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In This Article

  • Summary
  • Abstract
  • Introduction
  • Protocol
  • Results
  • Discussion
  • Disclosures
  • Acknowledgements
  • Materials
  • References
  • Reprints and Permissions

Summary

We developed a rat model of severe corneal inflammation through corneal epithelium curettage combined with corneal sutures. The study evaluated corneal inflammation patterns, epithelial proliferation, and changes in limbal stem cells under inflammatory conditions.

Abstract

Corneal inflammation, especially severe corneal inflammation, plays a significant role in the development of corneal limbal stem cell dysfunction. Constructing appropriate animal models can help us focus on the effects of severe inflammation on corneal limbal stem cells. A 2 mm rust removerΒ wasΒ used to remove the central corneal epithelium of Sprague Dawley (SD) rats to create an injury. Then, the central stroma of the cornea was sutured with nylon sutures to induce persistent inflammation. In this way, a corneal inflammation model with central corneal epithelium abrasion and central stroma suturing was constructed, which induced severe corneal inflammation. The changes in corneal inflammation and the condition of the limbal stem cells at 1, 3, and 7 days post-modeling were observed. On the 3rd day after modeling, the rats' corneal limbus was severely edematous, with obvious neovascularization and local hyperplasia, which are typical signs of limbal stem cell deficiency. By the 7th day, the corneal edema gradually worsened, and the neovascularization continued to increase. Through quantitative reverse transcription polymerase chain reaction (RT-qPCR) and immunofluorescence staining, we found that the corneal epithelial inflammatory factors were significantly upregulated, the corneal epithelial differentiation was abnormal, the corneal epithelial stem cells were significantly reduced, and the cell proliferation and stemness had also decreased. Therefore, this model demonstrates that severe inflammation can induce limbal stem cell damage without directly damaging the limbal stem cells. The model is beneficial for observing the effects of severe inflammation on the biological mechanisms of stem cells and provides an ideal platform for studying the mechanisms of corneal epithelial stem cell dysfunction induced by inflammation.

Introduction

Limbal stem cell dysfunction (LSCD) is characterized by persistent epithelial defects, corneal vascularization, chronic inflammation, scarring, and conjunctivalization of cornea1,2. It may arise from the depletion or dysfunction of limbal stem cells after severe ocular surface diseases, such as chemical burns, thermal burns, Stevens-Johnson syndrome, and iatrogenic injury caused by ocular surgeries2,3,4. The pathogenic mechanisms of LSCD mainly involve alterations in stem cells and disturbances in the stem cell microenvironment5,6, which affects the homeostasis of the corneal epithelium2,7. There are two primary types of fate changes in limbal stem cells in LSCD: 1) The directional differentiation potential of corneal epithelial stem cells becomes abnormal, leading to their differentiation into skin epithelial cells. This is evidenced by a decrease in the expression of corneal epithelial cell-specific transcription factor Pax6 and cornea-specific keratins Krt12 and Krt3, alongside a significant increase in the expression of skin-related squamous epithelial metaplasia markers Krt10, Krt1, and Sprr1b8; 2) Ocular surface injury directly destroys corneal limbal stem cells, resulting in necrosis or apoptosis, and subsequently causing conjunctival tissue proliferation that covers the cornea9. It has been reported that during the development of LSCD, inflammatory cells such as macrophages, neutrophils, and dendritic cells significantly increase in the corneal epithelial stem cell microenvironment. Correspondingly, cytokines such as interferon-gamma (IFN)-Ξ³, tumor necrosis factor(TNF)-Ξ±, interleukin (IL)-1Ξ², and macrophage inflammatory proteins (MIP)-1Ξ±/Ξ² also show significant elevations10.

Various LSCD models have been established, including those induced by sutures, chemical injuries, and benzalkonium chloride spotting11. Each of these models has its advantages and disadvantages. Chemical injuries can damage the entire ocular surface and directly destroy limbal stem cells12. Benzalkonium chloride functions similarly to chemical injuries but has a relatively slow effect13. The corneal suture model can induce a stable and long-term inflammatory response, but the inflammatory reaction is relatively mild and cannot cause LSCD.

To investigate the role and mechanisms of inflammation in the development of corneal LSCD, an animal model was established that combines curettage of the central corneal epithelium with corneal sutures. This model induces persistent inflammation of the corneal epithelium without directly damaging limbal stem cells.

