Results 301 to 310 of about 10,758,011 (382)

Mitochondrial Transplantation Augments the Reparative Capacity of Macrophages Following Myocardial Injury

Advanced Science, EarlyView.
Mitochondrial transplantation induces macrophage polarization toward an anti‐inflammatory M2 phenotype, enhances their reparative capacities, and facilitates mitochondrial transfer to cardiomyocytes, collectively promoting tissue repair and functional recovery post‐myocardial infarction.
Yuning Zhang, Xiaolei Sun, Yawei Jin, Kanghui Chen, Lu Zhang, Xiong Gao, Mohan Li, Ze Yuan, Jianguo Jia, Aijun Sun, Junbo Ge   +10 more
wiley   +1 more source

Walking on Collaterals: Unveiling Discrepancies in Gender-Based Variances in Peripheral Arterial Disease. [PDF]

Cureus
Rodriguez-Santiago MA, Garcia-Berrios A, Martinez-Toro J, Mesa-Pabón M.   +3 more
europepmc   +1 more source

PPP1R3B Suppresses Atherosclerosis by Promoting the M2 Polarization of Macrophages Through Glycogen Metabolic Reprogramming

Advanced Science, EarlyView.
PPP1R3B induces anti‐inflammatory M2 macrophage polarization and maintains energy supply in plaques. Its absence accelerates plaque progression. PPP1R3B regulates M2 macrophage polarization and energy metabolism via phosphorylated STAT3 (p‐STAT3), which plays a dual role by activating anti‐inflammatory transcriptional programs through the PPAR‐γ/PGC‐1α/
Lin Shen, Junchao Yu, Weiqian Chen, Yanran Bi, Zhangyu Yang, Chenying Lu, Chengli Jiang, Yang Yang, Minjiang Chen, Jianhua Zou, Lingchun Lv, Xiaoyuan Chen, Jiansong Ji   +12 more
wiley   +1 more source

Poly(ADP-ribose) polymerase 1 orchestrates vascular smooth muscle cell homeostasis in arterial disease. [PDF]

Exp Mol Med
Xu W, Wu Y, Mao R, Jia Y, Jiang H, Zhang F, Huang D, He X, Wang C, Huang K.   +9 more
europepmc   +1 more source

Spontaneous Arterial Disease in Animals

, 1983
Robert Finlayson
openalex   +1 more source

FMO2 Promotes Angiogenesis via Regulation of N‐Acetylornithine

Advanced Science, EarlyView.
This study identifies flavin‐containing monooxygenase 2 (FMO2) as a novel proangiogenic regulator in endothelial cells. Targeted FMO2 ablation impairs vessel sprouting, whereas its compensation potently enhances angiogenesis. Metabolomics and single‐cell sequencing reveal that FMO2 drives vascular growth via the N‐acetylornithine/ATF3/NOTCH1 axis ...
Jingyi Wang, Yinghui Xu, Xianpeng Wu, Mo Li, Changchen Xiao, Zaiyang Fu, Yongjian Chen, Qingju Li, Yating Ruan, Jing Zhao, Zhiwei Zhong, Jinghai Chen, Wei Zhu, Jinliang Nan, Cheng Ni, Xinyang Hu   +15 more
wiley   +1 more source

Exploring Plasma Proteome Thermal Stability in Peripheral Arterial Disease: Biophysical Findings Under Cilostazol Therapy. [PDF]

Pharmaceuticals (Basel)
Szabó D, Benkő L, Lőrinczy D.
europepmc   +1 more source

Cell Fate Determination and Lineage Tracing: Technological Evolution and Multidimensional Applications

Advanced Science, EarlyView.
This figure is a candidate for the cover image. It shows a whole‐mount fluorescent image of lymphatic vessels (red) in the heart of an adult Cdh5‐Dre; Prox1‐RSR‐CreER; Rosa26‐tdT mouse. Image courtesy of Ximeng Han. Abstract Cell fate determination is a fundamental process in multicellular development.
Hui Chen, Zhicong Liu, Qiang Shu, Bin Zhou   +3 more
wiley   +1 more source

Perirenal adipose tissue accumulation mediates the adverse impact of the atherogenic index of plasma on lower extremity peripheral arterial disease. [PDF]

Sci Rep
Guo XL, Tu M, Qiu XP, Wang W.
europepmc   +1 more source

Redox Cascade in Chicken Skeletal Muscle: SELENOT Suppression in Selenium Deficiency Triggers Disulfidptosis via mtROS‐NADPH Dysregulation

Advanced Science, EarlyView.
Se deficiency downregulates SELENOT, disrupting mitochondrial function and elevating mtROS to induce glucose metabolic reprogramming, NADPH depletion, cysteine accumulation, and disulfidptosis‐mediated actin cytoskeleton collapse in chicken skeletal muscle.
Huanyi Liu, Hao Wu, Ziyu Zhang, Shiwen Xu, Cong Zhou, Tong Xu   +5 more
wiley   +1 more source