A prospective study of the effect of COVID-19 on psychiatric symptoms and sleep problems from infection to 9-month follow-up.

Diverse psychological consequences of the COVID-19 pandemic have been reported for 6 months after infection. We conducted a prospective study to evaluate the psychological impact of COVID-19 infection in newly diagnosed cases that were followed up at 1, 6, and 9 months after infection. 137 people were recruited and divided into four groups based on the COVID-19 Treatment Guidelines. They were evaluated using the Pittsburgh Sleep Quality Index (PSQI), Post-traumatic stress disorder Checklist for DSM-5 (PCL-5), and Symptom Checklist 90 (SCL-90). We found that 9 months after infection, patients continued to report poor sleep (74.5%), PTSD (78.3%), somatization (17%), anxiety (17%), aggression (5.7%), phobic anxiety (4.7%), psychoticism (1.9%), paranoid (3.8%), and obsessive-compulsive (9.4%) symptoms, as well as depression and interpersonal sensitivity. The most significant risk factors for psychiatric complications were older age, level of education, smoking, hospitalization duration, hypertension, and critical severity. The negative mental health effects of COVID-19 persist after hospital discharge, and many patients continue to experience moderate-to-severe issues that may endure for 9 months. Notably, there was a progressive improvement in these symptoms over that time.

Metabolic and Metabo-Clinical Signatures of Type 2 Diabetes, Obesity, Retinopathy, and Dyslipidemia.

Macro- and microvascular complications of type 2 diabetes (T2D), obesity, and dyslipidemia share common metabolic pathways. In this study, using a total of 1,300 metabolites from 996 Qatari adults (57% with T2D) and 1,159 metabolites from an independent cohort of 2,618 individuals from the Qatar BioBank (11% with T2D), we identified 373 metabolites associated with T2D, obesity, retinopathy, dyslipidemia, and lipoprotein levels, 161 of which were novel. Novel metabolites included phospholipids, sphingolipids, lysolipids, fatty acids, dipeptides, and metabolites of the urea cycle and xanthine, steroid, and glutathione metabolism. The identified metabolites enrich pathways of oxidative stress, lipotoxicity, glucotoxicity, and proteolysis. Second, we identified 15 patterns we defined as "metabo-clinical signatures." These are clusters of patients with T2D who group together based on metabolite levels and reveal the same clustering in two or more clinical variables (obesity, LDL, HDL, triglycerides, and retinopathy). These signatures revealed metabolic pathways associated with different clinical patterns and identified patients with extreme (very high/low) clinical variables associated with extreme metabolite levels in specific pathways. Among our novel findings are the role of N-acetylmethionine in retinopathy in conjunction with dyslipidemia and the possible roles of N-acetylvaline and pyroglutamine in association with high cholesterol levels and kidney function.

Diagnosis and treatment of type 1 diabetes at the dawn of the personalized medicine era.

Type 1 diabetes affects millions of people globally and requires careful management to avoid serious long-term complications, including heart and kidney disease, stroke, and loss of sight. The type 1 diabetes patient cohort is highly heterogeneous, with individuals presenting with disease at different stages and severities, arising from distinct etiologies, and overlaying varied genetic backgrounds. At present, the "one-size-fits-all" treatment for type 1 diabetes is exogenic insulin substitution therapy, but this approach fails to achieve optimal blood glucose control in many individuals. With advances in our understanding of early-stage diabetes development, diabetes stratification, and the role of genetics, type 1 diabetes is a promising candidate for a personalized medicine approach, which aims to apply "the right therapy at the right time, to the right patient". In the case of type 1 diabetes, great efforts are now being focused on risk stratification for diabetes development to enable pre-clinical detection, and the application of treatments such as gene therapy, to prevent pancreatic destruction in a sub-set of patients. Alongside this, breakthroughs in stem cell therapies hold great promise for the regeneration of pancreatic tissues in some individuals. Here we review the recent initiatives in the field of personalized medicine for type 1 diabetes, including the latest discoveries in stem cell and gene therapy for the disease, and current obstacles that must be overcome before the dream of personalized medicine for all type 1 diabetes patients can be realized.

Reading between the (Genetic) Lines: How Epigenetics is Unlocking Novel Therapies for Type 1 Diabetes.

Type 1 diabetes (T1D) is an autoimmune condition where the body's immune cells destroy their insulin-producing pancreatic beta cells leading to dysregulated glycaemia. Individuals with T1D control their blood glucose through exogenous insulin replacement therapy, often using multiple daily injections or pumps. However, failure to accurately mimic intrinsic glucose regulation results in glucose fluctuations and long-term complications impacting key organs such as the heart, kidneys, and/or the eyes. It is well established that genetic and environmental factors contribute to the initiation and progression of T1D, but recent studies show that epigenetic modifications are also important. Here, we discuss key epigenetic modifications associated with T1D pathogenesis and discuss how recent research is finding ways to harness epigenetic mechanisms to prevent, reverse, or manage T1D.