Protocol

All procedures conformed to the ARVO guidelines for using animals in ophthalmic and vision research and were approved by the Animal Ethics Committee of Guizhou Medical University (Approval No. 2305192). The rats were housed at the Animal Center of Guizhou Medical University, adhering to relevant animal management regulations.

1. Animal selection

  1. Use female Sprague-Dawley (SD) rats aged 7-8 weeks. Ensure that there are no ocular surface lesions under slit lamp examination.
  2. Sterilize the instruments using a rapid sterilizer. Required instruments include corneal rust ring remover, 2 mm size skin sampling marker, needle holders, plate layer knives, ophthalmic surgical scissors, and forceps.
  3. Anesthetize the rats with 1.25% tribromoethanol via intraperitoneal injection at a dose of 0.3 mL/100 g. Instill one drop of tropicamide eye drops for pupil dilation. Apply proparacaine hydrochloride eye drops.
  4. Disinfect the skin and hair around the eyes with iodophor.
  5. Establish the inflammation model.
    1. Place the rat in the lateral decubitus position. Expose the eyeball under an operating microscope.
    2. The central cornea wasΒ labeled using a 2mm size skin sampling marker,Β and the labeled central corneal epithelium wasΒ scraped using a Corneal rust ring remover.
    3. Place three 120Β° corneal sutures using 10-0 nylon wire, needle holder, and ophthalmic surgical scissors and forceps about 3 mm from the limbus, do not penetrate the cornea14,15.
  6. Apply Ofloxacin eye ointment at the end of the procedure to prevent infection.
  7. Observe and photograph the cornea on the 1st, 3rd, and 7th day post-operation using a slit lamp magnified 10x lens. Record the symptoms such as corneal epithelial healing, conjunctival hyperemia, corneal edema, limbal hyperemia, and corneal neovascularization.

2. Calculation of the inflammatory index

  1. Calculate the inflammatory index of the ocular surface after establishing the animal model.
    1. Score ciliary body congestion as follows: no congestion (0 points); the presence of congestion less than 1 mm (1 point); hyperemia between 1 mm and 2 mm (2 points); hyperemia between 1 mm and 2 mm (3 points).
    2. Score central corneal edema as follows: no edema (0 points); edema with clear iris visibility (1 point); edema with unclear iris visibility (2 points); edema with the iris not visible (3 points).
    3. Score paracentral corneal edema as follows: no edema (0 points); edema with clear iris visibility (1 point); edema with unclear iris visibility (2 points); edema with the iris not visible (3 points).
    4. Calculate the inflammation index by adding all scores and dividing it by 9.

3. Assessment of corneal neovascularization

  1. Observe corneal neovascularization with a slit lamp.
    1. Analyze and process images using slit lamp image processing software16.
    2. Record the growth of corneal neovascularization at each observation time point, measuring the longest corneal neovascularization towards the central cornea with minimal curvature.
    3. Grade them as follows: Grade 0: Avascular; Grade 1: Micro (<1 mm); Grade 2: Mild (1 mm to 1.5 mm); Grade 3: Moderate (>1.5 mm to 2 mm); Grade 4: Severe (>2 mm).

