Rear 4-minute Schirmer Test, A Modified Indicator of Schirmer Test in Diagnosing Dry Eye

DOI: https://doi.org/10.21203/rs.3.rs-744613/v1

Abstract

This study was desgined to find a reliable and convenient indicator (a modified Schirmer test) to improve the accuracy of assessing tear secretion and diagnosing dry eye. This is a prospective continuous study on 180 volunteers. Schirmer test I without anesthesia was performed once on both eyes to determine the value of normal Schirmer test. The values of tear secretion were recorded in each minute. Examined individuals also underwent other examinations: the standard patient evaluation of eye dryness (SPEED), the Ocular Surface Disease Index (OSDI), fluorescein stain, tear film breakup time (BUT), and Meibomian gland (MG)grading. The participants were divided into two groups: dry eye (DE) groupand non-dry eye (ND) group. The mean age was 39.41±14.05 years in DE group and 37.62±13.17 in ND group. The value of  2-minute Schirmer test, rear 3-minute Schirmer test, rear 4-minute Schirmer test and 5-minute Schirmer test was 5.36±4.63, 5.57±2.11, 7.21±4.13 and 10.93±6.30 respectively in DE group. And these indicators was 8.25±6.80, 2.73±2.31, 7.36±3.42, 11.84±6.16 in ND group. The rear 4-minute ST has significant correlation with OSDI and SPEED in DE group (r =-0.242/-0.183) and in ND gruop(r =-0.316 /-0.373). Meanwhile, rear 4-minute ST had stronger connection with fBUT(r =0.159) and MG (r =-0.162) in DE gruop. And rear 4-minute ST also had higher accuracy in diagnosing severe dry eye and borderline dry eye.The rear 4-minute Schirmer test may be a supplement indicator in  assessing tear secretion and diagnosing dry eye.

Introduction

Dry eye(DE) is a common disorder in ocular surface and now the number of the patients is increased rapidly. The incidence of DE varies from 5% to 35% 1-2 due to geographical and ethnic differences. There are about 30 million persons with DE in the world 3. According the International Dry Eye Workshop in 2017, DE is defined as “a multifactorial disease of the ocular surface characterized by a loss of homeostasis of the tear film, and accompanied by ocular symptoms, in which tear film instability and hyperosmolarity, ocular surface inflammation and damage, and neurosensory abnormalities play etiological roles”4.

    The stable tear film has been considered as the key to healthy ocular surface because it can protect the lubricated environment for eyes 5. When tear film becomes abnormal, patients often have the six main symptoms: dry, gritty or sandy, burn, appear red, crust forms on lashes and eyelids stick shut in the morning 6. The assessment of people’s feelings is a major component for the diagnosis of DE. However, it’s unfortunate that signs of the disease do not always correlate with symptoms. In that case, we need objective ocular examinations. The most common diagnostic tests include Schirmer test (ST) 7-8, tear breakup time (BUT) 4, corneal fluorescein staining (CFS) 9, tear meniscus height 10.

    ST was used diagnostic test for dry eye syndrome in 1903 and it can help to evaluate the tear volume 11. In clinical practice, a special filter paper is placed at the middle and lateral thirds of the lower fornix with or without anesthetic 8. After 5 minutes, the tear secretion of person can be measured by the wetting paper. ST is always performed just one time in clinical practice. However, ST has several serious disadvantages such as discomfort, irritation, low reproducibility, requiring long time and inconvenience 12-13. Because of these limitations, many efforts were made to improve the ST’s efficiency and comfort, just like to be performed this test after using anesthesia or changing the filter paper 14. But these changes may not make significant improvements. With anesthesia, a reflex component was still alive and it may mislead physician to judge the situation of examinee. We set out this research for increasing the applicability and convenience of ST. Our purpose was to find a reliable and convenient way about ST which is more connected with the symptom of DE and help ophthalmologists diagnose DE.

