Active clinical trials for "Non-alcoholic Fatty Liver Disease"

Non Alcohlic Fatty Liver (NAFLD) is a spectrum of diseases that ranges from accumulation of fat in the liver (Hepatosteatosis) that may be accompanied by inflammation (Steatohepatitis) to necrosis, fibrosis and even cirrhosis resembling alcoholic hepatitis in the absence of alcoholic abuse (Pardee et al., 2012). It has been estimated that the global prevalence of NAFLD is as high as one billion. In the United States, NAFLD is estimated to be the most common cause of chronic liver disease, affecting between 80 and 100 million individuals, among whom nearly 25% progress to NASH (Loomba et al., 2013). In general, the prevalence of NAFLD has increased over the last 20 years. The Middle East and South America have the highest NAFLD prevalence at 31% and 32% respectively with the lowest prevalence in Africa at 13.5% (Younossi et al., 2016). Liver biopsy (LB) is still the standard test of NAFLD diagnosis and the presence of early liver fibrosis. However, histologic lesions are not evenly distributed throughout the liver. A sampling error is the biggest limitation in the diagnosis of NAFLD by LB with inflammatory lesions and ballooning degeneration potentially resulting in misdiagnoses and staging inaccuracies (Lee et al., 2016). To overcome these limitations, several non-invasive markers have been used instead of liver biopsy. These methods are either laboratory markers or imaging modalities. Controlled attenuation parameter (CAP) is a new technology based on the principle of the ultrasonic attenuation of transient elastography depending on the viscosity [fat] of the medium [liver] and the distance of propagation of the ultrasonic signals into the liver, providing a useful method for the quantitative detection of liver fat content and is considered a better assessment method for hepatic steatosis. Compared with ultrasound, this technology improves the sensitivity and specificity for the diagnosis of fatty liver and can be used for universal screening, diagnosis, and follow-up in NAFLD patients (Sasso et al., 2016). NAFLD is known to be closely associated with metabolic conditions, including insulin resistance, abdominal obesity, dyslipidaemia and type 2 diabetes, and is thus regarded as the hepatic manifestation of the metabolic syndrome (Ballestri., 2016). In recent epidemiological studies, NAFLD was shown to be connected with diseases that are usually not dependent on obesity, such as sarcopenia and osteoporosis (Poggiogalle et al., 2017). Osteoporosis is becoming a public health problem all over the world. Disability resulting from low-energy fractures, e.g: hip or vertebral fractures, is the major concern for early detection and treatment. It is estimated that osteoporosis affects 200 million women worldwide (Kanis et al., 2007). Liver is the source of many proteins and is the regulator of several pathways involving bone metabolism; one of the most well-known of all is vitamin D metabolism pathway. Considering the role of liver in bone metabolism, the association between NAFLD and bone abnormalities is not surprising especially with substantial supporting evidences in recent years (Eshraghian et al., 2017). Besides its role in the calcium and bone metabolism, vitamin D may also exert pleiotropic effects in many tissues. NAFLD patients were reported to have a marked reduction in serum 25(OH) vitamin D when compared with controls (Yilmaz et al., 2011). In adults, bone is constantly being remodeled, first being broken down (bone resorption) and then being rebuilt (bone formation). The resorption and reformation of bone is important for repair of microfractures and to allow modification of structure in response to stress and other biomechanical forces. Bone formation is normally tightly coupled to bone resorption, so that bone mass does not change. Bone diseases occur when formation and resorption are uncoupled. Several assays are available that measure bone turnover markers (BTMs). These assays measure collagen breakdown products and other molecules released from osteoclasts and osteoblasts during the process of bone resorption and formation. Markers that are specific to bone formation include bone-specific alkaline phosphatase (BSAP), osteocalcin, and N-terminal propeptide of type I procollagen (PINP); markers specific to bone resorption include N-terminal telopeptide of type I collagen (NTX), C-terminal telopeptide of type I collagen (CTX), and pyridinoline cross-links (Rosen et al., 2019).