4. Analyzing the biology of the model

  1. Prepare frozen eye specimens.
    1. Anesthetize the rat with 4-5% isoflurane and euthanize it by cervical dislocation.
    2. In the lateral decubitus position, lift the rat eyeball outward with micro tweezers and cut the conjunctiva open along the upper and lower eye dome with eye scissors.
    3. Cut the optic nerve, paying attention to maintaining the integrity of the corneal epithelium.
    4. Dry the blood stains and water on the eyeball surface with filter paper and put them in the embedding box with optimal cutting temperature (OCT) embedding medium.
    5. Remove the bubbles in the embedding box with a 200 Β΅L pipette, freeze it using liquid nitrogen, and then save the embedded specimens in the ultra-low temperature refrigerator.
  2. Prepare frozen sections of the eyeballs.
    1. Before preparing the frozen section, precool the cryostat to about -28 Β°C and the specimen holder to -26 Β°C.
    2. Remove the frozen specimens from the cold freezer and place them in the cryotome for about 1 h.
    3. Precool the frozen specimen in a cryotome for 10 min. Mark the specimen with a pencil, fix it on the specimen pad with OCT, and fix them together on the sectioning rack after cooling.
    4. Adjust the position and direction of the frozen specimen and fix it. First, cut 20 Β΅m sections until the central cornea is seen. Then, obtain 6 Β΅m sections by continuous slicing and collect the sections on the pre-prepared adhesion slides.
    5. Mark the name, material, section time, name, and number of the tissue on the slide. Place it at room temperature (RT) for about 30 min.
    6. After drying the sections, put them into a box and keep them in the ultra-low temperature refrigerator for reserve.
  3. Perform hematoxylin and eosin staining.
    1. Remove the pre-prepared frozen sections from the ultra-low temperature refrigerator and place them in the fume hood at RT to dry.
    2. Fix the sections using 4% paraformaldehyde for 15 min at RT. Rinse the specimens with 1x PBS for 5 min.
    3. Place the specimen sections containing slides on a slide holder and immerse them into the dye cylinder with hematoxylin dye solution at RT for 5 min.
    4. Slowly rinse the specimen containing slides with tap water to wash off the floating dye, put them into the dye tank with 0.1% hydrochloric acid alcohol, and remove them quickly after 1-2 s.
    5. Slowly rinse the specimen with tap water for 15 min.
    6. Remove the specimen from the water and immerse the slides into the eosin dye tank; leave at RT for 3 min.
    7. Slowly rinse the specimen with tap water, wash away the excess dye, and perform gradient alcohol dehydration using 75% alcohol, 80% alcohol, 95% alcohol, 100% alcohol (one), and 100% alcohol (two). Immsere the sections in each concentration for 2 min.
    8. Make the specimens transparent for 2 min in xylene (1) and xylene (2) respectively.
    9. Dry the specimen in the fume hood, seal the sections using a sealing agent, and be careful not to produce bubbles.
    10. Place the slides in a slide box at RT. Image the sections using a microscope.
  4. Perform immunofluorescence staining.
    1. Remove the frozen sections and place them in a box at RT in the fume hood to dry.
    2. Mark the name of the antibody to be stained in the glass slide blank of the frozen specimen.
    3. Fix the specimens with 4% paraformaldehyde at RT for 15 min. A small amount of tap water was added to the box to prevent the specimen from drying out.
    4. Remove the paraformaldehyde fixative and wash the specimen three times with 1x PBS buffer. Be careful not to flush off the specimen.
    5. Dry the liquid around the tissue section, cover the specimen with cell membrane solution (0.2% TritonX-100), and incubate at RT for 20 min.
    6. Remove the cell membrane solution and wash the sections three times for 5 min each with 1x PBS buffer.
    7. Dry the tissue sections, cover the specimen with immunofluorescence blocking solution (2% BSA), and incubate at RT for 1 h.
    8. Prepare the primary antibody and diluent (1% BSA) during the incubation per the manufacturer's instructions.
    9. Remove the blocking fluid and dry the specimen with a suction pump. Add the prepared primary antibody, cover the box, and incubate it in a 4 Β°C refrigerator overnight (incubate for about 12-16 h) away from light.
    10. Discard the primary antibody and wash the specimen four times for 10 min each in PBS.
    11. During the cleaning step, prepare the secondary antibody dilution as per the manufacturer's instructions.
    12. Remove PBS, dry the specimen, and add the prepared secondary antibody to the specimen. Cover the specimen and incubate at RT for 1 h away from light.
    13. Remove the secondary antibody, wash the specimen 4 times with 1x PBS buffer for 10 min each, and cover the whole slide with 1x PBS buffer.
