Morphological Analysis of Meibomian Glands

Meibomian Gland Dysfunction Clinical Trial

Official title:

Automated Morphological Analysis of Meibomian Glands

Clinical Trial Details — Status: Recruiting

Administrative data

• NCT number: NCT04052841
• Other study ID #: 20190722
• Status: Recruiting
• Phase: N/A
• Start date: October 12, 2020
• Est. completion date: December 1, 2023

Study information

• Verified date: April 2023
• Source: Zhongshan Ophthalmic Center, Sun Yat-sen University
• Contact: Yuqing Deng, MD
• Phone: 18120557291
• Email: 15927646647[@]163.com
• Is FDA regulated: No
• Study type: Interventional

Clinical Trial Summary

An automated quantitative meibomian gland analyzer based on all kinds of infrared meibomian gland images was develop to obtain more detail in meibomian gland, including width, length, area, signal intensity correlated to the quality of meibum, deformation index and ratio of area of each visible specific gland. The purpose of this study is present as separate sections the following points: (1) to compared the detailed characteristics of meibomian glands in normal subjects, Meibomian gland dysfunction (MGD) patients by the automated quantitative analyzer; (2) to identify the inter-examiner and intra-examiner repeatability of the new technique; (3) to explore the correlation among morphological and functional parameters of meibomian gland and risk factors，clinical symptoms and signs; (4) to explore the sensitivity and specificity of meibomian gland morphological and functional parameters in MGD diagnosis. (5) using morphological and functional parameters as new assessment of MGD severity and efficacy indicators for treatment.

Description:

Meibomian glands are essential for maintaining ocular surface health and integrity secrete various lipid components to forms a lipid layer to prevent excessive tear evaporation. Functional disorders of the meibomian glands, referred to today as meibomian gland dysfunction (MGD), are increasingly recognized as a high incidence disease commonly characterized by terminal duct obstruction and/or abnormal glandular secretion, often results in ocular surface epithelium damage, chronic blepharitis and dry eye disease that significantly reduces quality of life. A wide variation of the prevalence of MGD were reported from 0.39% to 69.3%, which is likely due to lack of diagnostic methods. To identify which clinical features are likely to be predictive of progressive disease in MGD may indicate the early diagnosis and proper treatment strategies. Histologic section through the normal meibomian glands and the obstructed human meibomian gland revealed that obstruction of orifice in MGD could lead to dilation of the central duct, damage of the secretory meibocytes and finally result in atrophy of dilated meibomian glands and glands drop-out. It was thus be accepted that detailed changes of meibomian glands morphology are key signs to diagnose and evaluate the severity of MGD. The detailed changes including dilation, distortion, shortening and loss of visualisation of glands which can be directly observed and visual assessment by the developed of non-contact meibomian gland infrared imaging technology. Quantitative evaluations of meibomian glands were obtain by developing imaging processing techniques. The most common use is the image editing software Image J (National Institute of Health; http://imagej.nih.gov/ij) which can identify the gland region on the image manually by the users and may lead to inter-observer variability. Koh et al., first applied original algorithms to automatically analysed gland loss in meibography images with a manually pre-processing. Reiko et al., then develop an objective and automatic system to measure the meibomian gland area. However, the existing methods of meibomian gland analysis have been limited to clinical use where large number of images needs to be analyzed efficiently due to the inter-observer variability or time-consuming process. Meanwhile, the existing quantitative morphological parameters obtain by those imaging processing techniques, including percentage of MG drop-out and gland atrophy area, were suggested to not only be advanced stages or terminal changes in MGD, but also occurs as an age-related atrophic process. The early findings of MGD induced by the primary pathologic obstruction including degenerative gland dilation, irregularly shapes of gland and change of meibum quality are still difficult to be evaluated automatically and quantitively from the image. Moreover, the meibomian gland drop-out is still an approximate assessment without specific pattern. Whether the atrophy or loss occur in upper or lower eyelids, central, distal or proximal, total loss of gland or partial loss of gland has the greatest effect on the pathology progress of MGD will be important to identify. Thus, a comprehensive analysis technique to automatically detect multi-information of meibomian gland morphology will benefit the future early diagnosis and management of MGD. Recently, an automated quantitative meibomian gland analyzer based on all kinds of infrared meibomian gland images was develop to obtain more detail in meibomian gland, including width, length, area, signal intensity correlated to the quality of meibum, deformation index and ratio of area of each visible specific gland. The purpose of this study is present as separate sections the following points: (1) to compared the detailed characteristics of meibomian glands in normal subjects and MGD patients by the automated quantitative analyzer; (2) to identify the inter-examiner and intra-examiner repeatability of the new technique; (3) to explore the correlation among morphological and functional parameters of meibomian gland and risk factors，clinical symptoms and signs; (4) to explore the sensitivity and specificity of meibomian gland morphological and functional parameters in MGD diagnosis. (5) using morphological and functional parameters as new assessment of MGD severity and efficacy indicators for treatment.