One-third of the world's population suffers from Non-Alcoholic Fatty Liver Disease (NAFLD), that is a disease with an accumulation of fat in the liver. Some patients with NAFLD will progress in their disease to develop inflammation, scarring of the liver tissue, and cirrhosis that can lead to liver failure. The mechanisms of the disease and its progression are still not fully understood. It is therefore critical to find early markers that can identify the patients that will progress so that they can be treated early. A compound called L-carnitine, synthesised in the body from two amino acids; lysine and methionine, is critical for fat metabolism. Some studies have shown that it is decreased in liver disease patients and that L-carnitine supplementation can protect the liver function. This study aims to increase the understanding of the mechanisms behind NAFLD disease progression through its different stages. This may help diagnostic methods to be developed to predict the patients at risk for developing severe liver disease. Furthermore, fat metabolism and L-carnitine levels will be established in the different disease stages to evaluate whether fat metabolism could be compromised. Magnetic Resonance Imaging (MRI) will be used for imaging of the whole liver and the heart to investigate metabolism and function non-invasively. Whole-body metabolism and how carbohydrates are taken up from diets are converted to fats in the body will be explored using stable isotope labelling. This study will recruit 30 participants with NAFLD; 10 each for low-risk NALFD, biopsy-proven NASH and compensated NASH cirrhosis. Participants will undergo MRI, followed by a stable isotope labelled study, where through blood- and breathe samples, metabolism will be investigated. An additional 10 healthy participants will be assessed using MR techniques to assess whether an injection of L-carnitine can lead to increase of L-carnitine in the liver such that it can be detected by MR. This is to validate a methodology prior to using it in NAFLD participants.

Non-alcoholic fatty liver diseases (NAFLD) include several entities ranging from simple steatosis to hepatic fibrosis or cirrhosis. Steatosis, considered benign and the first stage of the disease, is characterized by the accumulation of triglycerides in the liver. It may in some cases progress to nonalcoholic steatohepatitis (NASH), which is characterized by the presence of a marked inflammation with or without fibrosis. NAFLD is the most common liver disease in the world and is particularly associated with type 2 diabetes (T2D) (80% in the diabetic population). While NASH is characterized by a higher prevalence of mortality from a cardiac and hepatic (cirrhosis and cancer) origin, therapeutic resources are almost non-existent. RANK (receptor activator of NF-kB) and its ligand RANKL (a member of the TNFalpha family) have emerged in recent years as new players in bone pathophysiology. By binding to its receptor, RANKL induces a number of signaling pathway and in particular the NF-kB pathway (Nuclear factor-kB), a major player in inflammation. Recent literature shows that the role of RANK / RANKL is not confined to the bone but may be involved in the genesis of inflammation in other tissues. It has been shown recently that a high circulating level of RANKL was a risk factor predictor of T2DM. Furthermore, the invalidation of RANK specifically in hepatocytes protects from insulin resistance and hepatic steatosis induced by a high fat diet in mice. The aim of our project is to provide a proof of concept that the RANKL / RANK system plays an important role in the pathogenesis of NAFLD and in the progression of this disease to NASH. The aim of our project is to provide a proof of concept that the RANKL / RANK system plays an important role in the pathogenesis of NAFLD and in the progression of this disease to NASH. The investigator propose to study the RANKL / RANK expression in serum and liver biopsies of type 2 diabetic patients at different stages of NAFLD.

To investigate the predictive roles of adipokines and hepatokines to detect non-alcoholic fatty liver disease (NAFLD), diabetes, or dyslipidmia. To examine the association or effects of clinical and biochemical factors (lab results and medication, etc.) on serum levels of adipokines and hepatokines in certain subjects with non-alcoholic fatty liver disease (NAFLD), diabetes, or dyslipidmia.

Since both pathologies (PCOS and NAFLD) involve disturbed carbohydrate economy, which revolve around insulin resistance, it is tempting to examine the specific "liver profile" of women with PCOD. Furthermore, it would be of great importance if lean women who suffer from PCOD would be revealed to shere cardiovascular risks with their more overweight peers. Patients - women who will be diagnosed with PCOD following their initial referal to our fertility clinic. Controls - normal ovulatory women who approached our fertility clinic due to either unexplained or male factor infertility. Workup - history for menstrual pattern; Clinical evaluation for features of hyperandrogenism; ultrasonographic documentation of ovarian morphology; follicular phase hormonal profile for validation of the diagnosis and for ruling out other pathologies which may cause anovulation. Liver profiling - The following blood tests will be used for the biochemical profiling: fasting glucose and insulin, CRP, HDL-cholesterol, triglycerides, AST, ALT, GGT, LDH, alkaline phosphatase, total bilirubin, direct bilirubin, ferritin, HBA1C and micro albumin ratio. FibroScan® will be used to measure liver stiffness.

