The Effect of 0.1% Topical Ciclosporin A for 12-weeks on the Eye Surface Immune Cells in Dry Eyes

NCT ID: NCT06898853

Last Updated: 2025-04-02

Basic Information

• Recruitment Status: NOT_YET_RECRUITING
• Clinical Phase: NA
• Total Enrollment: 60 participants
• Study Classification: INTERVENTIONAL
• Study Start Date: 2025-05-01
• Study Completion Date: 2026-09-30

Brief Summary

Dry eye disease (DED) is a common, long-lasting condition that affects the surface of the eye. It happens when there's a problem with tear production or quality, which can lead to inflammation and discomfort. The immune system plays a big role in how DED develops and continues.

Researchers have found that in people with DED, there are more immune cells and inflammatory substances in the tears and on the eye's surface. This includes various types of immune cells, like T cells and dendritic cells, which are part of the body's defense system.

The first treatment for DED is usually artificial tears, but because the condition is chronic and can flare up, clinicians often use anti-inflammatory treatments too. One such treatment is cyclosporine A (CsA), which comes as eye drops. CsA works by reducing inflammation and affects how immune cells behave.

Researchers can study the immune cells on the eye's surface using a special microscopy technique called in vivo confocal microscopy (IVCM). A newer version of this method, called functional IVCM (Fun-IVCM), allows researchers to watch how these cells move and behave over time.

In the current study, researchers want to compare 0.1% CsA with a lubricating eye drop to see how they affect the immune cells on the eye's surface. The researchers will use Fun-IVCM to look at the number, shape, and movement of immune cells of the eye. The researchers will also collect samples from the eye's surface and tears to measure various markers of inflammation.

The goal is to better understand how CsA works in treating DED by directly observing its effects on the immune response in the eye, which is unexplored. This could help improve treatments for people suffering from this condition and expand the use of CsA in DED.

Detailed Description

The immune system plays a pivotal role in dry eye disease (DED) pathogenesis. An increased level of several tear cytokines, chemokines, expression of HLA-DR molecules and activation of antigen presenting cells - dendritic cells (DCs), and lymphocytes all plays a central role in DED pathogenesis . The increased expressions of CD4+ and CD8+ T cells in the ocular surface of DED patients suggest a potential role of adaptive immunity in DED chronicity. The presence of antigen-presenting cells in the ocular surface and the upregulation of MHC II, IL-2, IL-17, IL-6 and IFN- γ and other co-stimulatory molecules in the tears of DED patients indicates a possible activation of the local adaptive immune response.

The conjunctiva serves as a primary site for immunological and histochemical analysis in ocular surface diseases . Researchers have employed various techniques to study ocular surface immunology such as impression cytology, conjunctival biopsy and through real-time polymerase chain reaction, immunocytochemistry, and light microscopy. Flow cytometry is a powerful technique that allows for the phenotypic analysis of cells through immunolabeling of extracellular expressions of various immune cell markers. An increased expressions of activation markers like HLA-DR and various immune cell populations including T cells (CD3+, CD4+, and CD8+), B cells, natural killer cells, and monocytes (CD14+ cells) are observed in DED using flow cytometry on conjunctival impression cytology samples .

Historically, studying human ocular surface immune cells required invasive techniques. With the advent of in vivo confocal microscopy (IVCM), has enabled real-time, non-invasive visualization of ocular surface epithelial immune cells (EICs) and corneal nerves. Over the past 20 years, researchers have used IVCM to examine pathologic changes in various ocular surface disorders. It is evident from several IVCM studies that corneal EICs undergoes changes such as increase in density and changes in its morphology in all forms of DED. Conventional static IVCM captures section images at a single time point of the corneal EIC's, and their analysis is limited to its density and morphology. While the in vivo nature of IVCM prevents direct immune cell phenotyping, the observed cells are predominantly believed to be DCs based on their morphological characteristics. Therefore, the authors have used the term EICs to define immune cells density (EIC density) quantified using static-IVCM. Unlike this method, which limits identification of the immune cell type, a recently pioneered, novel technique called functional IVCM (Fun-IVCM) enables identification of the immune cell types in the cornea by observing their morphodynamics. This method involves capturing consecutive sequence and volume scan images over a 30-40-minute period, with intervals of 4-5 minutes. The images are then time-lapsed to identify dynamic behaviour of each immune cell. Based on their dynamic behaviour and morphology, cells can be differentiated into either epithelial T cells (highly motile, smaller body size) or dendritic cells (DC's, less motile, larger body size with dendrites). Anterior corneal stromal macrophages can also be identified. Time-lapsed images allow for the examination of additional cell motility parameters, such as instantaneous speed and displacement speed.