Recruitment information / eligibility

• Status: Recruiting
• Enrollment: 180
• Est. completion date: December 1, 2023
• Est. primary completion date: July 1, 2023
• Accepts healthy volunteers: Accepts Healthy Volunteers
• Gender: All
• Age group: 18 Years to 70 Years

Eligibility

General Inclusion Criteria:

• Age from 18 to 70 years.
• Patients and healthy volunteers who are willing and capable to participate in this clinical study with signed Informed Consent Form.

Inclusion Criteria of patients:

• Clinical diagnosis of MGD: The diagnosis of MGD was based on an altered quality of expressed secretions and/or decreased or absent expression.
• Patients without =2/3 Meibomian glands atrophy.
• Fitzpatrick skin type 1-4.

Inclusion Criteria of healthy volunteers:

• Negative history or condition of ocular or systemic illness based on evaluation by a research physician.

General Exclusion Criteria:

• Patients and healthy volunteers with ocular allergies, trauma, contact lens wear, continuous medications usage such as tretinoin, isotretinoin, antidepressant medications, photosensitive drugs, glucocorticoids and immunomodulators, or have used them within one month.
• Patients and healthy volunteers who have a history of ocular surface surgery.
• Patients and healthy volunteers who have active ocular surface infection or have suffered from ocular surface infection within one month.
• Patients and healthy volunteers who have endophthalmitis or a medical history of endophthalmitis.
• Patients and healthy volunteers who have a medical history of viral keratitis infection.
• Women who are pregnant, planning to become pregnant during the course of the study or breast-feeding (women of child-bearing age will be asked by the physician).
• Meibography images were blurred or with obvious tarsus folds, incomplete exposure and large hyperreflective area.
• Patients and healthy volunteers who are not suitable for the trial as determined by investigators.

Exclusion Criteria of patients:

• Patients have abnormalities of ocular surface function or eyelid function, or presence of precancerous lesions, cancer or pigmentation in the eyelid area.
• Patients who have plans to receive ocular surgeries (e.g., cataract, myopic refractive surgery) within 6 months.
• Patients who have been treated with lacrimal punctum embolization within one month.
• Patients with disease that could lead to ADDE, such as Sjogren syndrome and a lacrimal gland abnormality.