This is a small preliminary study conducted to explore new methods for the potential of aiding in diagnosis of liver fibrotic disease as well as predicting disease progression. There will be a total of 4 visits spread out over approximately 8 weeks. You will be asked to drink "heavy water" during most of that time. "Heavy Water" also known as deuterated water, is physically and chemically very similar to ordinary drinking water. It tastes and feels exactly like regular water. It is odorless and has no known harmful effects at the doses given here. Heavy water occurs naturally, and is a minor component of the water we all ingest daily.

The objective of the study is to investigate the development of NAFLD following total pancreatectomy and pancreaticoduodenectomy and to explore the histological and metabolic changes following the procedures.

The present study investigates relationship between non-alcoholic fatty liver disease and its risk factors, such as genetic background and diseases, such as chronic kidney disease and diabetes mellitus.

Rationale: Non-alcoholic fatty liver disease (NAFLD) is the most widespread liver disorder in Western society (prevalence 20-30%). It is strongly associated with overweight and obesity. The majority of patients have simple steatosis. However, in about 15-30% of the subjects, a chronic inflammatory state develops that is referred to as non-alcoholic steatohepatitis (NASH), which leads to an overall increase in morbidity and mortality due to the progression to fibrosis, cirrhosis and in some cases, hepatocellular carcinoma (HCC). The term NAFLD comprises both simple steatosis and NASH. Most patients with NAFLD have no or few, mainly aspecific symptoms; and generally there is a silent progression of simple steatosis to NASH and in the end, liver-related morbidity and mortality. To date, liver biopsy is the most sensitive test for detecting and staging NAFLD, and is the only reliable method for differentiating between NASH and simple steatosis. However, the procedure of obtaining a liver biopsy is invasive and associated with patient discomfort, significant complications and high costs. In addition, liver biopsy is prone to sampling error and inter- and intra-observer variability, due to the small size of liver biopsy samples. This method is therefore not suitable for screening large numbers of subjects at risk, or for follow-up of patients with NASH over time. Hence, only subjects at high risk (usually based upon elevated aminotransferase levels, which is not specific for the presence of NASH) are biopsied, leading to an underestimation of NASH prevalence and undertreatment. Further insight into disease mechanisms and risk factors for NAFLD and in particular NASH is warranted, to enable early diagnosis, adequate therapy and preventive measures to improve health status of these individuals. Accurate and less invasive methods to evaluate NASH, and NAFLD, are urgently needed. Objective: The primary objective of this study is to establish non-invasive tools (e.g. biomarkers and imaging) to accurately diagnose patients with NASH. The secondary objective is to show an association between the levels of identified markers and disease severity. Study design: Eligible subjects will be included via the outpatient clinics Zuyderland in Heerlen, the Catharina hospital in Eindhoven and MUMC+ in Maastricht. A subset of eligible subjects has undergone a liver biopsy for clinical reasons. It is estimated that about 85% of subjects will be asked to undergo a biopsy for study purposes only. Liver biopsies for study purposes will be performed during a surgical procedure, e.g. bariatric surgery or cholecystectomy. Blood, faeces and exhaled air will be collected and a FibroScan (+CAP) will be performed during a study visit. An MRI will be performed, to estimate the degree of steatosis. Furthermore, anthropometric data (weight, height, abdominal and waist circumference and blood pressure (BP)) will be collected. The participants in the group undergoing liver biopsy during bariatric surgery will be asked permission to be approached for follow-up measurements 3 months post-surgery. As they will lose weight, which is associated with improvement of hepatic steatosis, this enables assessment of possible changes over time. A routine follow-up visit post-surgery will take place after 3 months. The follow-up measurements will be combined with this visit, minimizing the burden for the participant. The measurements will consist of blood, faeces and exhaled air collection and a FibroScan (+CAP) will be performed during a study visit. Furthermore, weight, height, BP and abdominal and waist circumference will be measured. Study population: Subjects with proven NAFLD by histology or NAFLD proven by imaging, who are undergoing surgery (i.e. bariatric surgery or cholecystectomy) will be asked to participate in this study. Furthermore, all subjects have to be between 18 and 65 years old. Main study parameters/endpoints: Non-invasive tool based on biomarkers and imaging to diagnose NASH.

To evaluate the role of regulatory B cells in the pathogenesis of metabolic associated fatty liver disease patients.