Materials And Methods

1. Subjects

    This prospective study was performed at the outpatient clinic of the Second Affiliated Hospital of Zhejiang University School of Medicine in September of 2019. All subjects were divided as DE groups and non-dry eye (ND) groups. The criteria of DE diagnosis was OSDI higher than 13 points and fBUT shorter than 10 seconds and non-dry eye diagnosis was OSDI was not higher than 13 points or fBUT were not shorter than 10 seconds. The exclusion criteria were subjects who were under 18 years old and pregnancy, with eye allergies, conjunctival inflammation, corneal ulcer, eyelid inflammation, palsy, valgus and other ocular lesions, history of wearing contact lenses within 30 days, history of intraocular operation within 6 months, severe blepharitis, or severe systemic disease. This study followed the tenets of the Declaration of Helsinki and was approved by the Ethics Committee of the Second Affiliated Hospital of Zhejiang University School of Medicine(NO. 2019-307). All individuals who agreed to enter this study provided written informed consent after explanation of the nature and possible consequences of the study.

2. Dry eye symptom questionnaires

2.1. The ocular surface disease index(OSDI) 

     The ocular surface disease index (OSDI) was a validated dry eye questionnaire that can measure the severity of DE, symptoms, functional problems, and environmental triggers queried for the past week 15. Each answer of OSDI in 12 questions was graded on a scale of 0-4. A total OSDI scores ranged from 0-100. 

2.2. The standard patient evaluation of eye dryness (SPEED) questionnaire 

     The standard patient evaluation of eye dryness (SPEED) questionnaire was administered to grade the level of dry eye symptomology 16. The assessment standard of the SPEED questionnaire is derived by summing the scores from the frequency and severity parts of the questionnaire of 3 months. The value for each part of the frequency and severity questions in the SPEED questionnaire were obtained by summing the 0–4 scores of each of the 8 items and the total SPEED scores ranged from 0–28.

3. Dry eye symptom examinations

3.1. Schirmer test I

Schirmer test (ST) was performed once without topical anesthesia. In each test, both eyes were tested at the same time. The filter paper (Showa Yakuhin Kako Co, Ltd, Tokyo, Japan) was folded and placed between the lower eyelid and the globe at the junction between the middle and lateral thirds of the eyelid. The participants were asked to close their eyes, as since ST with close eyes may be more reliable in DE 17. The test lasted 5 minutes and the length of wetted paper was directly read off the scale on the paper. Wetting was measured in eyes at 1, 2, 3, 4, and 5 minutes. The participants were excluded from the study if any of the scores exceeded 30 mm (the whole paper was wetted) because of inability to give an exact measurement of the amount of wetting. Results were interpreted as follows: ≤5 mm as severe dry eye, ≤10 mm as borderline dry eye and >10 mm as normal tear secretion 18. We observed multiple indicators of Schirmer test as following: 

1.ST1: the value of normal Schirmer test. 

2.2-minute ST: the value of first 2 minutes of Schirmer test.

3.rear 3- minute ST: the value that five minute's value subtracting first two minutes of ST

4.rear 4-minute ST: the value that five minute's value subtracting first minute of ST

3.2. tear film breakup time(BUT) 

     Tear film instability was assessed using BUT measurements, which were obtained using the following method. TBUT test include fluorescein tear film break-up time (fBUT) and noninvasive tear film break up time (NIBUT). fBUT: Fluorescein was added to the tear film for both eyes and patients were asked to blink several times to ensure that it was uniformly distributed across their eyes. The time from the last blink of the eye to the first dry spot on the tear film was measured. Three consecutive measurements were made and recorded. The average values of three measurements were recorded. NIBUT: NIBUT were measured by Keratograph 5M (Oculus Optikgerate GmbH, Wetzlar, Germany). The examinee should place the lower jaw on the jaw rest and keep both eyes open. After successful focusing, examinee should blink 2 times and look at the red point in the center, keeping the eye open as much as possible until the next blink. Then the device can automatically detect the tear film distribution map and displays the measured value. The results of the BUT measurements were categorized as moderate (5–10s) or severe (<5s) 19-20.

