Dry eye disease (DED), as one of the most common ocular surface diseases that affecting visual acuity, is highly associated with ocular surface inflammation. Until now, there is no accurate quantization index system to evaluate real-time ocular surface inflammation. Besides, an individualized therapy for ocular surface inflammation is also badly needed. As we all know, conjunctival congestion is one of the important clinical appearance of ocular surface inflammation. Hence, we suggest that several specific microvascular indexes could measure the change of ocular surface inflammation. Our program is aiming to investigate the correlation between inflammatory factors and blood flow velocity as well as microvascular distribution detecting from bulbar conjunctiva through our own devices and software.Futhermore, we tend to compare ocular surface microvascular indexes and microvascular distribution in normal people and dry eye patients in order to establish a database for Chinese people. By confirming the relationship between ocular surface microvascular indexes and ocular inflammation, we hope to set up new diagnostic criteria for ocular inflammation and an individualized therapeutic regimen based on ocular surface microvascular indexes. Finally, we want to establish a precision diagnostic and therapeutic pattern for dry eye disease.
Dry eye (DE) is a growing public health concern that affects not only the visual function but also the quality of life of patients. In 2017, the International DE Study Workshop (DEWSII) adjusted the definition of DE by particularly emphasizing the inflammation in the ocular surface, and this adjustment represented a major shift in the understanding of dry eye disease (DED) pathogenesis and the facilitation of DED treatment.1,2 The recurrence of chronic and low-grade inflammation plays an important role in long-term disease progression and gradually deteriorates the ocular surface.3 Previous studies have concluded that the inflammatory response is involved in the pathological process of DE.4-7 The concentrations of IL-1α and mature IL-1ß in the tear fluid are increased.4,5 The activity of MMP-9, a suggested biomarker associated with ocular surface diseases including DE, is significantly elevated in Meibomian gland dysfunction (MGD), Sjögren's syndrome (SS) and aqueous tear deficiency (ATD).6 Other studies have indicated that inflammatory mediators such as IL-6, IL-8 and TNFα are expressed proportionally to the severity of DE symptoms, indicating the involvement of inflammation.7 The identification of inflammation as a major factor in DE informs the treatment strategy, including anti-inflammatory medication, which results in improvements to the ocular surface condition and to ocular comfort in DED patients.8,9 A series of studies have demonstrated improvements in the subjective and objective signs and symptoms of DE after anti-inflammatory and immunomodulatory therapies.8-11 To monitor the status of ocular surface inflammation and the ocular surface condition, traditional assessments, namely, evaluation of conjunctival hyperemia12 and corneal fluorescein staining using a slit lamp biomicroscope, are used. However, these methods are subjective and volatile and may not be sensitive indicators of the disease stage and treatment efficacy.13 A number of new tests have been used to distinguish inflammation.13-15 These new technologies include corneal confocal microscopy,15 conjunctival impression cytology16 and inflammatory tear-film cytokine tests in research and in the clinic.17 These newly implemented techniques have several limitations. Corneal confocal microscopy is a structure-based instrument with a narrow view of 400 × 400 µm2 that is limited to localization and cell counting. Conjunctival impression cytology16 and inflammatory tear-film cytokine tests19 are not routinely used, possibly due to the invasiveness, high cost and discomfort of these techniques.5,18 Therefore, the development of new methodologies to noninvasively and subjectively evaluate the inflammation status of the ocular surface is crucial. The microvascular system of the bulbar conjunctiva can be easily accessed. The release of inflammatory cytokines on the ocular surface can cause vasodilation, which may result in alterations to the conjunctival microcirculation.19 Cheung et al. used a computer-assisted intravital microscope to evaluate vasculopathies of the conjunctival vessels and identified microvascular abnormalities in patients with diabetes20 and in patients who wore contact lens.21 Schulze et al. have also performed 'evaluations of the redness of the bulbar conjunctiva using fractal analysis and photometry.22 However, these studies did not directly measure the microcirculation. The microcirculation is an important aspect of the vascular system, may directly represent the hemodynamic response to ocular surface inflammation and may exhibit more sensitivity for monitoring vascular responses to anti-inflammatory treatment. Recently, Jiang et al. developed a functional slit-lamp biomicroscope that could be used to measure the conjunctival blood flow velocity (BFV) and vessel diameter.23 The goal of the present study was to characterize the microvasculature and microcirculation in the bulbar conjunctiva of DE patients in response to anti-inflammatory treatment.
