RESUMO
Cardiac sarcoidosis (CS) is a rare auto-immune disorder where immune cells form granulomas in the heart that may lead to potential arrhythmias and heart failure. Due to the low prevalence of CS, the management remains challenging, requiring a multidisciplinary approach. In addition to the management of the resulting arrhythmias and heart failure, corticosteroids and immunosuppressants are used as anti-inflammatories to prevent disease progression. Immunosuppressive regimens for the treatment of CS are not yet well established. Abatacept has been approved for rheumatoid arthritis and psoriatic arthritis and both are mainly Th1-driven autoimmune diseases. Even though there are several different drugs used to treat corticosteroid-dependent sarcoidosis, abatacept may represent a unique option as its side effects differ from other drugs like methotrexate, azathioprine, or mycophenolate, especially bone marrow and liver toxicity. We present the case of a 52-year-old CS patient treated with abatacept after the failure of methotrexate and mycophenolate mofetil. Our patient had a history of stage D heart failure with reduced ejection fraction (HFrEF) with ejection fraction (EF) of 15-20%, nonischemic cardiomyopathy (NICM) s/p left heart catheterization (LHC), CS diagnosed by positron emission tomography (PET), status post implantable cardioverter-defibrillator (ICD) implantation, lung sarcoid, paroxysmal atrial fibrillation, and aflutter, who followed with cardiology, rheumatology, and pulmonology. He had multiple admissions for heart failure exacerbations. The patient was initially diagnosed with pulmonary sarcoidosis after which he completed a small course of steroids. CT chest showed lymphadenopathy; however, endobronchial ultrasound (EBUS) did not show evidence of pulmonary sarcoidosis. During an admission for heart failure about four years later, cardiac PET CT showed CS, and rheumatology was brought on board. The patient initially refused steroids and steroid-sparing agents. At subsequent visits, the patient was amenable to medication and was started on methotrexate 10mg weekly. However, given worsening chronic kidney disorder, methotrexate was discontinued and mycophenolate 200mg daily was started. A couple of weeks after mycophenolate was started, the patient felt like "his throat was closing up" and his stomach was cramping, which was thought to be an allergic response to the mycophenolate so it was discontinued. He then received an abatacept infusion which he tolerated well. Currently, our patient has been referred for heart transplantation.
RESUMO
Background: Ketones are the brain's main alternative fuel to glucose. Dietary medium-chain triglyceride (MCT) supplements increase plasma ketones, but their ketogenic efficacy relative to coconut oil (CO) is not clear. Objective: The aim was to compare the acute ketogenic effects of the following test oils in healthy adults: coconut oil [CO; 3% tricaprylin (C8), 5% tricaprin (C10)], classical MCT oil (C8-C10; 55% C8, 35% C10), C8 (>95% C8), C10 (>95% C10), or CO mixed 50:50 with C8-C10 or C8. Methods: In a crossover design, 9 participants with mean ± SD ages 34 ± 12 y received two 20-mL doses of the test oils prepared as an emulsion in 250 mL lactose-free skim milk. During the control (CTL) test, participants received only the milk vehicle. The first test dose was taken with breakfast and the second was taken at noon but without lunch. Blood was sampled every 30 min over 8 h for plasma acetoacetate and ß-hydroxybutyrate (ß-HB) analysis. Results: C8 was the most ketogenic test oil with a day-long mean ± SEM of +295 ± 155 µmol/L above the CTL. C8 alone induced the highest plasma ketones expressed as the areas under the curve (AUCs) for 0-4 and 4-8 h (780 ± 426 µmol â h/L and 1876 ± 772 µmol â h/L, respectively); these values were 813% and 870% higher than CTL values (P < 0.01). CO plasma ketones peaked at +200 µmol/L, or 25% of the C8 ketone peak. The acetoacetate-to-ß-HB ratio increased 56% more after CO than after C8 after both doses. Conclusions: In healthy adults, C8 alone had the highest net ketogenic effect over 8 h, but induced only half the increase in the acetoacetate-to-ß-HB ratio compared with CO. Optimizing the type of MCT may help in developing ketogenic supplements designed to counteract deteriorating brain glucose uptake associated with aging. This trial was registered at clinicaltrials.gov as NCT 02679222.
RESUMO
Brain glucose uptake is impaired in Alzheimer's disease (AD). A key question is whether cognitive decline can be delayed if this brain energy defect is at least partly corrected or bypassed early in the disease. The principal ketones (also called ketone bodies), ß-hydroxybutyrate and acetoacetate, are the brain's main physiological alternative fuel to glucose. Three studies in mild-to-moderate AD have shown that, unlike with glucose, brain ketone uptake is not different from that in healthy age-matched controls. Published clinical trials demonstrate that increasing ketone availability to the brain via moderate nutritional ketosis has a modest beneficial effect on cognitive outcomes in mild-to-moderate AD and in mild cognitive impairment. Nutritional ketosis can be safely achieved by a high-fat ketogenic diet, by supplements providing 20-70 g/day of medium-chain triglycerides containing the eight- and ten-carbon fatty acids octanoate and decanoate, or by ketone esters. Given the acute dependence of the brain on its energy supply, it seems reasonable that the development of therapeutic strategies aimed at AD mandates consideration of how the underlying problem of deteriorating brain fuel supply can be corrected or delayed.
