The purpose of this study is to determine whether poly(β-amino ester)(PAE)hydrogel loaded with tRNA-derived fragments-antisense oligonucleotides-exosomes(tRF-ASO-Exo) could alleviate symptoms in patients with diabetic ocular surface diseases(DOSD).
Diabetes mellitus is a highly prevalent, chronic systemic metabolic disorder affecting populations worldwide. According to the most recent data from the International Diabetes Federation (IDF), the global prevalence of diabetes among adults stands at 10.5%, whereas in China, it reaches 11.6%-corresponding to approximately 113.9 million affected adults, the highest absolute number globally. Diabetes-related systemic and ocular complications significantly impair patients' quality of life and impose substantial economic burdens on individuals, families, and healthcare systems, thereby constituting a pressing public health challenge requiring coordinated national and international action. Diabetic ocular surface disease (DOSD) represents one of the earliest and most frequently observed ocular complications of diabetes, often preceding other diabetic eye manifestations. Its incidence rises markedly with longer disease duration and suboptimal glycemic control. Notably, diabetic patients undergoing common ophthalmic procedures-including phacoemulsification for cataract, pterygium excision, and vitreoretinal surgery-are at heightened risk of postoperative keratoconjunctival disorders, which may progress to irreversible visual impairment or blindness, thereby threatening long-term ocular integrity. Among individuals with diabetes of ≥5 years' duration, over 60% develop moderate-to-severe dry eye or keratoconjunctival epithelial damage, clinically characterized by progressive symptoms including ocular dryness, foreign body sensation, photophobia, pain, and, in advanced cases, vision loss-collectively resulting in marked functional and quality-of-life deterioration. Current clinical management of DOSD remains largely palliative, relying predominantly on artificial tear supplementation, secretagogues, and topical anti-inflammatory agents. However, these interventions do not address underlying neuroepithelial dysfunction and are limited by poor long-term adherence-reported rates fall below 50%-leading to suboptimal therapeutic outcomes. Consequently, the development of mechanism-targeted, disease-modifying therapies for DOSD is an urgent unmet clinical need. Antisense oligonucleotides (ASOs) are synthetic, single-stranded RNA molecules designed to bind complementary tRNA-derived fragments (tRFs) with high specificity, thereby inhibiting their pathogenic activity. ASO-based therapeutics have demonstrated robust efficacy in neurodegenerative disorders, with several candidates having advanced to late-stage clinical trials. Engineered exosomes represent a next-generation drug delivery platform, offering enhanced nucleic acid loading capacity, improved pharmacokinetic stability, increased bioavailability, and superior tissue targeting compared with conventional exosomes or free small-molecule drugs. In ophthalmology, scalable production of engineered exosomes has opened new avenues for localized treatment of keratoconjunctival diseases. Furthermore, hydrogels provide physical encapsulation of nucleic acid therapeutics, shielding them from rapid enzymatic degradation in vivo; when combined with the intrinsic lipid bilayer of exosomes, this creates a synergistic "dual-barrier" protection system that markedly enhances therapeutic durability and clinical translatability. Poly(β-amino ester) (PAE) hydrogels-fabricated as biocompatible, three-dimensional scaffolds-retain the favorable properties of conventional hydrogels while additionally enabling sustained, controlled release, scalable manufacturing, and intrinsic neuroregenerative potential. In preclinical studies using a murine model of diabetic ocular surface disease, topical application of PAE hydrogel loaded with tRF-targeting ASO-engineered mesenchymal stem cell-derived exosomes (tRF-ASO-Exo) significantly attenuated ocular surface inflammation, promoted structural recovery of the corneal and conjunctival epithelium, and preserved corneal epithelial viability. This study aims to evaluate a novel, non-invasive, topical hydrogel-based delivery system for tRF-ASO-loaded mesenchymal stem cell-derived exosomes (MSC-Exos) in patients with DOSD. The primary objective is to assess structural and functional ocular surface restoration using multimodal imaging and clinical metrics: anterior segment optical coherence tomography (AS-OCT), in vivo confocal microscopy (IVCM), slit-lamp-guided corneal fluorescein staining, and quantitative corneal sensitivity testing. Symptom improvement will be evaluated using the validated Ocular Surface Disease Index (OSDI). Secondary endpoints include tear secretion volume (Schirmer test), tear film breakup time (TBUT), ocular redness grading, tear meniscus height (via AS-OCT), and best-corrected visual acuity (BCVA). A total of 30 participants will be enrolled and randomized into three intervention groups. Following a 14-day placebo run-in period-during which all subjects receive bilateral placebo eye drops (one drop per eye, twice daily, approximately 12 hours apart)-participants will receive active treatment for 84 days: Group 1 (Exo) receives 10 μg/drop of unmodified MSC-Exos; Group 2 (tRF-ASO-Exo) receives 10 μg/drop of MSC-Exos formulated in PAE hydrogel; and Group 3 (tRF-ASO-Exo-PAE) receives 10 μg/drop of tRF-ASO-engineered MSC-Exos delivered via PAE hydrogel-all administered twice daily. A 12-weeks follow-up will be conducted to monitor disease progression and durability of therapeutic effects.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
QUADRUPLE
Enrollment
30
Participants will receive artificial tears for 2 weeks to get the normalized baseline, followed by Exosomes 10ug/drop, two times a day for 84 days. The follow-up visit will be 12 weeks.
