Tumor cells have unique energy metabolism phenomena, namely high glucose absorption, aerobic glycolysis and high lactic acid production, which are characterized by down-regulation of related proteins involved in oxidative metabolism in tumor cells, and up-regulation of glucose transporters and monocarboxylate transporters. Studies have shown that drugs that target tumor cell glucose metabolism have the ability to selectively kill tumor cells, bringing new hope for tumor treatment. Tumor stem cells are considered to be the root cause of tumor recurrence, metastasis and poor prognosis, and their energy metabolism characteristics have not yet been agreed. Studies have shown that reversing the energy metabolism of tumor stem cells can increase their chemosensitivity. This article reviews recent studies on tumor and tumor stem cell glucose metabolism and the opportunities and challenges of tumor treatment through targeting glucose metabolism, which might provide new ideas and opportunities for clinical tumor therapy.
Abstract: Objective To study the pathophysiological mechanism of the morphological change of immature pulmonary vessels in the piglet model of congenital heart defect with decreased pulmonary blood flow established with balloon atrial septostomy and pulmonary artery banding. Methods Twenty piglets at an age of one to two months were divided into three groups with random number table. For the control group (group C,n=6), small incisions were carried out on the right chest to produce a transient reduction in the pulmonary blood; for the lowmedium pulmonary artery stenosis group (group T1, n=7), the balloon dilator was delivered through the surface of the right atrium and septostomy and pulmonary artery banding were performed, and the systolic transpulmonary artery banding pressure (Trans-PABP) was controlled to be 20.30 mm Hg; For the severe pulmonary artery stenosis group (group T2, n=7), the same surgical procedures with group T1 were performed while TransPABP was controlled to be more [CM(159mm]than 3050 mm Hg.At 2 months after surgery respectively,a lung tissue of 1.0 cm×0.8 cm×0.8 cm from the lateral segment of the right middle lobe was taken out to be observed under optic microscope. The morphological change of the distal arterioles was detected. Furthermore, the content of vascular endothelial growth factor (VEGF) and matrix metalloproteinase2( MMP2) were also examined by the method of enzymelinked immunosorbent assay (ELISA). Results The model was successfully established in all the survival piglets of the group T1 and group T2. Two months after operation, the inner diameter of the pulmonary arterioles in group T1 was significantly higher than that in group C (82.89±10.72 μm vs.74.12±9.28 μm;t=-5.892, Plt;0.05), so as group T2 (85.47±5.25 μm vs.74.12±9.28 μm;t=-6.325, Plt;0.05); the number of arterioles per square centimeter (NAPSC) of group T1 was significantly lower than that of the group C (229.70±88.00 entries/cm 2 vs. 431.50±40.60 entries/cm2; t=39.526, Plt;0.05), so as group T2 (210.00±40.30 entries/cm2 vs. 431.50±40.60 entries/cm2; t=67.858, Plt;0.05). Two months after operation, the lung expression of MMP -2 and VEGF in group T1 was significantly lower than that in group C (58.30±19.60 ng/ml vs. 81.20±16.70 ng/ml, t=14.261, Plt;0.05; 17.80±3.00 pg/ml vs. 21.40±3.80 pg/ml, t=8.482, P<0.05), so does group T2 (42.10±15.20 ng/ml vs. 81.20±16.70 ng/ml, t=27.318, P<0.05; 12.30±3.20 pg/ml vs. 21.40±3.80 pg/ml, t=15.139, P<0.05). Conclusion Structural remodeling of pulmonary extracellular matrix is an important feature of the piglet model of congenital heart defect with decreased pulmonary blood flow. The arterioles show significant hypoplasia or degradation. Change in the structural proteins and cytokines during the reduction of blood in the lung is the key to structural remodeling.
ObjectiveBy comparing the mechanics of human auricular cartilage, polyurethane elastic material, and high density polyethylene material (Medpor), to produce theoretical proof on choosing optimal artificial auricular scaffold materials.MethodsThe experimental materials were divided into 3 groups with 6 samples in each: the auricular cartilage group (group A), the polyurethane elastic material group (group B), and the Medpor group (group C). With an Instron5967 mechanical testing machine, compression and tensile testing were performed to respectively measure values of compression parameters (including yield stress, yield load, elastic modulus, yield compressibility, compressibility within 2 MPa, and compression stress within 10% strain) and values of tensile parameters (including yield stress, yield load, elastic modulus, yield elongation, elongation within 2 MPa, tensile stress within 1% strain) for comparison.ResultsCompression testing: no obvious yield points were observed in the whole process in samples of group B, while obvious yield points were observed in samples of groups A and C. There was no significant difference between groups A and C with respect to yield stress and yield load (P>0.05); while the yield compressibility in group C was significantly lower than that in group A (P<0.05) and the elastic modulus in group C was significantly higher than that in group A (P<0.05). There was a significant difference with respect to compressibility within 2 MPa of materials among the 3 groups (P<0.05), the high, medium, and low values go to groups B, A, and C respectively. The compression stress within 10% strain in group C was significantly higher than that in groups A and B (P<0.05), and there was no significant difference between that in groups A and B (P>0.05). Tensile testing: the materials in group B had extremely high tensile strength. The yield stress in groups A and B was significantly higher than that in group C (P<0.05), and the elastic modulus and tensile stress within 1% strain were significantly lower than those in group C (P<0.05); but no significant difference was found between those in groups A and B (P>0.05). There was no significant difference with respect to yield load among the 3 groups (P>0.05); but there was significant difference with respect to yield elongation among the 3 groups (P<0.05), and the high, medium, and low values go to groups B, A, and C respectively. The elongation within 2 MPa in group B was significantly higher than that in groups A and C (P<0.05), and there was no significant difference between that in groups A and C (P>0.05).ConclusionCompared with the Medpor, the polyurethane elastic material is a more ideal artificial auricular scaffold material.