Clinical Trial Details
— Status: Completed
Administrative data
NCT number |
NCT05189990 |
Other study ID # |
HKU-DM-MAK-NAFLD01 |
Secondary ID |
|
Status |
Completed |
Phase |
|
First received |
|
Last updated |
|
Start date |
January 1, 2022 |
Est. completion date |
February 29, 2024 |
Study information
Verified date |
May 2024 |
Source |
The University of Hong Kong |
Contact |
n/a |
Is FDA regulated |
No |
Health authority |
|
Study type |
Observational
|
Clinical Trial Summary
Non-alcoholic fatty liver disease (NAFLD) is a condition where hepatocytes contain an
abnormally high fat percentage. This condition is becoming increasingly common due to
unhealthy food habits and sedentary lifestyle. Since NAFLD is a silent disease, many patients
would be diagnosed at the advanced stages when fat accumulation, scarring and liver cell
damage are irreversible. Therefore, early diagnosis of fatty liver disease during its
reversible stages is warranted. Current diagnostic techniques for fatty liver disease, such
as the FibroScan® and MRI proton density fat fraction (PDFF) are expensive, and require the
active work of certified professionals. Electrical Impedance Tomography (EIT) is an
alternative low cost, non-invasive imaging technique that does not involve radiation nor a
trained operator. The electrical conductivity of biological tissues varies according to the
tissue type and frequency of AC current. Fat tissue conductivity is known to be substantially
stable across the EIT current injection frequency spectrum. On the other hand, liver tissue
conductivity significantly increases over frequency change. Hence, the liver fat content can
be measured using frequency-difference EIT (fdEIT). The aim of this study is to investigate
the feasibility and effectiveness of fdEIT in detecting fatty liver. To achieve this goal, a
total of 160 subjects will be recruited, paired fdEIT-Fibroscan data will be acquired. First,
optimal fdEIT current injection frequency range will be determined. Second, fdEIT derived
indicators will be computed and statistical analysis will be performed to verify the
significance of correlation between the two. Comparative exploration between EIT and MRI-PDFF
will be performed on a subset of the study population, looking at both spatial localization
and image derived indicators.
Finally, demographics, clinical assessment and patient history will be analysed to produce
demographic group-based insights.
Description:
Fatty liver disease is a condition where the hepatocytes (liver cells) contain more than 5%
fat. This condition is becoming increasingly common due to unhealthy food habits and
sedentary lifestyle. Since NAFLD is a silent disease with symptoms arising only at the later
stages (e.g., fibrosis), many patients would be diagnosed at the advanced stages when fat
accumulation, scarring and liver cell damage are irreversible. Therefore, early diagnosis of
silent fatty liver disease during its reversible stages is important to prevent cell damage,
liver transplantation and allow better long-term prognosis.
Currently, liver biopsy is the gold standard in diagnosis and prognosis of fatty liver
disease. However, biopsies are invasive, expensive and involve risks of internal bleeding and
high sampling error. Non-invasive diagnostic tests include blood tests, FibroScan® and MRI.
FibroScan® (Echosens, Paris, France) is a quick 10 minutes non-invasive test which measures
the fatty change. Normal liver fat amount has controlled attenuation parameter (CAP) <248
dB/m which is S0, while mild fatty liver has CAP 248-267 dB/m or S1. Moderate fatty liver has
CAP 268-279 dB/m or S2 and lastly severe fatty liver has CAP >279 dB/m or S3 (Karlas et al.,
2017). The device is known to have reduced reliability for patients who are morbidly obese or
have ascites. It also heavily relies on the operator experience. Another liver fat
quantification method is MRI-based proton density fat fraction (MRI-PDFF). MRI-PDFF is a
noninvasive imaging tool which can accurately and precisely calculate the percentage of liver
fat over the whole liver. Nevertheless, MRI-PDFF takes a long time (~30 minutes), is
expensive, not portable and not routinely accessible.
EIT could be an alternative low cost, noninvasive imaging technique that does not involve
radiation and is routinely accessible. Existing EIT commercial devices are at present being
deployed in some clinical settings. EIT technology has been in use since more than a decade,
although so far it has mostly been used to assist mechanically ventilated patients in
intensive care units to prevent lung damage caused by artificial ventilation.
Within the past few years, non-clinical research studies on applying EIT for fatty liver
detection in animal and human models have been performed. The electrical conductivity of
biological tissues varies according to the tissue type and frequency of AC current. On one
hand, fat tissue conductivity is known to be substantially stable across the EIT current
injection frequency spectrum. On the other hand, liver tissue conductivity significantly
increases over frequency change. Hence, biological tissues can potentially be differentiated
using EIT frequency spectrum analysis.