Related Conditions & MeSH terms

• Meibomian Gland Dysfunction

Intervention

Procedure:
• Thermal pulsation
Participants underwent a single LipiFlow® thermal pulsation system (TearScience Inc., Morrisville, NC,USA) treatment on the first visit: after lid hygiene with wet cotton swabs(OCuSOFT, Inc., Texas, USA) and instillation of anesthetic eye drops (Alcaine, proparacaine hydrochloride 0.4 ml/2mg) in both eyes, sterile eye cups were placed on to the conjunctival sac as instructed by the manufacturer, after 12 minutes of upper and lower palpebral conjunctival surfaces heat while simultaneously graded pulsatile pressure applying, eye cups were removed slightly.
• Intense pulsed light therapy
Lid hygiene with wet cotton swabs(OCuSOFT, Inc., Texas, USA) before treatment. Intense pulsed light (IPL) with a range of wavelength (570 or 620 nm) was performed every 3 weeks,3 times in total (0, 3w, 6w). 10 pulses were transmited from one tragus through nose to the other tragus was a single pass, each treatment needed to do 2 passes. Manual lid massage was done after per IPL treatment.
• Manual warm compresses
Lids hygiene of both eyes with wet cotton swabs(OCuSOFT, Inc., Texas, USA).Commercial heated eye patch was use for 10 min. Manual lid massage every 2 weeks, 5 times in total(0,2w, 4w, 4w, 8w).

Locations

Country	Name	City	State
China	Deng Yuqing	Guangzhou
China	Zhongshan Ophthalmic Center, Sun Yat-Sen University	Guangzhou	Guangdong

Sponsors (1)

Lead Sponsor	Collaborator
Zhongshan Ophthalmic Center, Sun Yat-sen University

Country where clinical trial is conducted

China, 

References & Publications (14)

Arita R, Itoh K, Maeda S, Maeda K, Furuta A, Fukuoka S, Tomidokoro A, Amano S. Proposed diagnostic criteria for obstructive meibomian gland dysfunction. Ophthalmology. 2009 Nov;116(11):2058-63.e1. doi: 10.1016/j.ophtha.2009.04.037. Epub 2009 Sep 10. — View Citation

Arita R, Suehiro J, Haraguchi T, Shirakawa R, Tokoro H, Amano S. Objective image analysis of the meibomian gland area. Br J Ophthalmol. 2014 Jun;98(6):746-55. doi: 10.1136/bjophthalmol-2012-303014. Epub 2013 Jun 27. — View Citation

Chia EM, Mitchell P, Rochtchina E, Lee AJ, Maroun R, Wang JJ. Prevalence and associations of dry eye syndrome in an older population: the Blue Mountains Eye Study. Clin Exp Ophthalmol. 2003 Jun;31(3):229-32. doi: 10.1046/j.1442-9071.2003.00634.x. — View Citation

Knop E, Knop N, Brewitt H, Pleyer U, Rieck P, Seitz B, Schirra F. [Meibomian glands : part III. Dysfunction - argument for a discrete disease entity and as an important cause of dry eye]. Ophthalmologe. 2009 Nov;106(11):966-79. doi: 10.1007/s00347-009-204 — View Citation

Knop E, Knop N, Millar T, Obata H, Sullivan DA. The international workshop on meibomian gland dysfunction: report of the subcommittee on anatomy, physiology, and pathophysiology of the meibomian gland. Invest Ophthalmol Vis Sci. 2011 Mar 30;52(4):1938-78. — View Citation

Koh YW, Celik T, Lee HK, Petznick A, Tong L. Detection of meibomian glands and classification of meibography images. J Biomed Opt. 2012 Aug;17(8):086008. doi: 10.1117/1.JBO.17.8.086008. — View Citation

Lekhanont K, Rojanaporn D, Chuck RS, Vongthongsri A. Prevalence of dry eye in Bangkok, Thailand. Cornea. 2006 Dec;25(10):1162-7. doi: 10.1097/01.ico.0000244875.92879.1a. — View Citation

Nelson JD, Shimazaki J, Benitez-del-Castillo JM, Craig JP, McCulley JP, Den S, Foulks GN. The international workshop on meibomian gland dysfunction: report of the definition and classification subcommittee. Invest Ophthalmol Vis Sci. 2011 Mar 30;52(4):193 — View Citation

