Abstract Background ST segment elevation myocardial infarction (STEMI) elicits an intense inflammatory response which is thought to contribute to subsequent maladaptive myocardial healing and remodeling, ultimately leading to heart failure (HF). The interleukin-1 (IL-1) blocker anakinra administered during the first 14 days after STEMI patients has been shown to effectively dampen the inflammatory response and reduce the incidence of HF events in pilot randomized controlled trials. Diabetes mellitus is a condition of enhanced systemic inflammation. Purpose To assess the role of diabetes mellitus as a modulating factor in respect to the efficacy of anakinra treatment during the first 14 days after STEMI. Methods We conducted a pooled analysis of three previous proof of principle trials on anakinra in STEMI. Diabetes mellitus was defined based on clinical history, use of glucose-lowering medications, or elevated hemoglobin A1c >6.5% at time of enrollment and further characterized as type I or type II based on the available clinical assessment. The area-under-the-curve for C reactive protein (AUC-CRP) at 14 days was used as a measure of the systemic inflammatory response during STEMI. The clinical endpoint was composite of death, hospitalizations for HF and urgent HF visits. Results The study population included 139 patients, of whom 39 (28%) had a diagnosis of diabetes mellitus at time of enrolment, all with type II. Median age was 56 [49-63] and 56 [49-63] years in patients with and without diabetes, respectively (p=0.652). There were 29 (21%) female and 52 (37%) Black-African American patients among those with diabetes compared to 29 (21%) female and 52 (37%) Black-African American patients in those without diabetes (p=0.69 and p=0.16, respectively). Treatment with anakinra (N=84) significantly dampened acute inflammation associated with STEMI in patients with diabetes (AUC-CRP 223 [117-399] vs 76 [42-148] mg•day/L, p<0.001) and in those without diabetes (AUC-CRP 223 [117-399] vs 76 [42-148] mg•day/L, p<0.001 – Figure 1). No statistically significant interaction between diabetes status and treatment with anakinra on outcomes was detected (pint=0.92): treatment with anakinra was associated with a hazard ratio [HR] 0.28 [0.09-0.84](p=0.02) in non-diabetic patients and HR 0.26 [0.11-1.32](p=0.10) in diabetic patients – Figure 2. Conclusion In this pooled analysis of the VCU-ART trials, the presence of type II diabetes mellitus showed no interaction with the efficacy of the treatment with anakinra early after STEMI in reducing the systemic inflammatory response or preventing new onset heart failure, hospitalization for HF or death.Figure 1.Figure 2
Abstract Recurrent pericarditis (RP) is the most troublesome complication of acute pericarditis reflecting an unresolving inflammation of the pericardial sac around the heart and associated with significant morbidity. Recent studies have shown interleukin-1 (IL-1) signaling to be central to the pathophysiology of cases of RP with evidence of activation of systemic inflammation. We herein review the literature and clinical trials discussing the utility of IL-1 blockade for RP. The early experience of IL-1 blockade with anakinra (Kineret) and its favorable safety profile paved the way for the clinical development of rilonacept (Arcalyst) and subsequent approval by the US FDA for RP. In patients with RP who have become colchicine-resistant and glucocorticoid-dependent, IL-1 blockade with rilonacept or anakinra effectively treats recurrences and prevents future flares and significantly improves quality of life.
OBJECTIVES/GOALS: Heart failure (HF) is a clinical condition that notably affects the lives of patients in rural areas. The partnering of a rural satellite hospital with an urban academic medical center may provide geographically underrepresented populations with HF an opportunity to access controlled clinical trials (CCTs). METHODS/STUDY POPULATION: We report our experience in screening, consenting and enrolling subjects at the VCU Health Community Memorial Hospital (VCU-CMH) in rural South Hill, Virginia, that is part of the larger VCU Health network, with the lead institution being VCU Health Medical College of Virginia Hospitals (VCU-MCV), Richmond, VA. Subjects were enrolled in a clinical trial sponsored by the National Institutes of Health (ClinicalTrials.gov: NCT03797001) and assigned to treatment with an anti-inflammatory drug for HF or placebo. We used the electronic health record and remote guidance and oversight from the VCU-MCV resources using a closed-loop communication network to work with local resources at the facility to perform screening, consenting and enrollment. RESULTS/ANTICIPATED RESULTS: One hundred subjects with recently decompensated HF were screened between January 2019 and August 2021, of these 61 are enrolled to date: 52 (85 %) at VCU-MCV and 9 (15%) at VCU-CMH. Of the subjects enrolled at VCU-CMH, 33% were female, 77% Black, with a mean age of 5210 years. DISCUSSION/SIGNIFICANCE: The use of a combination of virtual/remote monitoring and guidance of local resources in this trial provides an opportunity for decentralization and access of CCTs for potential novel treatment of HF to underrepresented individuals from rural areas.
Abstract Obesity and diabetes are independent risk factors for heart failure and are associated with the consumption of diet rich in saturated fat and sugar, Western diet (WD), known to induce cardiac dysfunction in the mouse through incompletely characterized inflammatory mechanisms. We hypothesized that the detrimental cardiac effects of WD are mediated by interleukin-18 (IL-18), pro-inflammatory cytokine linked to cardiac dysfunction. C57BL/6J wild-type male mice and IL-18 knockout male mice were fed high-saturated fat and high-sugar diet for 8 weeks. We measured food intake, body weight and fasting glycemia. We assessed left ventricular (LV) systolic and diastolic function by Doppler echocardiography and cardiac catheterization. In wild-type mice, WD induced a significant increase in isovolumetric relaxation time, myocardial performance index and left ventricular end-diastolic pressure, reflecting an impairment in diastolic function, paired with a mild reduction in LV ejection fraction. IL-18 KO mice had higher food intake and greater increase in body weight without significant differences in hyperglycemia. Despite displaying greater obesity, IL-18 knockout mice fed with WD for 8 weeks had preserved cardiac diastolic function and higher left ventricular ejection fraction. IL-18 mediates diet-induced cardiac dysfunction, independent of food intake and obesity, thus highlighting a disconnect between the metabolic and cardiac effects of IL-18.
