464 results on '"Lygate, Craig A."'
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2. pH-sensitive release of nitric oxide gas using peptide-graphene co-assembled hybrid nanosheets
3. S-nitrosocysteamine-functionalised porous graphene oxide nanosheets as nitric oxide delivery vehicles for cardiovascular applications
4. Nitric Oxide Releasing Nanomaterials for Cardiovascular Applications
5. Synergistic effect on cardiac energetics by targeting the creatine kinase system: in vivo application of high-resolution 31P-CMRS in the mouse
6. Insights Into the Metabolic Aspects of Aortic Stenosis With the Use of Magnetic Resonance Imaging
7. Synthesis and characterization of amine-functionalized graphene as a nitric oxide-generating coating for vascular stents.
8. Hyperpolarized 13C and 31P MRS detects differences in cardiac energetics, metabolism, and function in obesity, and responses following treatment.
9. Mitochondria-targeted nanomedicines for cardiovascular applications
10. Maintaining energy provision in the heart: the creatine kinase system in ischaemia-reperfusion injury and chronic heart failure.
11. Nitric Oxide Releasing Nanomaterials for Cardiovascular Applications
12. Measuring cardiomyocyte cellular characteristics in cardiac hypertrophy using diffusion‐weighted MRI
13. Aberrant developmental titin splicing and dysregulated sarcomere length in Thymosin β4 knockout mice
14. Overexpression of mitochondrial creatine kinase preserves cardiac energetics without ameliorating murine chronic heart failure
15. Graphene nanocomposites for real-time electrochemical sensing of nitric oxide in biological systems.
16. Cardiac Energetics in Patients With Aortic Stenosis and Preserved Versus Reduced Ejection Fraction
17. Comparative studies in experimental hypertension and cardiac failure
18. Supplementary Figure 6 from Adaptation to HIF1α Deletion in Hypoxic Cancer Cells by Upregulation of GLUT14 and Creatine Metabolism
19. Supplementary Figure 5 from Adaptation to HIF1α Deletion in Hypoxic Cancer Cells by Upregulation of GLUT14 and Creatine Metabolism
20. Supplementary Figure 8 from Adaptation to HIF1α Deletion in Hypoxic Cancer Cells by Upregulation of GLUT14 and Creatine Metabolism
21. Supplementary Figure 7 from Adaptation to HIF1α Deletion in Hypoxic Cancer Cells by Upregulation of GLUT14 and Creatine Metabolism
22. Supplementary Figure 3 from Adaptation to HIF1α Deletion in Hypoxic Cancer Cells by Upregulation of GLUT14 and Creatine Metabolism
23. Supplementary Figure 2 from Adaptation to HIF1α Deletion in Hypoxic Cancer Cells by Upregulation of GLUT14 and Creatine Metabolism
24. Data from Adaptation to HIF1α Deletion in Hypoxic Cancer Cells by Upregulation of GLUT14 and Creatine Metabolism
25. Supplemetary Data from Adaptation to HIF1α Deletion in Hypoxic Cancer Cells by Upregulation of GLUT14 and Creatine Metabolism
26. Supplementary Figure 4 from Adaptation to HIF1α Deletion in Hypoxic Cancer Cells by Upregulation of GLUT14 and Creatine Metabolism
27. Authorship Change Form from Adaptation to HIF1α Deletion in Hypoxic Cancer Cells by Upregulation of GLUT14 and Creatine Metabolism
28. Supplementary Figure 1 from Adaptation to HIF1α Deletion in Hypoxic Cancer Cells by Upregulation of GLUT14 and Creatine Metabolism
29. The Myocardial Creatine Kinase System in the Normal, Ischaemic and Failing Heart
30. Mechanistic role of mitochondrial creatine kinase in the stabilization of mitochondrial ROS and Ca2+. Implications for human cardiomyopathies
31. The Amino Acid Homoarginine Inhibits Atherogenesis by Modulating T-Cell Function
32. Homoarginine and creatine deficiency do not exacerbate murine ischaemic heart failure
33. Influence of homoarginine on creatine accumulation and biosynthesis in the mouse
34. Cardiac dysfunction and peri-weaning mortality in malonyl-coenzyme A decarboxylase (MCD) knockout mice as a consequence of restricting substrate plasticity
35. Endothelial Cell Tetrahydrobiopterin Modulates Sensitivity to Ang (Angiotensin) II–Induced Vascular Remodeling, Blood Pressure, and Abdominal Aortic Aneurysm
36. Impaired cardiac contractile function in arginine: glycine amidinotransferase knockout mice devoid of creatine is rescued by homoarginine but not creatine
37. Proteomic and metabolomic changes driven by elevating myocardial creatine suggest novel metabolic feedback mechanisms
38. Metabolic arithmetic: do two wrongs make a right?
39. The subcellular localization of neuronal nitric oxide synthase determines the downstream effects of NO on myocardial function
40. Dietary Supplementation with Homoarginine Preserves Cardiac Function in a Murine Model of Post-Myocardial Infarction Heart Failure
41. Synergistic effect on cardiac energetics by targeting the creatine kinase system: in vivo application of high-resolution 31P-CMRS in the mouse.
42. Homoarginine and creatine deficiency do not exacerbate murine ischaemic heart failure.
43. Fumarate Is Cardioprotective via Activation of the Nrf2 Antioxidant Pathway
44. Energetics in the Hypertrophied and Failing Heart
45. List of Contributors
46. Acute myocardial infarction activates distinct inflammation and proliferation pathways in circulating monocytes, prior to recruitment, and identified through conserved transcriptional responses in mice and humans
47. Refinement of analgesia following thoracotomy and experimental myocardial infarction using the Mouse Grimace Scale
48. 1H-MR spectroscopy for analysis of cardiac lipid and creatine metabolism
49. Myocardial infarction causes inflammation and leukocyte recruitment at remote sites in the myocardium and in the renal glomerulus
50. The Pitfalls of in vivo Cardiac Physiology in Genetically Modified Mice – Lessons Learnt the Hard Way in the Creatine Kinase System
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