Effect of Molecular Hydrogen in Patients With NAFLD

Not Applicable

Completed

• Conditions: Non-Alcoholic Fatty Liver Disease
• Interventions: Dietary Supplement: placebo; Dietary Supplement: HRW drink, HRW Natural Health Products Inc., Made in Vancouver, Canada

• Registration Number: NCT05325398
• Lead Sponsor: Comenius University

Brief Summary

Molecular hydrogen H2 acts as antioxidant which selectively reduces cytotoxic harmful reactive oxygen species ROS and concomitantly acts as biological messenger, which mediates several signaling pathways that play cytoprotective role in many human diseases. Due to their small size and high permeability, H2 is easily transportable into subcellular structures as mitochondria.

Detailed Description

Non-alcoholic fatty liver disease, NAFLD, is the most common cause of liver disease. According to the forecasts, the non-alcoholic steatohepatitis will be the most common cause of liver transplantation and hepatic mortality in 2030. NAFLD is also a significant risk factor for the development of hepatocellular carcinoma, even in the non-cirrhotic stage of liver disease. The prevention of the progression of NAFLD to NASH (nonalcoholic steatohepatitis) is therefore a key factor in preventing this unfavorable prognosis.

Obesity and its associated comorbidities are among the most widespread and challenging conditions in the confrontation of the medical profession in the 21st century. The main metabolic consequence of obesity is insulin resistance, which is strongly associated with the storage of triacylglycerols in the liver. Hepatic steatosis may be associated with steatohepatitis, a condition that can lead to liver cirrhosis and, in the final stage, liver transplantation.

According to various sources, the incidence of NAFLD in the population is 20-30%, in obese up to 60%, which makes it the most common liver disease. In the USA, it is even 3 times more common than type 2 diabetes mellitus and 5-10 times more common than chronic hepatitis C. The incidence of non-alcoholic steatohepatitis NASH is 2-3% and is now thought to be the cause of up to 80% cryptogenic liver cirrhosis. The risk of developing cirrhosis in patients with simple hepatic steatosis is 1-2% over 8 years.

Insulin resistance, which is defined as an elevated HOMA (homeostasis model assessment) index above 1,4, is found in 70% of patients with NAFLD and plays a major role in the accumulation of triacylglycerols TAG (triacylglyceride) in the liver. Through the rise of hormone-sensitive lipase, hyperinsulinemia leads to the hydrolysis of free fatty acids FFA from visceral adipocytes to the portal vein, through which they enter directly into the liver, where they are esterified to TAG. Reducing the production of apolipoprotein B-100, which is an important part of their secretion from the liver into the circulation in the form of VLDL-lipoproteins, is also a potentiating factor in TAG deposition in the liver. Free oxygen radicals ROS (reactive oxygen species), which are formed due to the oxidative stress, are formed directly in the hepatocyte. However, their formation in visceral adipocytes has also been shown to be involved in liver damage. The main site of ROS are mitochondria. In NAFLD, known mitochondrial dysfunction leads to pathological oxidation of FFA (free fatty acid) in peroxisomes and microsomes, making them another source of ROS. ROS, through damage of the mitochondrial membrane by lipoperoxidation and induction of Fas-ligand expression on the hepatocyte, leads to cell apoptosis.

By activating stellate cells, a larger amount of extracellular matrix is formed - Mallory's hyaline, which is associated with the formation of balloon degeneration of hepatocytes, that is a typical histological feature of NASH.

From the cytokines, TNF-alpha is mainly used. It is formed by hepatocytes due to the increased supply of FFA. The diagnostic process is often random. One of the options for non-invasive measurement of liver fibrosis is transient elastography FibroScan, which is used for direct measurement of liver elasticity or use of noninvasive fibrosis indexes (NFS, Fib-4, APRI etc) as nondirect tools. Initial studies have confirmed that H2 penetrates cell membranes and protects mitochondria and cell nuclei from acute oxidative stress. Several studies have reported the effect of H2 on mitochondrial function. With H2, the investigators protect the potential of the mitochondrial membrane, increase ATP production and reduce organelle swelling. There are at least four possible mechanisms for H2 through which gene expression can be altered through mitochondrial bioenergetics, of which ghrelin is probably the most important. Ghrelin is the hormone responsible for appetite.

It reaches its maximum level during hunger. Obestatin has the opposite effect, which in turn suppresses the feeling of hunger. The role of ghrelin as an energy modulator in H2 intervention may be promoted by interaction with expressed glucose transporters, which increase glucose consumption and modulate oxidative phosphorylation in mitochondria. Exercise led to a significant change in ghrelin levels but had no effect on plasma levels of obestatin.

Molecular hydrogen has been shown to relieve oxidative stress, have an anti-inflammatory effect and improve lipid, glucose and energy production in patients as well as in animal models of hepatic steatosis and atherosclerosis. The basic molecular mechanisms remain largely unknown.

Molecular hydrogen is an effective antioxidant that reduces cytotoxic reactive oxygen radicals, especially the hydroxyl radical. In several previous experiments, the use of hydrogen-enriched water, HRW, has been shown to have antioxidant effects. The effects of hydrogen on the prevention of hepatocarcinogenesis in STAM mice were also investigated. The number of tumors was significantly lower in the HRW groups and the tumors were smaller than in the other groups. The results clearly demonstrated that HRW can be an effective treatment for apoptosis, inflammation and hepatocarcinogenesis in NAFLD.