3.3. Meibomian gland grading (MG grading)

     The quality of the Meibomian gland dropout was briefly assessed using a Meibomian Gland Evaluator (TearScience, Morrisville, NC, United States). A total of 15 Meibomian glands (in the nasal, middle, and temporal parts of the lower tarsus, respectively) were selected. The quality of Meibomian dropout was graded as follows: 0, clear fluid; 1, thick and cloudy dropout; 2, inspissated and congealed dropout with the consistency of toothpaste; 3, none present. The total scores ranged from 0–45.

3.4. Corneal fluorescein staining score(CFS)

   Corneal fluorescein staining score assessment was used to stain the patients’ corneas in this study. The cornea was divided equally into five quadrants of and the score for each quadrant was recorded after fluorescein staining, as follows: 0, no punctate staining; 1, less than 30 stained points; 2, more than 30 stained points but no fusion; 3, entirely stained with fusion. A total score of five part was given as 0–15.

 4. Statistics

    All statistical analyses were performed using SPSS software (version 24, IBM, Armonk, NY, United States) for Mac. The chi-square test and Pearson’s rank-order correlation were used to identify the correlation between ST, BUT, OSDI, SPEED, MG grading and CFS. An independent sample t-test was used to compare the parameters of the ST indicators. One- way ANOVA test was uesd to compare the values of indicators in two groups. Figures were created by SPSS and GraphPad Prism, version 8 (San Diego, CA). Descriptive statistics were summarized as mean ± standard deviation (SD).A p-value < 0.05 was considered statistically significant.

Results

1.Participants Demographics and Baseline characteristics

A total of  360 eyes of 180 Chinese persons were included in this study. The 120 participants were diagnosed as DE, while 60 participants were not in the situation of DE. Table 1 shows the baseline characteristics of the subjects. The objective examinations results of NIBUT, fBUT, MG grading and CFS in DE group were 4.70±2.28, 3.69±2.22, 22.51±11.68 and 0.88±0.25, respectively. And the results in ND group were 8.43±3.31, 4.22±2.20, 16.32±9.60 and 0.35±0.06, respectively. The socres of OSDI and SPEED were 30.12±12.91, 12.59±4.63 in patients and 6.62±3.35, 5.27±2.87 in ND group. No age significant difference was detected between DE and ND group. Other dry eye related indicators had significant difference between two groups (p<0.01).

2. Schirmer Test and dry eye group

2.1 Comparsion among the different value of schemer test 

     In this study, the participants were asked to performed one time ST and varies ST indicators were compared. These indiactors were diffrent statistically with each other in both groups. Figure 1 summarizes four indicators of ST in DE gruop. The value of ST1, 2-minute ST, rear 3 minutes ST and rear 4 minutes ST was 10.93±6.30, 5.36±4.63, 5.57±2.11 and 7.21±4.13 respectively in DE group. The four indicators were statistically different with each other (p<0.01). Significant positive correlations were observed between ST1, 2-minute ST, rear 3 minutes ST and rear 4 minutes ST. The details were listed in Table 2. We also recorded the ST results at each minute. However, we noticed a sign of Schirmer Test. The speed of mean wetting per minute had been slow down in ST. The speed was about 1.25-4.56 mm per minute in test including DE group and ND group (Figure 2). We found that the speed in the first minute was unstable and casual. Therefore, we focused on the other indicators of ST which removed the data of the first minute. We observed that the value of rear of 4-minute was about 3/5 of ST1.

2.2 Different value of schirmer test and Dry eye symptom questionnaires

We analyzed the relationship between four indicators and Dry eye symptom questionnaires. We found that these indicators all had correlation with OSDI or SPEED. Table 3 showed the details. We found that both ST1 and rear 4-minute ST had relationship with other indicators. To our suprise, we noticed that the correlation of ST and questionnaires had low relationship.

