Ocular Surface Changes After Sulfur Mustard Exposure in Rabbits, Monitored by Impression Cytology.

PURPOSE: Ocular injuries after exposure to sulfur mustard (SM) are characterized by acute corneal erosion and inflammation of the anterior segment that may be followed by delayed corneal neovascularization and epithelial defects, associated with limbal stem cell deficiency in part of the exposed eyes. This study aimed to further clarify the mechanism of the late injury by monitoring SM-induced cytological alterations in the ocular surface, in relation to the clinical symptoms, using impression cytology (IC). METHODS: Rabbit eyes were exposed to SM vapor (n = 20) and were clinically observed up to 4 weeks. Samples for IC were collected simultaneously from the upper bulbar conjunctiva, limbus, and cornea and then fixed and stained with periodic acid-Schiff and hematoxylin. At 1 month, animals were killed and eyes dissected and processed for histology. RESULTS: Concomitant with clinical symptoms of SM ocular toxicity, IC showed significant long-term loss of conjunctival goblet cells shortly after exposure, followed by abnormal differentiation toward squamous metaplasia. Simultaneously with corneal erosion, apoptotic bodies and cellular debris were seen in the corneal epithelium, followed by regeneration at 1 week. Migration of conjunctival goblet cells toward the cornea was noted in neovascularized eyes, as early as 1 week, indicating limbal stem cell deficiency. The IC findings were supported by histological evaluation. CONCLUSIONS: Continuous monitoring of the ocular surface after SM exposure by IC enables earlier detection of pathology and therapeutic intervention, therefore, is recommended for routine follow-up of casualties. Prolonged loss of goblet cells may point toward the role of mucin in the pathogenesis.

Dermostyx (IB1) - High efficacy and safe topical skin protectant against percutaneous toxic agents.

Prevention of the penetration of toxic agents through the skin is crucial for both military troops and civilian populations. We have developed a novel topical skin protectant (TSP), coded as IB1 and commercially available as Dermostyx protective solution (Rekah Pharm, Israel). The formulation afforded significant protection against chemical warfare agents such as sulfur mustard (SM) and VX (2LD50), pesticides such as parathion and irritants such as acrolein. The efficacy of the protectant was evaluated in the pig model using clinical, histological and biochemical monitoring. A single topical application prior to exposure to the toxic agents reduced significantly the size and severity of skin lesions and ameliorated or prevented systemic clinical symptoms. The barrier properties of IB1 are immediate upon application and remain effective for at least 12 h. It is absorbed into the stratum corneum of the skin and remains there until rinsing with water, yet the ingredients are not absorbed into the body. The formulation is a hydrophilic water-based solution, composed of magnesium sulfate and glycerin that are widely used in cosmetic and medicine, and was shown to be safe in preclinical and in Phase I clinical studies. The suggested mode of action is based on the unique interaction of glycerin with the stratum corneum, changing its properties to hydrophilic and on the "salting out" effect of magnesium sulfate. The expected use of the TSP is by application on exposed skin areas and sensitive skin sites (e.g. armpits, groin, waist), when necessary. A quantity of 10 ml is sufficient for one application covering approximately 20% of the body surface area. The formulation was approved for human use by the Israel Ministry of Health and a CE mark certificate in Europe has been recently issued (Class I). Dermostyx has been adopted by the IDF and first responders as a skin protectant for special needs.

The beneficial effects of doxycycline, an inhibitor of matrix metalloproteinases, on sulfur mustard-induced ocular pathologies depend on the injury stage.

PURPOSE: Sulfur mustard (SM) induces acute ocular lesions, including erosions and inflammation that may be followed by delayed injuries expressed by epithelial defects and neovascularization (NV). Based on the matrix metalloproteinases (MMPs) activity, we evaluated the clinical and biochemical effects of topical treatment with doxycycline, an MMP inhibitor, targeted to the various injury stages. METHODS: Rabbit eyes were exposed to SM vapor. A clinical follow-up was carried out up to 2 months. Tear fluid and cornea samples were collected at different time points for measurements of MMPs activity by zymography. Efficacy of a post-exposure topical doxycycline (2 mg/ml in phosphate buffer saline, ×4/d), targeted to the different phases of the clinical injury, was evaluated. RESULTS: Elevated MMP-9 and MMP-2 activities were found in all corneas during the acute injury and in vascularized corneas during the delayed pathology. In the tear fluid, high MMP-9 activity and negligible MMP-2 activity were found in all the exposed eyes until after the appearance of the delayed pathology symptoms. Prolonged doxycycline treatment reduced MMP-9 activity in the tear fluid. During the acute phase, doxycycline treatment reduced corneal MMP-9 activity and the severity of the injury. Targeting the delayed pathology, doxycycline was clinically efficient only when treatment began before NV appearance. CONCLUSIONS: This in vivo study showed the involvement of MMP-9 and MMP-2 during different phases of the SM-induced ocular injury, and the potential of doxycycline treatment as a post exposure measure for reducing the acute injury and as a preventive therapy for ameliorating the delayed pathology. The tear fluid provided a non-invasive method for continuous follow-up of MMPs activity and revealed additional beneficial aspects of injury and the treatment.