    14. Remove PBS, dry the specimen, and seal the sections with a mounting medium containing DAPI, ensuring there are no air bubbles. Wrap the slides in tin foil and keep them at 4 Β°C away from light.
    15. Take photos with a laser confocal microscope system or with an upright fluorescence microscope camera system (scan speed: 4 Β΅s/pixel, scanning resolution: 1024 x 1024).
  5. Single-cell suspension preparation of the rat corneal epithelium
    1. After euthanasia, remove the eyeballs with tweezers soaked in 75% alcohol and put them into the 1x Hanks' balanced salt solution (HBSS) containing 10% fetal bovine serum (FBS) and 10% penicillin-streptomycin prepared in advance.
    2. Clean the eyeballs and use 1x HBBS containing 10% FBS and 10% penicillin-streptomycin twice for 5 min each.
    3. Remove the conjunctiva along the scleral margin; leave the scleral margin at about 1 mm. Again, wash the corneal tissue twice with 1x HBBS containing 10% FBS and 10% penicillin-streptomycin.
    4. Transfer the clean corneal tissue to a supplemented hormonal epidermal medium (SHEM) containing 2U/mL of Dispase II. Close the seal and place it at 4Β°C for 14-16 h.
    5. Have a pair of tweezers, toothless tweezers, an iris recovery device, and a surgical sterilizer ready.
    6. Under a surgical microscope, gently separate the corneal epithelium along the edge of the cornea.
    7. Wash the corneal epithelium with 1x HBSS containing 10% penicillin-streptomycin for 5 min.
    8. Transfer the corneal epithelial tissue to a 1.5 mL centrifuge tube containing 200 mL of trypsin and incubate in a 5% CO2, 37 Β°C incubator. Every 5 min, shake the centrifuge tube three times to digest the corneal epithelial sheet into a single-cell suspension.
    9. Add an equal amount of SHEM medium to stop the action of the trypsin digestion solution and place it at RT.
  6. Clone culture of corneal epithelial cells
    1. Prepare trophoblast cells.
      1. When the growth density of NIH 3T3 mouse cells reaches 80-90%, discard the cell culture medium. Add pre-prepared 10 mg/mL NIH 3T3 mitomycin culture medium and incubate at 37 Β°C for 2.5 h.
      2. Remove the medium, rinse cells with 1x HBSS, replace with new NIH 3T3 cell medium, and continue incubation in a CO2 incubator (5% CO2, 37 Β°C).
    2. Prepare the corneal epithelial cell suspension and count the cells according to the required ratio.
    3. While preparing the corneal epithelial cell suspension, process NIH 3T3 cells treated with mitomycin.
      1. Discard the supernatant, rinse cells with 1x HBSS, add 1 mL of trypsin-EDTA solution, and incubate at RT for 2-3 min.
      2. Add an equal amount of supplemental hormonal epithelial medium (SHEM medium: DMEM/F12, 10 ng/mL mouse epidermal growth factor [EGF], 10 Β΅g/mL Insulin-Transferrin-Selenium [ITS], 5% FBS, 1% penicillin-streptomycin, 0.5% dimethyl sulfoxide [DMSO], 0.5 mg/mL hydrocortisone), gently pipette to make a cell suspension, and count the cells.
    4. Use a 12-well plate and add 0.5 mL of SHEM medium to each well.
    5. Mix corneal epithelial cells with NIH 3T3 cells at a density of 500 corneal epithelial cells/cm2 and 5 x 105 NIH 3T3 cells/cm2. Add 1 mL of SHEM medium to each well.
    6. Add 1 mL of the cell mixture to each well and gently pipette to distribute the cells evenly.
    7. Incubate in an incubator (5% CO2, 37 Β°C), changing the medium every 2-3 days. Culture for 12-14 days.
  7. Crystal violet staining
    1. After approximately 12 days, when corneal epithelial clones are about to fuse, remove the culture medium and add 1 mL of 4% paraformaldehyde solution to each well, covering the cells completely. Fix the cells for 15 min at RT.
    2. Remove 4% paraformaldehyde and wash the wells three times with 1x PBS for 5 min each.
    3. Remove 1x PBS buffer and add 0.4% crystal violet dye solution to each well. Stain for 30 min at RT.
    4. Remove or recycle the crystal violet dye solution and wash it three times with 1x PBS for 10 min each.
    5. Air dry the wells at RT until thoroughly dry.
    6. Use a regular upright microscope photography system (scan speed: 4 Β΅s/pixel, scanning resolution: 1024 x 1024).
  8. Extraction of corneal mRNA
    1. Gather ophthalmic scissors, corneal scissors, toothed forceps, electric corneal epithelial scraper, Trizol, RNase-free 1.5 mL centrifuge tubes, and an ice box.
    2. Epithelial acquisition
      1. Anesthetize the rat with 4-5% isoflurane and euthanize it after cervical dislocation. Place the animal in a lateral position. Trim the mouse's whiskers with eye scissors to avoid blocking the view.
      2. Place the rat under a surgical microscope and adjust it to an appropriate height to focus on the eyeball. Use toothed forceps to gently push and expose the eyeball. Lift the rat's conjunctiva and use a clean electric corneal epithelial scraper to scrape the central 2 mm area of the corneal epithelium.