The first-line treatment for DED is artificial tears. But, due to the chronic nature of the disease and recurrent acute exacerbations anti-inflammatory therapies has been largely implemented. Consequently, many of the current therapeutic approaches target various inflammatory pathways, aiming to break the vicious cycle of DED. Both topical corticosteroids and immunosuppressants effectively reduce inflammation in DED. Topical corticosteroids are used in DED to control acute exacerbations of inflammation of the ocular surface, but their longer-term use is limited by their iatrogenic ocular side-effects. To contrast this, immunosuppressive agents such as ciclosporin A (CsA) have potential anti-inflammatory effect, with minimal local side-effects. The use of CsA in chronic DED can significantly reduce ocular surface staining, redness, inflammatory markers and improves dry eye symptoms. In brief, CsA dampens T cell proliferation by inhibiting the phosphatase calcineurin. CsA functions at different steps of the immune response, during antigen presentation and DC-T cell interaction. Innate immune cells are now seen as potentially important targets of CsA and may reflect simultaneous targeting of dendritic cells, macrophages, and neutrophils. In the ocular surface preliminary evidence suggest that CsA can significantly reduce activation markers such as HLA-DR, CD11c, certain apoptosis markers, and conjunctival T lymphocytes accompanied the clinical improvement in CsA-treated DED patients.

While a handful of clinical trials have evidenced the efficacy of CsA in reducing inflammation and improving symptoms of DED, the direct effect of CsA on ocular surface immune cells has not been studied in detail using static and using Fun-IVCM. Given the effect of CsA on both innate and adaptive immune cells, the authors hypothesise that the use of 0.1% CsA will have an inhibitory effect on the ocular surface immune response along with improvement of signs and symptoms of DED compared with its vehicle. This paper highlights the randomized clinical trial protocol to comprehensively study the effect of CsA on the ocular surface innate and adaptive immune system in DED. The study will investigate CsA's impact on DCs (CD11c+ DCs, HLA-DR), T helper cell populations (CD4+ T cells) through analysis of lymphocyte markers (CD45, CD3, CD4) and their associated cytokines (Th1 pathway cytokines), particularly IL-2, IFN- γ and IL-17 which is a primary target of CsA's immunomodulatory action.

1.2. Study aims and hypothesis Aim 1: To investigate and compare the effect of 12-weeks topical 0.1% CsA therapy on ocular surface innate and adaptive immune cells using imaging - Static-IVCM and Fun-IVCM (immune cell density, morphology and morphodynamic behaviours), immune cell phenotyping using conjunctival impression cytology and flow cytometry techniques and tear cytokine analysis (Multiplex bead assay assessing tear concentrations of IL-2, IL-4, IL-6, IL-12, IL-17, IL-23, IFN- γ) Hypothesis: CsA will have an inhibitory effect on the ocular surface innate and adaptive immune cell density, morphology and tear cytokines in DED.

Aim 2: To assess the association between DED signs, symptoms and immune cell characteristics and tear cytokines in DED Hypothesis: A direct relationship between immune cell characteristics, teat cytokines and DED signs, symptoms exist.

Aim 3: To investigate the temporal relationship between immune cell changes and clinical improvement Hypothesis: Changes in immune cell characteristics (density and dynamics) and inflammatory markers precede clinical improvement in signs and symptoms of DED following CsA treatment.