Anti-VEGF therapy (bevacizumab) for sulfur mustard-induced corneal neovascularization associated with delayed limbal stem cell deficiency in rabbits.

PURPOSE: To investigate the involvement of VEGF in corneal neovascularization (CNV) following sulfur mustard (SM) exposure and to test the therapeutic effects of bevacizumab (Avastin) in respect to dose, route of administration and timing. MATERIALS AND METHODS: Topical bevacizumab (6 or 25 mg/ml, ×2/day) was applied to rabbit eyes, before or after appearance of NV, following SM vapor exposure, and was compared with subconjunctival injection (25 mg/ml, ×2/week) and topical dexamethasone (1%, ×4/day). Treatments were given for 3 weeks. VEGF levels were monitored by immunohistochemistry and ELISA assay. Clinical evaluations included slit-lamp examination, impression cytology for diagnosis of Limbal Stem Cell Deficiency (LSCD), pachymetry, measurement of NV length and histology. RESULTS: Corneal NV was developed, as early as 2 weeks after exposure, in 50-70% of the eyes, associated with increased levels of VEGF. Topical bevacizumab treatment with both doses, starting at 4 weeks, reduced vascularization. Subconjunctival injection and topical dexamethasone were more potent. A combined treatment of dexamethasone and bevacizumab improved the anti-angiogenic efficacy, yet, there was no effect on LSCD. Topical bevacizumab treatment starting at 1 week, when VEGF was elevated but before appearance of NV, had no effect. CONCLUSIONS: VEGF was involved in corneal angiogenesis in SM-induced ocular injury. Bevacizumab was beneficial in reducing CNV by both, topical or subconjunctival injection, when given as a symptomatic therapy with or without dexamethasone, however with no effect on SC deficiency. Further studies on the pathological mechanism of SM-induced ocular surface disorder may direct towards improved therapy.

Endothelial cell damage following sulfur mustard exposure in rabbits and its association with the delayed-onset ocular lesions.

OBJECTIVE: Ocular injuries following exposure to the toxic agent sulfur mustard (SM) are characterized by acute corneal erosions and inflammation of the anterior segment that may be followed by delayed corneal injuries, expressed clinically by neovascularization and epithelial defects. The present study aimed to investigate the effects of SM on corneal endothelium (CE) during the acute and delayed phase in relation to the development of the long-term pathology. METHODS: Rabbit eyes were exposed to SM vapor. A clinical follow-up including pachymetry for measurement of corneal thickness were conducted up to 3 months following exposure. In vivo analysis of corneal endothelium in the central and peripheral cornea was carried out, using a contact specular microscopy. Morphometric analysis of cell area and number of cells was performed, to include the acute and delayed phases. Eyes were taken for histology at different time points following exposure (1 h to 3 months). TUNEL staining (Terminal deoxynucleotidyl transferase dUTP nick end labeling) was conducted for detection of apoptosis during the acute phase. RESULTS: SM induced acute corneal erosions and prolonged anterior segment inflammation. Corneal thickness increased within hours, declined after few days but remained higher compared to baseline value for months after the exposure, indicating a chronic edema. Apoptotic alterations were first observed at 6 h resulting in a significant decline in the number of endothelial cells at 24-48 h following exposure. Healing of the endothelium was relatively fast and at one week the Descemet's membrane was resurfaced, yet, the density and morphology of the cells was often abnormal. Moreover, histological evaluation revealed deformation and enlargement of many cells (polymegathism and pleomorphism), thickening and double layered Descemet's membrane. These changes were more pronounced in corneas displaying delayed pathology. DISCUSSION AND CONCLUSIONS: SM induced apoptotic cell death of endothelial cells that was accompanied by corneal edema. The impaired healing of the endothelium, including the decrease in endothelial cell density was associated with the delayed-onset injuries. Since human corneal endothelium is almost amitotic, endothelium toxicity should be taken into consideration when testing potential treatments against ocular injuries following SM exposure.