2.3 Different value of schirmer test and other dry eye examinations

    BUT was the most convenient diagnostic test used in the clinical practice. The subjects were perormed three consecutive fBUT tests and one time NIBUT under this research. Besides BUT, MG grading and CFS were performed. All four tests had statistical significance between DE group and ND group. Meanwhlie, we investigated the correlation about different values of ST and other 4 tests. The results showed the relationship between different ST and fBUT, MG grading, and CFS in Table 3. 

3. Schirmer Test and non-dry eye group

    We also collected the data of non-dry eye gruop. The value of ST1, 2-minute ST, rear 3 minutes ST and rear 4 minutes ST was 11.84±6.16, 8.25±6.80, 2.73±2.31, 7.36±3.42, respectively in ND group (Figure 3). The four indicators were statistically different with each other(p<0.01) in ND group. The score of OSDI and SPEED was 6.62±3.35 and 5.27±2.87. Other dry eye tests like NIBUT, fBUT, MG grading and CFS were 8.43±3.31, 4.22±2.20, 16.32±9.60 and 0.35±0.06. Table4 shows the correlation between ST and other examinations in ND gruop.

4.  rear 4-minute ST may be a suitable supplement for dry eye diagnosis

In order to evaluate four indicators in diagnosing DE, the true positive rate (TPR) was compared. The TPR of  ST1, 2-minute ST, rear 3 minutes ST and rear 4 minutes ST was 101 eyes(42.08%),75 eyes(31.25%), 68 eyes(28.33%), and 145 eyes (60.41%). We also calculated the true negative rate (TNR) in ND group. We found that the TNR of ST1, 2-minute ST, rear 3 minutes ST and rear 4 minutes ST was 50 eyes (41.67%), 47 eyes (39.17%), 48 eyes (40.00%), 54 eyes (45.00%). Stasitically, TPR of four indicators had significant difference (p<0.001). According to the above results, we choosed one indicator, 2-minute ST, to be a reliable supplement for ST. We found that the number of patients in theory whose tear secretion were less than 10 mm in 5 minutes accounts for 74.62% of persons which the value of rear 4-minute ST is lower than 6 mm. To provide the reference for the clinical diagnosis, we divided the patients into severe dry eye (ST≤5 mm) and borderline dry eye(5 mm<ST≤10 mm). We compared rear 4-minute ST with ST1 in subjective questionnaires and objective exanminations. Table 5 illustrated the points.

Discussion

Nowadays, there is still no consensus on the diagnostic criteria of DE in different areas, even though The International Dry Eye Workshop has declared the rules of diagnosis of DE. In previous reports, it’s known that most ocular examinations are not prefect means to diagnose DE 21. The sensitivity and specificity in detecting symptoms are too low to meet people’s need. One of the major reasons may be the heterogeneity of DE. However, there is no single existing test to diagnose DE reliably. Two or three tests are required to meet our need to diagnose DE. It means we need more time and more work. All we can do is to simplify the process and improve the accuracy of tests. 

      ST is one of the most commonly used test for assessment of ability in tear production for its low cost and simplicity. However, the value for diagnosing DE has not yet been unified with the improvements of ST over decades. Jones’ 12 prospective of basal ST was that the cut-point should be set at 10mm per 5 minutes, however, Van Bijsterveld 22 thought the length of wetting paper less than 5.5mm should be defined as deficient aqueous production. And it’s recommended currently that a cut-off 5.0mm per 5 minutes is meaningful 4,23. Even though ST without topical anesthesia may make patients feel discomfort, we think that reflex tear secretion is an indispensable indicator.