Conditions

Dry Eye Disease (DED)

Study Design

• Allocation Method: RANDOMIZED
• Intervention Model: PARALLEL
• Primary Study Purpose: TREATMENT
• Blinding Strategy: DOUBLE

Study Groups

Group A - CsA 0.1% - Ikervis (CSL Seqirus, Parkville, Victoria) once daily at night-time + Cationorm

Group Type: EXPERIMENTAL

0.1% Ciclosporin A eye drops

Intervention Type: DRUG

The active intervention arm has CsA 0.1% - Ikervis (CSL Seqirus, Parkville, Victoria) and mineral oils lubricating eye drops - Cationorm (CSL Seqirus, Parkville, Victoria)

Mineral oils eye drops

Intervention Type: DRUG

This arm is the comparator arm has mineral oils lubricating eye drops - Cationorm (CSL Seqirus, Parkville, Victoria)

Group B - Cationorm (CSL Seqirus, Parkville, Victoria) four times daily in both eyes for 12-weeks.

Group Type: ACTIVE_COMPARATOR

Mineral oils eye drops

Intervention Type: DRUG

This arm is the comparator arm has mineral oils lubricating eye drops - Cationorm (CSL Seqirus, Parkville, Victoria)

Interventions

0.1% Ciclosporin A eye drops

The active intervention arm has CsA 0.1% - Ikervis (CSL Seqirus, Parkville, Victoria) and mineral oils lubricating eye drops - Cationorm (CSL Seqirus, Parkville, Victoria)

Intervention Type: DRUG

Mineral oils eye drops

This arm is the comparator arm has mineral oils lubricating eye drops - Cationorm (CSL Seqirus, Parkville, Victoria)

Intervention Type: DRUG

Eligibility Criteria

Inclusion Criteria

1. 18 years of age and above

2. Participants should meet any two of the following DED diagnostic criteria: i) ocular surface disease index score of ≥23 and ii) Oxford staining score of ≥1 iii) Tear meniscus height < 0.2 mm.

Exclusion Criteria

1. Participants currently using or with previous use of steroids, ciclosporin, lifitegrast or any anti-inflammatory eye drops in the last 6 months.

2. Participants with systemic CsA or tacrolimus

3. Known hypersensitivity or contraindication to the study medication or any of its ingredients.

4. Active intraocular inflammation.

5. Contact lens wear or the use of contact lenses in the last 4 weeks.

6. Active eye infections or history of critical illness.

7. DED secondary to Steven-Johnson syndrome and cicatricial conjunctival disease.

8. Participants with other ocular co-morbidities and medications for glaucoma.

9. Participants with previous history of ocular surgery in the past 6 months.

10. Any other active or inactive systemic condition, structural abnormality such as eyelid malposition's that in the judgment of the investigator could confound study assessments or limit compliance.

11. Pregnant/breastfeeding women

• Minimum Eligible Age: 18 Years
• Eligible Sex: ALL
• Accepts Healthy Volunteers: No

Sponsors

University of Melbourne

OTHER

Sponsor Role: collaborator

The University of New South Wales

OTHER

Sponsor Role: lead

Responsible Party

Soumen Sadhu

Coordinating Investigator

Responsibility Role: PRINCIPAL_INVESTIGATOR

Principal Investigators

Fiona Stapleton Professor, PhD

Role: PRINCIPAL_INVESTIGATOR

The University of New South Wales

Locations

School of Optometry and Vision Science

Sudney, New South Wales, Australia

Countries

Australia

Central Contacts

Fiona Stapleton Professor, PhD

Role: CONTACT

f.stapleton@unsw.edu.au

+61 0418868234

Facility Contacts

Lisa Professor, PhD

Role: primary

l.keay@unsw.edu.au

+61 02 9385 4624

Other Identifiers

UNSW IIT Protocol 202412001

Identifier Type: -

Identifier Source: org_study_id