Prolonged impairment of corneal innervation after exposure to sulfur mustard and its relation to the development of delayed limbal stem cell deficiency.

PURPOSE: Ocular injuries after exposure to the vesicant sulfur mustard (SM) are characterized by acute corneal erosions and inflammation of the anterior segment that may be followed by delayed limbal stem cell deficiency (LSCD), expressed clinically by corneal neovascularization and epithelial defects. The present study aimed to investigate the involvement of corneal nerves in the development of the delayed LSCD. METHODS: Rabbit eyes were exposed to SM vapor and observed clinically up to 1 month. Morphology and density of corneal nerves were studied in acetylcholinesterase-stained whole-mount corneas at different time points after exposure. Corneal calcitonin gene-related peptide (CGRP) was measured and the relation to clinical symptoms was tested. RESULTS: Degeneration of nerve terminals was observed a few hours after exposure simultaneously with the typical signs of SM ocular toxicity. Although corneal erosions healed within days, the nerves continued to disintegrate under a Wallerian degeneration pattern and their density declined significantly at 1 week in both central and peripheral corneal regions. Sprouting and regenerative nerve fibers were observed later in most of the corneas; however, healing was partial and often abnormal and was correlated with corneal edema. CGRP levels decreased at 24 hours and then increased significantly at 1 to 4 weeks, concomitant with the reinnervation process and development of the late injuries. CONCLUSIONS: The prolonged impairment of corneal nerves, together with chronic inflammation implied by edema, and abnormal increase in CGRP may contribute to a pathological environment for corneal epithelial stem cells, leading to their death and to the development of the SM-induced delayed LSCD.

Delayed loss of corneal epithelial stem cells in a chemical injury model associated with limbal stem cell deficiency in rabbits.

PURPOSE: Ocular injuries following exposure to the chemical agent sulfur mustard (SM) are characterized by acute corneal erosions and inflammation of the anterior segment that may be followed by delayed Partial Limbal Stem Cell Deficiency (LSCD), expressed clinically by corneal neovascularization and epithelial defects. LSCD may derive from direct destruction of limbal stem cells or indirectly from altered limbal stromal niche. The aim of this study was to investigate the mechanism underlying LSCD in SM injuries, focusing on the effects of the chemical on limbal epithelium. METHODS: Rabbit eyes were exposed to SM vapor and were observed by slit lamp examinations and pachymetry. Eyes were taken for histological and molecular biology evaluations at different time points (4 h-4 weeks), to include acute and delayed injuries. Epithelial stem cells were identified by ABCG2, p63 and by in vivo BrdU labeling for slow cycling cells. RESULTS: Limbal stem cells were not damaged during the acute phase following SM exposure, in contrast to the severe injury of the central corneal epithelium. On the contrary, limbal epithelium became activated, responding to corneal insult with a wound healing process, as shown by histology and by transient elevation of the stem cells markers. Simultaneously, inflammation was taking place in the limbal stroma lasting for weeks. A gradual loss of stem cells was observed later-on (2-4 weeks), associated with typical symptoms of LSCD. CONCLUSIONS: LSCD associated with SM ocular toxicity was not derived from a direct cytotoxic effect on the epithelial stem cells, but apparently from pathological events at the limbal stroma, that produced an abnormal microenvironment for the stem cells, triggering their gradual death. The results, and in particular the absence of a primary damage to the epithelial stem cells, indicate the presence of a therapeutic window for intervention to avoid the development of the delayed LSCD.

Lipopolysaccharide induced protection against sulfur mustard cytotoxicity in RAW264.7 cells through generation of TNF-alpha.