Schaumberg DA, Sullivan DA, Buring JE, Dana MR. Prevalence of dry eye syndrome among US women. Am J Ophthalmol. 2003 Aug;136(2):318-26. doi: 10.1016/s0002-9394(03)00218-6. — View Citation

Schein OD, Munoz B, Tielsch JM, Bandeen-Roche K, West S. Prevalence of dry eye among the elderly. Am J Ophthalmol. 1997 Dec;124(6):723-8. doi: 10.1016/s0002-9394(14)71688-5. — View Citation

Simcock B. The role of the intrauterine device in contraceptive practice. Aust Fam Physician. 1976 Mar;5(2):124-39. — View Citation

Tomlinson A, Bron AJ, Korb DR, Amano S, Paugh JR, Pearce EI, Yee R, Yokoi N, Arita R, Dogru M. The international workshop on meibomian gland dysfunction: report of the diagnosis subcommittee. Invest Ophthalmol Vis Sci. 2011 Mar 30;52(4):2006-49. doi: 10.1 — View Citation

Uchino M, Dogru M, Yagi Y, Goto E, Tomita M, Kon T, Saiki M, Matsumoto Y, Uchino Y, Yokoi N, Kinoshita S, Tsubota K. The features of dry eye disease in a Japanese elderly population. Optom Vis Sci. 2006 Nov;83(11):797-802. doi: 10.1097/01.opx.0000232814.3 — View Citation

Wise RJ, Sobel RK, Allen RC. Meibography: A review of techniques and technologies. Saudi J Ophthalmol. 2012 Oct;26(4):349-56. doi: 10.1016/j.sjopt.2012.08.007. — View Citation