Study Type
INTERVENTIONAL
Allocation
NON_RANDOMIZED
Purpose
HEALTH_SERVICES_RESEARCH
Masking
NONE
Enrollment
20
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A traditional slit lamp (HAAG-STREIT SWISS MADE 900.7.2.34925) was used, and a digital camera (Canon 60D. Canon Inc, Melville, NY) was attached via an inherent camera port. Custom software was used to measure the conjunctival microvascular BFV and vessel diameter using a protocol that has been previously described in detail. At baseline, video clips were recorded on six fields of the bulbar conjunctiva, which was approximately 1 mm from the limbus. During the follow-up visits, attention was given to relocating the vessel segments for these 6 fields.
Wan Chen
Guangzhou, Guangdong, China
RECRUITINGConjunctival microvascular blood flow velocity
Acheived by a traditional slit lamp (HAAG-STREIT SWISS MADE 900.7.2.34925) with a digital camera (Canon 60D. Canon Inc, Melville, NY) and a custom software.
Time frame: Baseline
Conjunctival microvascular blood flow velocity
Acheived by a traditional slit lamp (HAAG-STREIT SWISS MADE 900.7.2.34925) with a digital camera (Canon 60D. Canon Inc, Melville, NY) and a custom software.
Time frame: 30 days after commencement of treatment
Conjunctival microvascular blood flow velocity
Acheived by a traditional slit lamp (HAAG-STREIT SWISS MADE 900.7.2.34925) with a digital camera (Canon 60D. Canon Inc, Melville, NY) and a custom software.
Time frame: 60 days after commencement of treatment
Conjunctival microvascular diameter
Acheived by a traditional slit lamp (HAAG-STREIT SWISS MADE 900.7.2.34925) with a digital camera (Canon 60D. Canon Inc, Melville, NY) and a custom software.
Time frame: Baseline
Conjunctival microvascular diameter
Acheived by a traditional slit lamp (HAAG-STREIT SWISS MADE 900.7.2.34925) with a digital camera (Canon 60D. Canon Inc, Melville, NY) and a custom software.
Time frame: 30 days after commencement of treatment
Conjunctival microvascular diameter
Acheived by a traditional slit lamp (HAAG-STREIT SWISS MADE 900.7.2.34925) with a digital camera (Canon 60D. Canon Inc, Melville, NY) and a custom software.
Time frame: 60 days after commencement of treatment
Conjunctival microvascular blood flow rate
Acheived by a traditional slit lamp (HAAG-STREIT SWISS MADE 900.7.2.34925) with a digital camera (Canon 60D. Canon Inc, Melville, NY) and a custom software.
Time frame: Baseline
Conjunctival microvascular blood flow rate
Acheived by a traditional slit lamp (HAAG-STREIT SWISS MADE 900.7.2.34925) with a digital camera (Canon 60D. Canon Inc, Melville, NY) and a custom software.
Time frame: 30 days after commencement of treatment
Conjunctival microvascular blood flow rate
Acheived by a traditional slit lamp (HAAG-STREIT SWISS MADE 900.7.2.34925) with a digital camera (Canon 60D. Canon Inc, Melville, NY) and a custom software.
