Clinical Trial Details
— Status: Active, not recruiting
Administrative data
| NCT number |
NCT05969691 |
| Other study ID # |
MINGGE-SW-00003-V1-01 |
| Secondary ID |
|
| Status |
Active, not recruiting |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
March 15, 2019 |
| Est. completion date |
December 15, 2026 |
Study information
| Verified date |
August 2023 |
| Source |
Mingge LLC |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
The goal of this clinical trail is to non-invasively visualise and quantitatively validate an
radiomics model of genetic heterogeneity in adult patients with diffuse glioma to help
clinicians better guide surgical resection and treatment options. It aims to answer are:
1. To overcome the limitations of the existing genetic diagnostic process in terms of
equipment and technology requirements, high costs and long timelines, and to enable
quantitative studies of isocitrate dehydrogenase 1 (IDH1) mutations, thus allowing
refined patient stratification and further exploration of the role of molecular markers
in improving patient prognosis.
2. To achieve non-invasive diagnosis of gene mutations within tumours by taking advantage
of artificial intelligence and medical images, and to test the clinical feasibility of
the model through typical target puncture, gene sequencing and quantitative gene
expression analysis.
Participants will read an informed consent agreement before surgery and voluntarily decide
whether or not to join the experimental group. They will undergo preoperative magnetic
resonance imaging, intraoperative brain puncture of typical tumour sites, and postoperative
genotype identification. Their imaging data, genotype data, clinical history data, and
pathology data will be used for the experimental study.
Description:
BACKGROUND
The WHO 2016 officially introduced molecular markers into the pathological diagnosis of
gliomas, marking a step into the era of molecular diagnosis of gliomas. Among them,
isocitrate dehydrogenase 1 (IDH1) mutation is considered to be the 'backbone' in the
development of gliomas, and affects the treatment plan and prognosis of patients. However,
the clinical use of this molecular biomarker is still controversial, which is rooted in the
lack of quantitative studies on IDH1 mutations. The spatial heterogeneity of gliomas has been
demonstrated in existing studies, i.e., tumor tissues in different parts of the same glioma
belong to different genetic subtypes. This implies that IDH1-mutant tumors do not indicate
the presence of mutations in all tumor cells, thus further exacerbating the problems in
clinical genetic diagnosis.
OBJECTIVE
To quantify gene mutations in tumours, we plan to use radiomics model with artificial
intelligence and clinical big data, and verify its accuracy by tissue puncture. In this way,
we can overcome the challenges of multisite sampling and second-generation sequencing, such
as high equipment and technology requirements, high cost and long time, and thus
theoretically realise the visualisation and quantification of genetic heterogeneity within
gliomas.
PROCESS
Participants will read an informed consent agreement before surgery and voluntarily decide
whether or not to join the experimental group.
1. Modelling of visualisation of genetic heterogeneity
Before surgery, participants first Routine imaging and the resulting images will be used
to build a radiomics model. The model will non-invasively predict IDH1 mutations in
gliomas.
2. Typical site puncture
After the enrolled participants were anaesthetised and craniotomised, clinicians
selected typical tumor sites for puncture based on the model outputs.
3. Histopathological diagnosis
The specimen from the same puncture site is divided into two parts, and the first part
is routinely formalin-fixed for paraffin embedding and finally H&E-stained sections. The
pathologist first reads the H&E sections and makes a histological diagnosis, describing
the pathological morphology and characteristics, especially the tumor cell content and
distribution.
4. IDH1 single nucleotide sequencing
Another part of the sample is used for liquid nitrogen preservation. The Qiagen DNA/RNA
Extraction Kit is used to extract DNA from the liquid nitrogen preserved tumour tissue,
which is purified and subjected to the IDH1 polymerase chain reaction (PCR). The PCR
product is purified and subjected to sequencing, and the sequencing product is detected
on an ABI 7200 sequencer to determine whether IDH1 is mutated or not.
5. Mass spectrometry analysis of 2-Hydroxyglutarate (2-HG) expression levels
The presence and expression of 2-HG in glioma samples is detected and analysed by mass
spectrometry.
6. Validation of the radiomics-based IDH1 mutation prediction model. The 2-HG detection
results were numerically compared with the model results.
This is a single centre validation study. Compared with the routine glioma surgical
procedure, this study adds intraoperative tumor-typical sits puncture to validate the
predictive accuracy of the radiomics model and collects corresponding MRI images, tumour
histology diagnosis, molecular pathology diagnosis. The radiomics model is built based on
preoperative clinical data and is a non-invasive and rapid tool for quantitative analysis and
visualisation of tumor genes.