* Note: There are 14 references in all — Click here to view all references

Outcome

Type	Measure	Description	Time frame	Safety issue
Primary	Mophology of meibomian glands	Infrared photography of inversed upper meibomian glands were measured by Meibography pattern of Keratograph 5M (Oculus, Wetzlar, Germany). The infrared images of Meibography were analysed using the new developed software for identifying the mophology features of meibomian glands in millimeter.	30 days after commencement of treatment
Primary	Functional feature of meibomian glands	Infrared photography of inversed upper and lower meibomian glands were measured by Meibography pattern of Keratograph 5M (Oculus, Wetzlar, Germany). The infrared images of Meibography were analysed using the new developed software for identifying the mean signal intensity of meibomian glands in millimeter.	30 days after commencement of treatment
Secondary	Non-invasive tear-film break-up time	Non-invasived tear-film break-up time is measured by tear film pattern of Keratograph 5M (Oculus, Wetzlar, Germany) with a scale of seconds. Higher values represent a better outcome	Baseline
Secondary	Non-invasive tear-film break-up time	Non-invasived tear-film break-up time is measured by tear film pattern of Keratograph 5M (Oculus, Wetzlar, Germany) with a scale of seconds. Higher values represent a better outcome	15 days after commencement of treatment
Secondary	Non-invasive tear-film break-up time	Non-invasived tear-film break-up time is measured by tear film pattern of Keratograph 5M (Oculus, Wetzlar, Germany) with a scale of seconds. Higher values represent a better outcome	30 days after commencement of treatment
Secondary	Non-invasive tear-film break-up time	Non-invasived tear-film break-up time is measured by tear film pattern of Keratograph 5M (Oculus, Wetzlar, Germany) with a scale of seconds. Higher values represent a better outcome	90 days after commencement of treatment
Secondary	Non-invasive tear-film break-up time	Non-invasived tear-film break-up time is measured by tear film pattern of Keratograph 5M (Oculus, Wetzlar, Germany) with a scale of seconds. Higher values represent a better outcome	180 days after commencement of treatment
Secondary	Non-invasive tear meniscus height	Non-invasived tear meniscus height is measured by tear film pattern of Keratograph 5M (Oculus, Wetzlar, Germany) in millimeter. The value higher than 0.20 mm was provided as a normal condition of tear secretion.	Baseline
Secondary	Non-invasive tear meniscus height	Non-invasived tear meniscus height is measured by tear film pattern of Keratograph 5M (Oculus, Wetzlar, Germany) in millimeter. The value higher than 0.20 mm was provided as a normal condition of tear secretion.	15 days after commencement of treatment
Secondary	Non-invasive tear meniscus height	Non-invasived tear meniscus height is measured by tear film pattern of Keratograph 5M (Oculus, Wetzlar, Germany) in millimeter. The value higher than 0.20 mm was provided as a normal condition of tear secretion.	30 days after commencement of treatment
Secondary	Non-invasive tear meniscus height	Non-invasived tear meniscus height is measured by tear film pattern of Keratograph 5M (Oculus, Wetzlar, Germany) in millimeter. The value higher than 0.20 mm was provided as a normal condition of tear secretion.	90 days after commencement of treatment
Secondary	Non-invasive tear meniscus height	Non-invasived tear meniscus height is measured by tear film pattern of Keratograph 5M (Oculus, Wetzlar, Germany) in millimeter. The value higher than 0.20 mm was provided as a normal condition of tear secretion.	180 days after commencement of treatment
Secondary	Tear film lipid layer thicknesses	Tear film lipid layer thicknesses were averaged in nanometer(0-100nm) during 20 seconds by LipiView II (Tear Science, Morrisville, NC).	Baseline
Secondary	Tear film lipid layer thicknesses	Tear film lipid layer thicknesses were averaged in nanometer(0-100nm) during 20 seconds by LipiView II (Tear Science, Morrisville, NC).	15 days after commencement of treatment
Secondary	Tear film lipid layer thicknesses	Tear film lipid layer thicknesses were averaged in nanometer(0-100nm) during 20 seconds by LipiView II (Tear Science, Morrisville, NC).	30 days after commencement of treatment
Secondary	Tear film lipid layer thicknesses	Tear film lipid layer thicknesses were averaged in nanometer(0-100nm) during 20 seconds by LipiView II (Tear Science, Morrisville, NC).	90 days after commencement of treatment
Secondary	Tear film lipid layer thicknesses	Tear film lipid layer thicknesses were averaged in nanometer(0-100nm) during 20 seconds by LipiView II (Tear Science, Morrisville, NC).	180 days after commencement of treatment
Secondary	The pattern of eye blinks	The pattern of eye blinks including numbers of incompleted and completed blinks during 20 seconds were measured by LipiView II (Tear Science, Morrisville, NC).	Baseline
Secondary	The pattern of eye blinks	Tear film lipid layer thicknesses and numbers of incomplete blinks during 20 seconds were measured by LipiView II (Tear Science, Morrisville, NC).	15 days after commencement of treatment