      3. Collect the scraped corneal epithelium with clean, toothed forceps sprayed with alcohol. Place the collected tissue into a centrifuge tube containing 1 mL of Trizol.
      4. Work as quickly as possible to rinse the collected tissue in a 50 mL centrifuge tube containing double-deionized water. Absorb excess water with filter paper. Spray with 75% alcohol and proceed to the next step.
      5. Lift the rat's conjunctiva again using toothed forceps. Use corneal scissors with the concave side up to cut the conjunctiva along the limbus, leaving about 0.5 mm of white conjunctiva.
      6. Scrape the corneal epithelium within a 2 mm range at the corneal limbus using the electric scraper. Collect the tissue as described before. Collect the central corneal epithelium from three eyeballs and the limbal epithelium from three eyeballs.
      7. Place the collected tissues into separate 1 mL Trizol RNA extraction reagent tubes. Perform the entire operation on ice to preserve RNA integrity. Proceed with the next steps immediately or store the samples in an ultra-low temperature freezer at -80 Β°C for later use.
    3. Thaw the specimen on ice, use an ultrasonic tissue homogenizer to lyse the cells. Set the ultrasonic homogenizer's power to 25%, time to 2 s per burst, interval time to 5 s, and the total time to 2 min. Let it stand on ice for 10 min.
    4. Add chloroform (1/5 of the total volume, approximately 200 Β΅L) to each sample, mix thoroughly by inverting for 30 s, and centrifuge at 400 x g for 10 min at 4 Β°C.
    5. RNA precipitation
      1. After centrifugation, the liquid inside the centrifuge tube is layered into three parts. The top clear layer is RNA, the middle white cloudy layer is DNA and proteins, and the bottom layer is Trizol. Carefully pipette about 500 Β΅L of the top clear layer into a new 1.5 mL centrifuge tube, careful not to aspirate the white precipitate in the middle layer. If inadvertently aspirated, repeat centrifugation to collect the clear layer again.
      2. Add an equal amount of pre-chilled isopropanol to the centrifuge tube containing the clear layer, approximately 500 Β΅L, invert the tube several times to mix thoroughly, then immediately place it in a -80 Β°C ultra-low temperature freezer for 20-30 min. This step aims to accelerate the precipitation of RNA.
    6. Take out the sample, and immediately centrifuge at 400 x g for 10 min at 4 Β°C. A small amount of white, flaky precipitate is seen at the bottom of the centrifuge tube; discard the supernatant.
    7. Add pre-prepared and ice-cooled 70% ethanol to each tube. Immediately centrifuge at 4 Β°C in a refrigerated centrifuge at 400 x g for about 10 min; repeat the above steps once to thoroughly wash the precipitate. At this step, pre-sterilize the fume hood with UV light for 15 min.
    8. After removing the centrifuge tubes and discarding the supernatant, centrifuge again at 4 Β°C at approximately 250 x g for 2 min. Use a 200 Β΅L pipette tip to carefully aspirate the excess alcohol from the side opposite the precipitate, drying as thoroughly as possible. Place in a pre-UV-sterilized fume hood to dry, air dry the precipitate for about 15 min.
    9. Prepare the solution by adding 1 mL of RNase inhibitor to 40 mL of Diethyl pyrocarbonate (DEPC) water. Add an appropriate amount of DEPC water/RNase inhibitor mixture, about 20-30 Β΅L, to dissolve the sample. If there is a lot of precipitate, add 30-50 Β΅L. Immediately proceed with reverse transcription PCR.
  9. Reverse transcription PCR
    1. Ensure these items are present: PCR machine, RNase-free 1.5 mL centrifuge tubes, 0.2 mL PCR tubes, ice bath or ice box, pipette, and RNase-free tips.
    2. Measure the RNA concentration using the microvolume spectrophotometer. For each sample, ensure 1 Β΅g of RNA is added to the reaction system.
    3. The reverse transcription system has a total volume of 20 Β΅L. Calculate the total amount of reagents needed based on the number of samples. Mix according to the ratio specified in the instructions.
    4. Prepare the reaction system on ice, vortex it, and briefly centrifuge it. Incubate at 42 Β°C for 15 min and at 90 Β°C for 30 s.
    5. Use the cDNA obtained from the reverse transcription process either directly for real-time quantitative PCR analysis or store in a -80 Β°C refrigerator.
  10. Real-time quantitative PCR reaction
    1. Use a real-time quantitative PCR reagent kit17 with a 10 Β΅L reaction system. Use the primer sequences shown in Table 1.
    2. Add the reaction system described above into a 96-well plate or an eight-strip tube specifically for RT-PCR. Ensure that the samples are well-mixed. Check for bubbles in the tubes before placing them on the PCR machine.
    3. Amplify the gene using the PCR cycle (95 Β°C for 5 min), 40 cycles (95 Β°C for 10 s, 60 Β°C for 30 s), and complete the data to calculate the 2-ΔΔ Ct value. Process, analyze, and plot the data using appropriate data analysis software.