    ST is easily influenced by many factors like reflex tear, paper irritation, temperature and humidity 24-25. Therefore, we have been in the process of improving the accuracy of ST in the long term of  clinical practice. In Vasileios Karampatakis' research, he compared the 2- and 5-minute test and evaluated the reliability and the tear secretion of the Schirmer test I in 2 minutes 26. And we saw a similar sign about the speed of wetting. During the initial 1 minute, the speed of tear production was faster than the next minutes, this phenomenon suggested an adaptation of the central nervous system27. Besides, another reason was that a little of remaining tears may exist in the low fornix. For that matter, the doctor should make sure that there is no tears before the test. But we realised that the technique and process of dipping tears was not inconvenient for doctors and patients. In the long term, ST is implemented only once in clinical practice. Only one test may impair the accuracy of results and the validity of the test. In our study, we took the ST once as usual and recorded the values of each minute in order to get the elements that may be more reliable to assess the tear secretion. We noticed that the research of Vasileios Karampatakis just got a conclusion of tear secretion in most normal individuals. Our study included patients and normal persons. Therefore, we had enough samples to verify whether our selected indicator really works or not.

    As we konwn, ST without topical anesthesia may induce reflex tearing and the reflex tear secretion is unstable. Because of this reason, we need to investigate tear secretion of every minute in patients. Therefore, iwe selected four indicators : ST1, 2-minute ST, rear 3 minutes ST and rear 4 minutes ST. In our study, the ST values were consistent with the OSDI and SPEED. But the relevance was low. At the same time, we valued ST with other examinations like BUT, MG grading and CFS. BUT is considered to be the most common statistical pattern to value the stability of tear film 28. MG grading is used to assess the capacity of secreting the lipids and the extent of gland obstruction. The abnormality of meibomian gland including morphology and block may cause the problems of lipid layer 29. Fluorescein staining score is a test that value the environment of cornea. An unhealthy tear film may impair the function of epithelial cell and induce keratitis. Just like the results above, ST and rear 4-minute ST were correlated to the fBUT and MG grading in DE group. And rear 4-minute ST was correlated to the fBUT and MG grading in ND group. It suggested that participants in our study , no matter which group, rear 4-minute ST may be a reliable indicator in assessing tear secretion.

     To increase the accuracy of examination's, we should take care of more than one indiccator. The rear 4-minute test was chosen as a safe time limit for the evaluation of normal tear secretion. In first minute test, the reflex tear secretion irritated by Schirmer strip was biggest. And Vasileios Karampatakis suggested that the speed of wetting strips may decrease after 2 minutes due to the evaporation of paper26. Besides ST1, we noticed an interesting phenomenon that rear 4-minute may be a supplement way to value the condition of ocular surface. And it also had strong relationship with other DE tests. Last but not least, rear 4-minute ST had higher accuracy in diagnosing DE. It just need few second to record the value of ST and it's able to give a reliable data to evaluate the tear secretion. But there are some participants who may be sensitive about the paper and have a massive tear secretion. These persons are not fit this measurement and need other tests.

    In conclusion, our study found that rear 4-minute ST seemed a better supplement measurement to value the tear production. In our opinion, it's most likely to be DE patients when the figure of rear 4-minute ST is less than 6mm and 5-minute ST less than 10mm. One of the limitations of this study is that we did not account for the drainage and evaporation of tears. And we need more clinical practices for our indicator.

Declarations

Due to technical limitations, Declarations Section is not available for this version.

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Tables

Table 1 Baseline characteristics of the subjects (Mean ± SD).

