The Bittersweet Reality: The Cardiovascular Risk of Artificial Sweeteners.

Artificial sweeteners are increasingly popular as alternatives to sugar. Approximately 41% of the American adult population reports regular consumption of low-calorie sweeteners. People are not even aware they are ingesting artificial sweeteners as they are now in chewing gum, toothpaste, various food products, baked goods, and even pharmaceutical products. Some of these sweeteners are sweeter than sugar, some less sweet than sugar, and some are natural sweeteners. With the goal of increasing palatability, many products have multiple additives to create the perfect taste. Despite their widespread use and perceived benefits, there is increasing concern in the academic community about the long-term safety of these artificial sweeteners and their role in increasing the burden of cardiovascular diseases, including coronary heart disease, stroke, and heart failure. There is general agreement about the cardiovascular risk of added sugars to a diet. Public health authorities have recommended limiting added sugar consumption. Replacing sugar with these artificial sweeteners has become increasingly popular, but safety remains a question. While multiple well-designed randomized clinical trials are needed for the conclusion, review of the current literature gives us pause about the cardiovascular risk and long-term safety of these additives.

The Interplay of Microbiome Dysbiosis and Cardiovascular Disease.

The intricate ecosystem of the mammalian gut, which hosts a diverse microbiome, plays a vital role in various physiological functions. Trillions of bacteria within the gut contribute to host metabolism, immune modulation, energy homeostasis, and more. Emerging research highlights the gut microbiota's significant impact on cardiovascular diseases (CVDs), with intestinal dysbiosis identified as a risk factor for conditions such as obesity and diabetes, both linked to atherosclerosis. Chronic inflammation, pivotal in atherosclerosis, is influenced by the gut microbiome, where microbial signals, such as lipopolysaccharides, can translocate from the gut to trigger inflammatory responses. Diet has major effects on the gut microbiota, with the Western diet, rich in saturated fats, contributing to dysbiosis and elevated cardiovascular risks. Probiotics and prebiotics offer therapeutic potential in CVD management. Probiotics, or live microorganisms, exhibit antioxidant, anti-inflammatory, and cholesterol-lowering effects. Probiotics are most effective when given with prebiotics, with the former acting on the latter as substrate. Understanding the dynamic interplay between diet, gut microbiota, and CVD provides insights into preventive and therapeutic strategies.

Nanotechnology: The Future for Diagnostic and Therapeutic Intervention in Cardiovascular Diseases is Here.

With advances in technology and medicine over the last 3 decades, cardiovascular medicine has evolved tremendously. Nanotechnology provides a promising future in personalized precision medicine. In this review, we delve into the current and prospective applications of nanotechnology and nanoparticles in cardiology. Nanotechnology has allowed for point-of-care testing such as high-sensitivity troponins, as well as more precise cardiac imaging. This review is focused on 3 diseases within cardiology: coronary artery disease, heart failure, and valvular heart disease. The use of nanoparticles in coronary stents has shown success in preventing in-stent thrombosis, as well as using nanosized drug delivery medications to prevent neointimal proliferation in a way that spares systemic toxicity. In addition, by using nanoparticles as drug delivery systems, nanotechnology can be utilized in the delivery of goal-directed medical therapy in heart failure patients. It has also been shown to improve cell therapy in this patient population by helping in cell retention of grafts. Finally, the use of nanoparticles in the manufacturing of bioprosthetic valves provides a promising future for the longevity and success of cardiac valve repair and replacement.

Titin: The Missing Link in Cardiac Physiology.

Titin, an extraordinary protein known for its colossal size and multifaceted roles, is a cornerstone in the structural and functional dynamics of striated muscle tissues, including the heart and skeletal muscles. Its sheer enormity, with a molecular weight exceeding 3000 kDa, is paralleled only by the immense influence it exerts on muscle physiology. This review will delve into the remarkable structural organization of Titin and the genetics of this molecule, including the common mutations resulting in various cardiomyopathies. We will delve deeper into its role in dilated cardiomyopathy, familial restrictive cardiomyopathy, hypertrophic cardiomyopathy, and left ventricular noncompaction cardiomyopathy. This review culminates by discussing the prospects of therapeutic strategies targeting Titin. While these interventions remain primarily theoretical, the possibilities are intriguing. Patients with Titin truncation mutations present unique challenges, but innovative approaches like gene therapy or preemptive treatments with drugs such as angiotensin-converting enzyme inhibitors or beta-blockers offer hope. This multi-pronged approach highlights the significance of understanding Titin's multifaceted role and its potential as a target for future therapeutic interventions.

GPR75: A Newly Identified Receptor for Targeted Intervention in the Treatment of Obesity and Metabolic Syndrome.

Metabolic syndrome increases the risk of stroke, cardiovascular disease, and diabetes. The morbidity and mortality associated with this constellation of risk factors are equally alarming when considering the economic and global significance that this epidemic has on an institutional and patient level. Despite several current treatments available, there needs to be a continuous effort to explore more specific and effective druggable entities for preventative and therapeutic interventions. Within this context, the G-protein coupled receptor, GPR75, is an attractive pharmacological target. GPR75 and its association with its ligand, 20-hydroxyeicosatetraenoic acid, have been shown to promote hypertension, inflammation, obesity, and insulin resistance. This review will help shed light on this novel signaling pathway and offer a perspective on a promising new direction of targeting different aspects of the metabolic syndrome involving GPR75. Gene targeting of GPR75 is more effective than current pharmacologic therapies without the known side effects.