The aim of the study is to verify effectiveness and safety of molecular hydrogen on a group of patients with NAFLD.

Study Timeline

• Study Start: 2020-05-01
• Primary Completion: 2020-12-01
• Study Completion: 2020-12-18
• Study First Submitted: 2021-05-14
• Status Verified: 2022-04
• Study First Submitted QC: 2022-04-06
• Last Update Submitted: 2022-04-06
• Study First Posted: 2022-04-13
• Last Update Posted: 2022-04-13

Recruitment & Eligibility

• Status: COMPLETED
• Sex: All
• Target Recruitment: 30

Inclusion Criteria

• People with age 33-69 years
• BMI ≥ 25
• Confirmation of fatty liver by ultrasonographic examination
• Signed informed consent
• Alcohol intake according to the AUDIT questionnaire 5 or less points for men or 4 or less points for women

Exclusion Criteria

• Unsigned informed consent
• BMI < 25
• Presence of severe inflammatory disease with activity (Crohn's disease, ulcerative colitis, active tuberculosis, rheumatoid arthritis, etc.)
• Presence of acute infectious disease (acute hepatitis, peritonitis, cholecystitis, pancreatitis, etc.)
• Presence of active neoplastic disease
• Alcohol intake according to the AUDIT questionnaire more as 5 points for men or more as 4 points for women

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: PARALLEL

Arm && Interventions

Group	Intervention	Description
probands in the control group	placebo	13 probands in the control group who will receive placebo.
patients with NAFLD	HRW drink, HRW Natural Health Products Inc., Made in Vancouver, Canada	17 patients will receive molecular hydrogen

Primary Outcome Measures

Name	Time	Method
Changes in blood parameters Insulin	8 weeks	Insulin (mIU/L)
Changes in blood parameters Beta carotene	8 weeks	Beta carotene (μmol/L)
Changes in blood parameters Coenzyme Q 10 in platelets	8 weeks	Coenzyme Q 10 in platelets (pmol/10\^9 cells)
Changes in blood parameters Coenzyme Q 10 in plasma	8 weeks	Coenzyme Q 10 in plasma (μmol/L)
Changes in blood parameters LDH	8 weeks	LDH (lactatdehydrogenase) (mU/mL)
Changes in blood parameters MMP-9	8 weeks	MMP-9 (matrix-metalloproteinase 9) (% of change)
Changes in blood parameters NFkB	8 weeks	NFkB (nuclear factor kappa B) (% of change)
Changes in blood parameters ALT	8 weeks	ALT (alaninaminotransferase) ukat/L
Changes in blood parameters Glucose	8 weeks	Glucose (mmol/L)
Changes in blood parameters Cholinesterase	8 weeks	Cholinesterase (ukat/L)
Changes in blood parameters TBARS	8 weeks	TBARS (μmol/L)
Changes in blood parameters SOD	8 weeks	SOD (superoxiddismutase) (ng/mL)
Changes in blood parameters AST	8 weeks	AST (aspartataminotransferase) ukat/L
Changes in blood parameters GMT	8 weeks	GMT (gamaglutamyltransferase) ukat/L
Changes in blood parameters Cholesterol	8 weeks	Cholesterol (mmol/L)
Changes in blood parameters Triacylglycerol	8 weeks	Triacylglycerol (mmol/L)
Changes in blood parameters Hemoglobin	8 weeks	Hemoglobin (g/L)
Changes in blood parameters Alpha tocopherol	8 weeks	Alpha tocopherol (μmol/L)
Changes in body parameters: Weight in kilograms, height in meters, waist circumference in centimeters	8 weeks	The following parameters will be measured for each proband before (time 0) and after the study (time 8 weeks): a) weight and height will be combined to report BMI in kg/m\^2, waist circumference in cm.
Changes in blood parameters ALP	8 weeks	ALP (alkaline phosphatase) ukat/L
Changes in blood parameters Albumin	8 weeks	Albumin (g/L)
Changes in blood parameters Bilirubin	8 weeks	Bilirubin total (umol/L)
Changes in blood parameters HOMA index	8 weeks	HOMA index (calculation)
Changes in blood parameters Leucocytes	8 weeks	Leucocytes (x10\^9/L)
Changes in blood parameters MDA	8 weeks	MDA (malondialdehyde) (μmol/L)
Changes in blood parameters 8-OHdG	8 weeks	8-OHdG (8-hydroxy-2-deoxyguanosine) (ng/mL)
Changes in blood parameters TNF alfa	8 weeks	TNF alfa (tumor necrosis factor alpha) (% of change)
Changes in blood parameters HSP 60	8 weeks	HSP 60 (heat shock protein 60) (% of change)
Changes in blood parameters HSP 70	8 weeks	HSP 70 (heat shock protein 70) (% of change)
Changes in blood parameters Platelets	8 weeks	Platelets (x10\^9/L)
Changes in blood parameters MMP-2	8 weeks	MMP-2 (matrix metalloproteinase2) (% of change)
Changes in blood parameters Gama tocopherol	8 weeks	Gama tocopherol (μmol/L)
Changes in blood parameters Coenzyme Q 10 in whole blood	8 weeks	Coenzyme Q 10 in whole blood (μmol/L)

Trial Locations

Locations (1)

3rd Department of Internal Medicine Faculty of Medicine Comenius University in Bratislava; 🇸🇰 Bratislava, Slovakia