Time frame: 60 days after commencement of treatment
The hyperemia index
The hyperemia index (HI) was measured by determining the percentage of conjunctival microvascular area in the conjunctiva automatically.26 The subjects were required to keep their eyes open and focus on the illuminated ring in front. Three consecutive readings were recorded, and the median was used. All data were recorded and analyzed with TF-scan software in the system.
Time frame: Baseline
The hyperemia index
The hyperemia index (HI) was measured by determining the percentage of conjunctival microvascular area in the conjunctiva automatically.26 The subjects were required to keep their eyes open and focus on the illuminated ring in front. Three consecutive readings were recorded, and the median was used. All data were recorded and analyzed with TF-scan software in the system.
Time frame: 30 days after commencement of treatment
The hyperemia index
The hyperemia index (HI) was measured by determining the percentage of conjunctival microvascular area in the conjunctiva automatically.26 The subjects were required to keep their eyes open and focus on the illuminated ring in front. Three consecutive readings were recorded, and the median was used. All data were recorded and analyzed with TF-scan software in the system.
Time frame: 60 days after commencement of treatment
Non-invasived tear-film break-up time
The system measures the tear-film break-up time (NI-BUT) by monitoring the Placido projection on the cornea and includes the noninvasive first tear-film break-up time (NI-fBUT) and NI-avBUT. NI-fBUT and NI-avBUT were the measured times of the first and half-area breaks in the tear film between the full opening of the eyelids after 2 complete blinks.
Time frame: Baseline
Non-invasived tear-film break-up time
The system measures the tear-film break-up time (NI-BUT) by monitoring the Placido projection on the cornea and includes the noninvasive first tear-film break-up time (NI-fBUT) and NI-avBUT. NI-fBUT and NI-avBUT were the measured times of the first and half-area breaks in the tear film between the full opening of the eyelids after 2 complete blinks.
Time frame: 30 days after commencement of treatment
Non-invasived tear-film break-up time
The system measures the tear-film break-up time (NI-BUT) by monitoring the Placido projection on the cornea and includes the noninvasive first tear-film break-up time (NI-fBUT) and NI-avBUT. NI-fBUT and NI-avBUT were the measured times of the first and half-area breaks in the tear film between the full opening of the eyelids after 2 complete blinks.
Time frame: 60 days after commencement of treatment
Corneal Fluorescein Staining
Fluorescein was administered into the conjunctival sac under a cobalt blue light from the slit lamp. Corneal epithelial cell disruption was measured via corneal staining (National Eye Institute (NEI) scale, 5 areas of the cornea assessed (central, temporal, nasal, superior, and inferior), and the scores were assigned per a 0-8 scale for each area (total 40). Tear production was measured with Schirmer strips without anesthesia.
Time frame: Baseline
Corneal Fluorescein Staining
Fluorescein was administered into the conjunctival sac under a cobalt blue light from the slit lamp. Corneal epithelial cell disruption was measured via corneal staining (National Eye Institute (NEI) scale, 5 areas of the cornea assessed (central, temporal, nasal, superior, and inferior), and the scores were assigned per a 0-8 scale for each area (total 40). Tear production was measured with Schirmer strips without anesthesia.
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Time frame: 30 days after commencement of treatment
Corneal Fluorescein Staining
Fluorescein was administered into the conjunctival sac under a cobalt blue light from the slit lamp. Corneal epithelial cell disruption was measured via corneal staining (National Eye Institute (NEI) scale, 5 areas of the cornea assessed (central, temporal, nasal, superior, and inferior), and the scores were assigned per a 0-8 scale for each area (total 40). Tear production was measured with Schirmer strips without anesthesia.
Time frame: 60 days after commencement of treatment
Schirmer I test
A meansurement of tear production with Schirmer strips and anaesthesia.
Time frame: Baseline
Schirmer I test
A meansurement of tear production with Schirmer strips and anaesthesia.
Time frame: 30 days after commencement of treatment
Schirmer I test
A meansurement of tear production with Schirmer strips and anaesthesia.
Time frame: 60 days after commencement of treatment