-infusion CAR T-cell products

Lipei Shao, Rongye Shi, Yingdong Zhao, Hui Liu, Alexander Lu, Jinxia Ma, Yihua Cai, Tatyana Fuksenko, Alejandra Pelayo, Nirali N. Shah, James N. Kochenderfer, Scott M. Norberg, Christian Hinrichs, Steven L. Highfill, Robert P Somerville, Sandhya R. Panch, Ping Jin & David F. Stroncek
Additional file 5: Figure S5. Percentage of integration sites at genomic features in each group with different clinical outcomes. Related to Figure 7.

Additional file 6 of CT radiomics-based long-term survival prediction for locally advanced non-small cell lung cancer patients treated with concurrent chemoradiotherapy using features from tumor and tumor organismal environment

Nai-Bin Chen, Mai Xiong, Rui Zhou, Yin Zhou, Bo Qiu, Yi-Feng Luo, Su Zhou, Chu Chu, Qi-Wen Li, Bin Wang, Hai-Hang Jiang, Jin-Yu Guo, Kang-Qiang Peng, Chuan-Miao Xie & Hui Liu
Additional File 6.

Additional file 3 of Evolution and functional analysis of the GRAS family genes in six Rosaceae species

Yibo Bai, Hui Liu, Kaikai Zhu & Zong-Ming Cheng
Additional file 3: Fig. S3. Mapchart shown the distribution of GRAS genes on 7 chromosomes in woodland strawberry.

Registration Year

  • 2022
    32

Resource Types

  • Image
    32

Affiliations

  • Zhejiang University
    32
  • Dali University
    32
  • Tianjin Medical University General Hospital
    30
  • Huazhong University of Science and Technology
    30
  • Henan Normal University
    30
  • Heilongjiang Provincial Academy of Agricultural Sciences
    30
  • Tianjin Medical University Cancer Institute and Hospital
    30
  • Nanfang Hospital
    30
  • Lanzhou University
    30
  • China University of Mining and Technology
    30