Secondary	The pattern of eye blinks	Tear film lipid layer thicknesses and numbers of incomplete blinks during 20 seconds were measured by LipiView II (Tear Science, Morrisville, NC).	30 days after commencement of treatment
Secondary	The pattern of eye blinks	Tear film lipid layer thicknesses and numbers of incomplete blinks during 20 seconds were measured by LipiView II (Tear Science, Morrisville, NC).	90 days after commencement of treatment
Secondary	The pattern of eye blinks	Tear film lipid layer thicknesses and numbers of incomplete blinks during 20 seconds were measured by LipiView II (Tear Science, Morrisville, NC).	180 days after commencement of treatment
Secondary	Lid margin signs	Three lid margin abnormalities (irregular lid margin, plugging of meibomian gland orifices, and anterior or posterior replacement of the mucocutaneous junction) were scored from 0 through 4 according to the number of these abnormalities that were present in each eye. Higher scores represent a worse outcome.	baseline
Secondary	Lid margin signs	Three lid margin abnormalities (irregular lid margin, plugging of meibomian gland orifices, and anterior or posterior replacement of the mucocutaneous junction) were scored from 0 through 4 according to the number of these abnormalities that were present in each eye. Higher scores represent a worse outcome.	15 days after commencement of treatment
Secondary	Lid margin signs	Three lid margin abnormalities (irregular lid margin, plugging of meibomian gland orifices, and anterior or posterior replacement of the mucocutaneous junction) were scored from 0 through 4 according to the number of these abnormalities that were present in each eye. Higher scores represent a worse outcome.	30 days after commencement of treatment
Secondary	Lid margin signs	Three lid margin abnormalities (irregular lid margin, plugging of meibomian gland orifices, and anterior or posterior replacement of the mucocutaneous junction) were scored from 0 through 4 according to the number of these abnormalities that were present in each eye. Higher scores represent a worse outcome.	90 days after commencement of treatment
Secondary	Lid margin signs	Three lid margin abnormalities (irregular lid margin, plugging of meibomian gland orifices, and anterior or posterior replacement of the mucocutaneous junction) were scored from 0 through 4 according to the number of these abnormalities that were present in each eye. Higher scores represent a worse outcome.	180 days after commencement of treatment
Secondary	Meibum expressibility	Meibum expressibility were measured by firm digital pressure of Meibomian gland diagnostic Expressibility (Tear Sience, Morrisville, NC): For each of these glands, the secretion was graded as follows: 0:no secretion; 1: inspissated/ toothpaste consistency; 2: cloudy liquid secretion and 3: clear liquid secretion19. The scores were then summed in 15 glands to a single meibomian gland yield secretion score (MGYSS) with a range from 0 to 45. Higher values represent a better outcome.	baseline
Secondary	Meibum expressibility	Meibum expressibility were measured by firm digital pressure of Meibomian gland diagnostic Expressibility (Tear Sience, Morrisville, NC): For each of these glands, the secretion was graded as follows: 0:no secretion; 1: inspissated/ toothpaste consistency; 2: cloudy liquid secretion and 3: clear liquid secretion19. The scores were then summed in 15 glands to a single meibomian gland yield secretion score (MGYSS) with a range from 0 to 45. Higher values represent a better outcome.	15 days after commencement of treatment
Secondary	Meibum expressibility	Meibum expressibility were measured by firm digital pressure of Meibomian gland diagnostic Expressibility (Tear Sience, Morrisville, NC): For each of these glands, the secretion was graded as follows: 0:no secretion; 1: inspissated/ toothpaste consistency; 2: cloudy liquid secretion and 3: clear liquid secretion19. The scores were then summed in 15 glands to a single meibomian gland yield secretion score (MGYSS) with a range from 0 to 45. Higher values represent a better outcome.	30 days after commencement of treatment
Secondary	Meibum expressibility	Meibum expressibility were measured by firm digital pressure of Meibomian gland diagnostic Expressibility (Tear Sience, Morrisville, NC): For each of these glands, the secretion was graded as follows: 0:no secretion; 1: inspissated/ toothpaste consistency; 2: cloudy liquid secretion and 3: clear liquid secretion19. The scores were then summed in 15 glands to a single meibomian gland yield secretion score (MGYSS) with a range from 0 to 45. Higher values represent a better outcome.	90 days after commencement of treatment
Secondary	Meibum expressibility	Meibum expressibility were measured by firm digital pressure of Meibomian gland diagnostic Expressibility (Tear Sience, Morrisville, NC): For each of these glands, the secretion was graded as follows: 0:no secretion; 1: inspissated/ toothpaste consistency; 2: cloudy liquid secretion and 3: clear liquid secretion19. The scores were then summed in 15 glands to a single meibomian gland yield secretion score (MGYSS) with a range from 0 to 45. Higher values represent a better outcome.	180 days after commencement of treatment