Results

As shown in Figure 1A, through observation with a slit lamp, we found that the healing of the corneal epithelium was impaired. Under normal circumstances, the central corneal epithelium would completely heal within 24-48 h after removal, but in the corneal central epithelium excision combined with a suture model, new blood vessels continued to exist. On the third day after the model was established, significant corneal limbal edema and neovascularization were observed, with typical signs of ...

Discussion

Inflammation plays a key role in the development of limbal stem cell deficiency18, but its specific mechanisms and effects require further exploration. To address this issue, we induced LSCD by scraping the central corneal epithelium and suturing the central corneal stroma to cause severe corneal inflammation. We observed the evolution of corneal inflammation and the status of the limbal stem cells on days 1, 3, and 7 post-modeling. On the third day post-modeling, significant edema of the rat limb...

Disclosures

The authors have nothing to disclose.

Acknowledgements

This study was supported in part by the Guizhou Provincial Science and Technology Projects (QKHJC-ZK[2024]ZD043), Fujian Provincial Science Fund for Distinguished Young Scholars (2023J06053 [to S.O]); the Natural Science Foundation of China (No.82101084 [to S.O.] and China Scholarship Council (CSC, 202306310049 [to Y.W.]).

Materials

NameCompanyCatalog NumberComments
10-0 suture lineAlcon, Inc., USA8065698001
2 mm corneal trephineSuzhou XVI Vision Company, Chinahttp://www.66vision.com/
20 ΞΌ L, 100 ΞΌ L, 1 mL pipette gun heads, cell culture plate culture plates, centrifuge tubesGuangzhou Jiete Biological Co., Ltd., Chinahttps://www.jetbiofil.com/index.html
-20/-80 Β°C fridgeQingdao Haier Company, Chinahttps://www.haier.com/cn/
A 10-mL syringeΒ Zhejiang Condelai Medical Device Co., Ltd., Chinahttps://en.kdlchina.com/zhejiang/25.html
Adhere to the slideShiTai Company188105
Amylene alcoholShanghai. Macklin Biochemical, Chinahttp://www.macklin.cn/products/
Anti-CytokertinAbcam, United Kingdomab76318
Anti-Keratin 12 antibody EPR17882Abcam, United Kingdomab185627
Anti-PAX6 antibodyAbcam, United Kingdomab195045
Anti-stripping slides, cover slipsJiangsu Shitai Experimental Equipment Co., Ltd., Chinahttps://cn.citotest.com/
AutoclaveHirayama, Japanhttps://hirayama.com.cn/about/
AvertinShanghai Aladdin Biochemical Technology, Chinahttps://www.aladdin-e.com/zh_cn/A111225.html
ChloroformShanghai Biological Engineering Co., Ltd., Chinahttps://www.siobp.com/web
CO2 Oven incubator, ultrasonic crusher, centrifugeThermo Fisher Technologies Inc., USAhttps://www.thermofisher.cn/cn/zh/home.html
Confocal microscopeShanghai Qinxiang Scientific Instrument Co., Ltd., Chinahttps://www.clinx.cn/about
Corneal epithelial forcepsSuzhou XVI Vision Company, China53418D
DAPIVector. Inc., USAH-1000
DEPC waterΒ Shanghai Biological Engineering Co., Ltd., Chinahttps://www.siobp.com/web
Dicuro eye cream (ofloxacin eye cream)Santian Pharmaceutical Corporation, Japanhttps://www.santen.com/asia
D-KSFM, culture medium, double antibody, and PBSThermo Fisher Scientific, Inc., USAhttps://www.thermofisher.cn/cn/zh/home.html