Participants will receive artificial tears for 2 weeks to get the normalized baseline, followed by tRF-ASO-Exo 10ug/drop, two times a day for 84 days. The follow-up visit will be 12 weeks.
Participants will receive artificial tears for 2 weeks to get the normalized baseline, followed by tRF-ASO-Exo-PAE 10ug/drop, two times a day for 84 days. The follow-up visit will be 12 weeks.
corneal and conjunctival nerve density
In vivo confocal microscopy (IVCM) examination: All subjects underwent IVCM to assess corneal and conjunctival nerve density. Instruct the patient to fixate on a target, and the examiner slowly moves the objective lens until the vortex structure of the subbasal nerve plexus of the cornea can be seen.
Time frame: 1day, 2 weeks, 6 weeks, 12 weeks
Corneal sensitivity
Corneal sensitivity of the operated eye was evaluated by one examiner via a French Cochet-Bonnet aesthesiometer (Luneau Ophthalmologie), which consists of a calibrated nylon filament on a retractable shaft with a length scale. Longer filaments (lower bending force, weaker stimulus) indicate higher sensitivity. The sensitivity threshold was the maximum filament length evoking a reliable blink response. All tests were conducted in a standardized quiet indoor setting; patients kept eyes open with stable gaze during testing. Starting at 60 mm, the filament was perpendicularly applied to the central cornea, then shortened by 5 mm increments until consistent blinks occurred. Three measurements were taken, and corneal sensitivity was defined as the mean length of positive responses.
Time frame: 1day, 2 weeks, 6 weeks, 12 weeks
conjunctival goblet cell density
All participants underwent in vivo confocal microscopy (IVCM) assessment of conjunctival goblet cell density. Prior to imaging, subjects were instructed to maintain steady fixation on a standardized external target. The examiner systematically scanned the temporal bulbar conjunctiva approximately 3 mm from the corneal limbus, using the "section" scanning mode to acquire high-resolution images of the conjunctival epithelium-including the vortex region and its surrounding tissue within a 2-3 mm radius. To ensure optimal image quality and anatomical coverage, four non-overlapping image fields were captured per eye, each centered on a distinct location within a predefined small target zone. A sterile, single-use plastic cap was gently applied to the conjunctival surface prior to scanning to stabilize the ocular surface and minimize motion artifact. A total of 100-200 well-focused, artifact-free images were acquired for each examined eye.
Time frame: 1day, 2 weeks, 6 weeks, 12 weeks
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Changes in Ocular Surface Staining
Ocular surface integrity was checked with a non-toxic dye at the slit lamp. Corneal and conjunctival staining were graded with the NEI photo atlas; lower scores mean less dry-eye damage. Change-from-baseline numbers were calculated for each eye, so a negative value equals improvement.
Time frame: 1day, 2 weeks, 6 weeks, 12 weeks
conjunctival vessel density and number of branches
AS-OCTA examination was performed to quantify conjunctival vasculature using anterior segment optical coherence tomography angiography. The anterior segment AS Angio 9×9 mm scan pattern with a resolution of 256×256 A-scans was selected for imaging and motion tracking. The scanning frame was positioned to intersect the corneal limbus, and the focal plane was adjusted until optimal visualization of the conjunctival layer was achieved. Superficial and deep conjunctival vascular plexuses were analyzed at depth ranges of 0-50 μm and 50-100 μm, respectively, with partial overlap between the two layers to account for transitional vascular networks. Vessel density and branching index were quantified using the device-integrated analytical software. Additionally, en face images were exported and further processed using ImageJ software (National Institutes of Health, USA) for supplementary image analysis.
Time frame: 1day, 2 weeks, 6 weeks, 12 weeks
Changes in Ocular Surface Disease Index (OSDI) Score
The Ocular Surface Disease Index (OSDI) is a validated 12-item questionnaire specifically designed to quantify the severity of dry eye symptoms in clinical settings. Its scoring range spans from 0 to 100, with lower scores correlating with a greater alleviation of dry eye-related discomfort. Baseline-adjusted OSDI scores were calculated, and a reduction of more than 10 points from the baseline value was defined as a clinically meaningful improvement in symptoms.
Time frame: 1day, 2 weeks, 6 weeks, 12 weeks
Changes in tear secretion amount by Schirmer's Test
The examiner tucked a sterile paper strip beneath the lower lid, left it in place for the set time, then read the millimeters of strip the tears had traveled.
Time frame: 1day, 2 weeks, 6 weeks, 12 weeks
Changes in Tear break time
After a blink, the stopwatch ran until the first dry patch showed up on the ocular surface-time recorded in seconds.
Time frame: 1day, 2 weeks, 6 weeks, 12 weeks
Changes in best corrected visual acuity (BCVA)
to understand the effect of tRF-ASO-Exo-PAE on visual acuity
Time frame: 1day, 2 weeks, 6 weeks, 12 weeks
Changes in conjunctiva redness score
To explore the effect of tRF-ASO-Exo-PAE on conjunctiva. Under the slit lamp the investigator lined up each quadrant with the Allergan redness photos and handed out a 0-4 card: 0 = normal, vessels sharp; 1 = trace flush; 2 = mild; 3 = moderate; 4 = fiery severe-every step matched to its reference picture.
Time frame: 1day, 2 weeks, 6 weeks, 12 weeks