Clinical Trial Details
— Status: Not yet recruiting
Administrative data
| NCT number |
NCT06107101 |
| Other study ID # |
H23-01777 |
| Secondary ID |
|
| Status |
Not yet recruiting |
| Phase |
Phase 4
|
| First received |
|
| Last updated |
|
| Start date |
June 1, 2024 |
| Est. completion date |
January 1, 2025 |
Study information
| Verified date |
April 2024 |
| Source |
St. Paul's Sinus Centre |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Chronic rhinosinusitis (CRS) is a condition of persistent sinonasal mucosal inflammation
which affects 11.9% of the US population. Mepolizumab is newly approved to treat chronic
rhinosinusitis with nasal polyps (CRSwNP, the spaces inside nose and head are swollen and
inflamed) and acts booking interleukin-5 (IL-5) a protein implicated in the inflammatory
process. We aim to use Single-cell RNA sequencing (RNA-Seq, a method of genetically
'barcoding' cells to allow gene expression to be profiled at the level of individual cells)
to study the effects of IL-5 blockade on the generation and maintenance of nasal adaptive
immune responses, in CRS subjects.
Description:
Purpose:
CRS is a poorly understood disease with suboptimal therapeutic strategies and a high disease
burden. Adaptive immunity in the form of Th2 polarized T cell responses and B cell IgE class
switching, and plasma cell infiltration, are a core component of eosinophilic CRS and asthma,
yet our understanding of adaptive immunity in CRS remains limited. Modulating the Th2
response, through IL-5 blockade, leads to mixed results for CRSwNP patients. There are a
number of patients who achieve improved asthma control with IL-5 blockade therapies that fail
to see the same improvements in their nasal disease, outlining the currently limited
understanding of factors involved in disease activity, disease endotypes, and the effects of
modulating the Th2 response in this tissue environment. Improved understanding of nasal
tissue immunity modulation by IL-5 blockade at a cellular level is an essential step towards
appropriate patient selection and development of new targeted therapeutics. Single-cell
transcriptomics is powerful tool for characterizing tissue immune landscapes and functional
variations, has as yet been poorly utilized beyond studies of nasal epithelium in CRS
Hypothesis
- IL-5 blockade stimulates increased activity of nasal tissue T cells > peripheral blood T
cells, and promotes increased tissue T cell Th2 polarization
- IL-5 blockade stimulates increased B cell germinal center activity in nasal secondary
and tertiary lymphoid structures, through increased Tfh-B cell interactions and
increased maturation to tissue antibody-secreting cells through BLIMP1 upregulation in
Germinal Centre B cells.
Objectives
1. Characterise the local mucosal B cell response in tertiary (nasal) and secondary
(postnasal space) lymphoid organs in CRSwNP, compared with circulating immunity, through
visualization and modeling of germinal center activity, cellular support for germinal
center activity and assessment of B cell clonal selection, class-switching, fate, and
somatic hypermutation using single-cell transcriptomics, single-cell BCR (B- cell
receptor) sequencing and spatial resolution through confocal microscopy.
2. Use single-cell transcriptomics and VDJ (variable, diversity, and joining) repertoire
analysis to characterize the effects of Th2 modulation, through IL-5 blockade, on the
formation and maintenance of nasal T and B cell adaptive immune memory.
3. Localize nasal sources of pro-inflammatory signaling in CRSwNP in the presence of IL-5
blockade, using single-cell transcriptomics, confocal microscopy, and nasal cytokine
analysis.
4. Compare nasal pro-inflammatory cell subsets with paired peripheral blood samples by
single cell transcriptomics, to correlate activity with biomarker candidates.
Research design
The proposed study is a prospective experimental medicine study using IL-5 blockade as a way
of investigating the effects of Th2 modulation on the generation of local tissue adaptive
immunity in CRSwNP. Participants will be classified in:
- Treatment group:20 subjects with CRSwNP and asthma that will start Mepolizumab treatment
- Disease control group: 10 subjects with CRSsNP without asthma that will not start
Mepolizumab and will continue their standard of care treatment.
- Control group: 10 healthy subjects without any sinuses disease
This study involves three study visits for the Treatment arm (Baseline, weeks 6, and 30), two
visits for disease control subjects, and one (Baseline) visit for Healthy control subjects.
Participants on study medication will receive 100mg of mepolizumab every 4 weeks
subcutaneously.
Treatment Arm:
CRSwNP (NPS 1-8) and asthma undergoing IL-5 blockade (Mepolizumab)
• Week 0: Recruitment, screening, and initiating standard-of-care therapy
o Nasal and blood samples Week 6 - Pre-Mepolizumab commencement (Pre-treatment) Week 30 -
After Mepolizumab commencement (On treatment)
Control Arm:
1. Diseased Control:
CRSsNP without asthma
• Week 0: Recruitment, screening, and initiating standard-of care therapy
o Nasal and blood samples Week 6 - After 6 weeks standard of care therapy
2. Healthy control • Week 0: Recruitment and screening, Nasal and blood samples
Statistical analysis Single cell RNA sequencing data Sequenced data will be aligned with
CellRanger v7.0. The resulting output files will be processed using a standard filtering and
QC pipeline in Scanpy. The batch correction will be performed using scVI, and Leiden
clustering will be performed. Cluster labels will be assigned using canonical marker genes
and published gene signatures, with validation using a published dataset of sorted immune
cells via the SingleR package. The downstream analysis will include, but not be limited to,
gene set expression analysis (GSEA) of Hallmark and Gene Ontology genesets, differential
abundance testing, weighted gene co-expression network analysis, and imputation of cell-cell
interaction using CellphoneDB. TCR analysis will be performed using Scirpy, and BCR analysis
with the Dandelion, and Immcantation suites