ED1AbD Serote c, United KingdomΒ MCA341GA
Electronic balanceShanghai Ohaus Biotechnology Company, Chinahttp://shbio.com/company
Enclosure of the membraneParafilm, Inc., USAhttps://www.sigmaaldrich.cn
Fluorescein sodium test strip was used in ophthalmologyTianjin Jingming New Technology Development Co., Ltd., Chinahttps://www.eworldtrade.com/c/jingmingtechnological/
Fluorescent inverted phase-contrast micrographic systemTE-2000U, Nikon, Japanhttps://www.microscopyu.com/museum/eclipse-te2000-inverted-microscope
Frozen table-top centrifugeEppendorf, Germanyhttps://www.eppendorf.sh.cnΒ 
Glass sheet frameXiamen Tianjing Biotechnology Co., Ltd., Chinahttp://www.tagene.net/
H-1200 with DAPI sealagentXiamen Juin Biotechnology Co., Ltd., Chinahttps://www.bosonbio.com.cn/
HE staining kitAuragene, Chinahttp://jushengwu.com/a048/
Hematoxylin-eosin dye solution kitAURAGEN, United StatesP032IH
High and low precision electronic balanceSdolis, Germanyhttps://www.solisinverters.com/global
IsopropanolShanghai Sinopharm Chemical Reagents Co., Ltd., Chinahttps://en.reagent.com.cn/
Ki-67 antibodyAbcam, United Kingdomab16667
liquid nitrogenXiamen Yidong Gas Co., Ltd., Chinahttps://www.china.tdk.com.cn/tdk_chn_en/tdk_xiamen/
Microhand holderSuzhou XVI Vision Company, Chinahttp://www.66vision.com/
Multiformaldehyde powderSigm, Americahttps://www.sigmaaldrich.cn
Normal temperature centrifuge 46Eppendorf, Germanyhttps://www.thermofisher.cn
OCTShanghai Maokang Biotechnology Co., Ltd., China4583
Ordinary biological micrographic systemEclipse 50i, Nikon, Japanhttps://www.microscope.healthcare.nikon.com/zh_CN/products/upright-microscopes/eclipse-ni-series
PBSShanghai Anjin Biotechnology Co., Ltd, ChinaSH30256.01
PCR, and the reactor apparatusBiometra Thermocycler, Germanyhttps://www.analytik-jena.com/products/life-science/pcr-qpcr-thermal-cycler/thermal-cycler-pcr/biometra-tone-series/
Pipettes of various specificationsEppendorf Company, Germanyhttps://www.eppendorf.com/cn-zh/
Primers for Rt-PCRShanghai Bio-Tech Co., Ltd.
Promeaine hydrochloride 0.5% eye dropsAlcon, Inc., USAhttps://www.alcon.com/about-us
Rat PMN antibodyFitzgerald, United States20R-PR020
Real time fluorescence quantitative PCRApplied Biosystems,Β United Stateshttps://www.thermofisher.cn
Reverse transcription kitTAKARA, Japanhttps://www.takarabiomed.com.cn/
Slit lampTOPCON, Japanhttps://topconchina.cn/
Smooth forcepsSuzhou XVI Vision Company, Chinahttp://www.66vision.com/
Specimen-boxLambolid (Fuzhou) Biotechnology Co., Ltd., Chinahttp://chuangdianbio.com/
Superclean benchNew Plus Pi Art High Technology Company Limited, Singaporehttps://www.hi-p.com/
Toothed forcepsSuzhou XVI Vision Company, Chinahttp://www.66vision.com/
Toppicamide eye drops (Medol)Alcon, Inc., USAhttps://www.alcon.com/about-us
Trace nucleic acid protein concentration testerThermo Fisher Technologies Inc., USAhttps://www.thermofisher.cn/cn/zh/home.html
TrizolInvitrogen The United Stateshttps://www.fishersci.com/us/en/brands/IIAM0WMR/invitrogen.html
Zeiss, with a surgical microscopeCarl ZEIS, Germanyhttps://www.zeiss.com/corporate/en/about-zeiss.html

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