Secondary	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 (0-3 scale for each area of 5 areas, total score 15). Higher values represent a worse outcome.	baseline
Secondary	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 (0-3 scale for each area of 5 areas, total score 15). Higher values represent a worse outcome.	15 days after commencement of treatment
Secondary	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 (0-3 scale for each area of 5 areas, total score 15). Higher values represent a worse outcome.	30 days after commencement of treatment
Secondary	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 (0-3 scale for each area of 5 areas, total score 15). Higher values represent a worse outcome.	90 days after commencement of treatment
Secondary	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 (0-3 scale for each area of 5 areas, total score 15). Higher values represent a worse outcome.	180 days after commencement of treatment
Secondary	Schirmer I test	The tear production was measured with Schirmer strips without anaesthesia 15 minutes after corneal staining.	baseline
Secondary	Schirmer I test	The tear production was measured with Schirmer strips without anaesthesia 15 minutes after corneal staining.	15 days after commencement of treatment
Secondary	Schirmer I test	The tear production was measured with Schirmer strips without anaesthesia 15 minutes after corneal staining.	30 days after commencement of treatment
Secondary	Schirmer I test	The tear production was measured with Schirmer strips without anaesthesia 15 minutes after corneal staining.	90 days after commencement of treatment
Secondary	Schirmer I test	The tear production was measured with Schirmer strips without anaesthesia 15 minutes after corneal staining.	180 days after commencement of treatment
Secondary	Mophology of meibomian glands	Infrared photography of inversed upper meibomian glands were measured by Meibography pattern of Keratograph 5M (Oculus, Wetzlar, Germany). The infrared images of Meibography were analysed using the new developed software for identifying the mophology features of meibomian glands in millimeter.	15 days after commencement of treatment
Secondary	Mophology of meibomian glands	Infrared photography of inversed upper meibomian glands were measured by Meibography pattern of Keratograph 5M (Oculus, Wetzlar, Germany). The infrared images of Meibography were analysed using the new developed software for identifying the mophology features of meibomian glands in millimeter.	90 days after commencement of treatment
Secondary	Mophology of meibomian glands	Infrared photography of inversed upper meibomian glands were measured by Meibography pattern of Keratograph 5M (Oculus, Wetzlar, Germany). The infrared images of Meibography were analysed using the new developed software for identifying the mophology features of meibomian glands in millimeter.	180 days after commencement of treatment
Secondary	Mophology of meibomian glands	Infrared photography of inversed upper meibomian glands were measured by Meibography pattern of Keratograph 5M (Oculus, Wetzlar, Germany). The infrared images of Meibography were analysed using the new developed software for identifying the mophology features of meibomian glands in millimeter.	Baseline
Secondary	Functional feature of meibomian glands	Infrared photography of inversed upper and lower meibomian glands were measured by Meibography pattern of Keratograph 5M (Oculus, Wetzlar, Germany). The infrared images of Meibography were analysed using the new developed software for identifying the mean signal intensity of meibomian glands in millimeter.	Baseline
Secondary	Functional feature of meibomian glands	Infrared photography of inversed upper and lower meibomian glands were measured by Meibography pattern of Keratograph 5M (Oculus, Wetzlar, Germany). The infrared images of Meibography were analysed using the new developed software for identifying the mean signal intensity of meibomian glands in millimeter.	15 days after commencement of treatment
Secondary	Functional feature of meibomian glands	Infrared photography of inversed upper and lower meibomian glands were measured by Meibography pattern of Keratograph 5M (Oculus, Wetzlar, Germany). The infrared images of Meibography were analysed using the new developed software for identifying the mean signal intensity of meibomian glands in millimeter.	90 days after commencement of treatment
Secondary	Functional feature of meibomian glands	Infrared photography of inversed upper and lower meibomian glands were measured by Meibography pattern of Keratograph 5M (Oculus, Wetzlar, Germany). The infrared images of Meibography were analysed using the new developed software for identifying the mean signal intensity of meibomian glands in millimeter.	180 days after commencement of treatment