Characteristics

DE

ND

Age

39.41±14.05

37.62±13.17

Sex (male/female)

45/75

30/30

NIBUT-Average (s)

4.70±2.28

8.43±3.31

fBUT-Average (s)

3.69±2.22

4.22±2.20

OSDI Total

30.12±12.91

6.62±3.35

SPEED

12.59±4.63

  5.27±2.87

MG grading

22.51±11.68

16.32±9.60

CFS

0.88±0.25

0.35±0.06

 

Table 2 the relationship between four indicators in DE group

Relationship (r/p)

Value(Mean±SD)

ST1

2-minute ST

rear 3- minute ST

rear 4- minute ST

Value(Mean±SD)

 

10.93±6.30

5.36±4.63

5.57±2.11

7.21±4.13

ST1

10.93±6.30

1.00

0.796*/<0.001

0.676*/<0.001

0.845*/<0.001

2-minute ST

5.36±4.63

0.796*/<0.001

1.00

0.256*/<0.001

0.508*/<0.001

rear 3-minute ST     

5.57±2.11

0.676*/<0.001

0.256*/0.001

1.00

0.884*/<<0.001

rear 4- minute ST

7.21±4.13

0.845*/<0.001

0.508*/<0.001

0.884*/<0.001

1.00

  

Table 3 the relationship between indicators of ST and OSDI, SPEED, fBUT, MG grading, and CFS in DE group 

Relationship (r/p)

Value(Mean±SD)

ST1

2-minute ST

rear 3- minute ST

rear 4- minute ST

value(Mean±SD)

 

10.93±6.30

5.36±4.63

5.57±2.11

7.21±4.13

OSDI

30.12±12.91





 r/p

 

-0.198*/<0.001

-0.137*/0.014

-0.081/0.155

-0.242*/<0.0016

SPEED

12.59±4.63





 r/p

 

-0.124*/0.037

-0.059/0.317

-0.170*/0.005

-0.183*/0.002

fBUT

3.69±2.22





 r/p

 

0.108*/0.024

0.040/0.403

0.103*/0.036

0.159*/0.001

MG grading

22.51±11.68





 r/p

 

      -0.153*/<0.001

-0.098*/0.022

-0.151/0.001

    -0.162*/<0.001

CFS

0.88±0.25

 

 

 

 

 r/p

 

0.091/0.156

0.064/0.326

0.176*/0.006

0.108/0.090

 

Table 4 the correlation between ST and other examinations in ND gruop

Relationship (r/p)

Value(Mean±SD)

ST1

2-minute ST

rear 3- minute ST

rear 4- minute ST

value(Mean±SD)

 

11.84±6.16

8.25±6.80

2.73±2.31

7.36±3.42

OSDI

6.62±3.35





 r/p

 

-0.284*/0.005

-0.086/0.370

-0.082/0.4

-0.316*/0.002

SPEED

5.27±2.87

 

 

 

 

r/p

 

-0.237*/0.025

-0.174*/0.075

-0.170*/0.090

-0.373*/<0.001

fBUT

4.22±2.20





r/p

 

0.195*/0.028

0.108/0.187

0.139/0.095

0.191*/0.029

MG grading

16.32±9.60

 

 

 

 

r/p

 

-0.279*/0.001

-0.194*/0.010

-0.048/0.546

-0.284*/<0.001

 

 Table 5 the relationship between rear 4-minute ST and ST1 with examinatios

Relationship (r/p)

Value

(Mean±SD)

Severe dry eye

Value

(Mean±SD)

Borderline dry eye



rear 4-minute ST

ST1


rear 4-minute ST

ST1

Value

(Mean±SD)


1.87±0.94

2.96±1.67


4.66±0.80

7.81±1.43

OSDI

30.45±10.46



32.46±10.97



r/p


-0.278*/0.001

-0.207*/0.014


-0.276*/0.026

-0.274*/0.038

SPEED

12.27±2.45



13.69±3.47



r/p


-0.289*/<0.001

-0.150*/0.043


-0.257*/0.039

-0.220*/0.048

fBUT

3.14±1.27



4.43±2.07



r/p


0.196*/0.015

0.145*/0.047


0.242*/0.042

0.223*/0.049

MG grading

24.40±10.83



22.72±10.83



r/p


-0.179*/0.002

-0.168*/0.038


-0.266*/0.021

-0.207*/0.05