Sulfur mustard (HD), a very potent alkylating agent and lipopolysacchride (LPS), are both well characterized inflammatory factors. We have found that concomitant exposure of murine macrophage cells (RAW264.7) to LPS and HD induced protection against HD induced cytotoxicity. Both HD and LPS induce release of inflammatory markers in RAW264.7 cells. However, there are marked differences in the repertoire of inflammatory factors released by the two toxins: While exposure to HD, induced a dose-dependant death of these cells, no significant change in survival rate was observed following LPS (1-100 ng/ml) exposure. Additionally, LPS elicited a robust nitric oxide (NO) and TNF-alpha secretion whereas HD was practically ineffective. Both toxins increased PGE(2) secretion in a concentration dependent manner. Treatment of HD-exposed RAW264.7 cells with anti-inflammatory drugs such as dexamethazone (5 muM), voltaren (diclofenac) (8 muM) or doxycycline (5 muM), decreased the release of cytokines but had no effect on cell viability. Simultaneous application of LPS (100 ng/ml) and HD (20-100 muM) resulted in an amelioration of HD cytotoxicity. Adding the NO generator S-nitrosoglutathione (GSNO) or inhibiting NO production using L-N(G)-monomethyl Arginine, had no effect on cell viability. Moreover, addition of PGE(2) (20 ng/ml) failed to induce any changes in cell viability under basal or HD-induced toxicity. In contrast, TNF-alpha (20 ng/ml) provided remarkable protection against HD-induced cell death. These findings strongly suggest that LPS exerts its protective action against HD toxicity through the generation of TNF-alpha and may provide better understanding of the mechanism of cytoprotection.

Inhalation exposure to sulfur mustard in the guinea pig model: clinical, biochemical and histopathological characterization of respiratory injuries.

Guinea pigs (GP) were exposed (head only) in individual plethysmographs to various concentrations of sulfur mustard vapor, determined online, using FTIR attached to flow chamber. The LCt(50) and the inhaled LD(50) were calculated at different time points post exposure. Surviving animals were monitored for clinical symptoms, respiratory parameters and body weight changes for up to 30 days. Clinical symptoms were noted at 3 h post exposure, characterized by erythematic and swelling nose with extensive mucous secretion (with or without bleeding). At 6 h post exposure most of the guinea pigs had breathing difficulties, rhonchi and dyspnea and few deaths were noted. These symptoms peaked at 48 h and were noted up to 8 days, associated with few additional deaths. Thereafter, a spontaneous healing was noted, characterized by recovery of respiratory parameters and normal weight gain with almost complete apparent healing within 2 weeks. Histopathological evaluation of lungs and trachea in the surviving GPs at 4 weeks post exposure revealed a dose-dependent residual injury in both lung and trachea expressed by abnormal recovery of the tracheal epithelium concomitant with a dose-dependent increase in cellular volume in the lungs. These abnormal epithelial regeneration and lung remodeling were accompanied with significant changes in protein, LDH, differential cell count and glutathione levels in the bronchoalveolar lavage (BAL). It is suggested that the abnormal epithelial growth and cellular infiltration into the lung as well as the continuous lung inflammation could cause recurrent lung injury similar to that reported for HD exposed human casualties.

Ocular injuries following sulfur mustard exposure--pathological mechanism and potential therapy.

Sulfur mustard (SM) is a potent vesicant, known for its ability to cause incapacitation and prolonged injuries to the eyes, skin and respiratory system. The toxic ocular events following sulfur mustard exposure are characterized by several stages: photophobia starting a few hours after exposure, an acute injury phase characterized by inflammation of the anterior segment and corneal erosions and a delayed phase appearing following a clinically silent period (years in human). The late injury appeared in part of the exposed eyes, expressed by epithelial defects and corneal neovascularization (NV), that lead to vision deficits and even blindness. During the last years we have characterized the temporal development of ocular lesions following SM vapor exposure in rabbits and have shown the existence of two sub-populations of corneas, those exhibiting delayed ocular lesions (clinically impaired) and those exhibiting only minor injuries if at all (clinically non-impaired). The aim of the present study was to investigate the pathological mechanism underlying the delayed injury by focusing on the unique characteristics of each sub-population and to test the efficacy of potential treatments. Clinically impaired corneas were characterized by chronic inflammation, increased matrix metalloproteinase (MMP) activity, poor innervation and limbal damage. Moreover, using impression cytology and histology, we identified the delayed lesions as typical for an ocular surface disorder under the category of limbal epithelial stem cell deficiency (LSCD). These results point to therapeutic directions, using anti-inflammatory drugs, MMPs inhibitors, neurotrophic factors and amniotic membrane transplantation. Topical anti-inflammatory drugs, either steroid (Dexamycin, DEX) or non-steroidal anti-infllammatory drug (NSAID, Voltaren Ophtha) were found to be beneficial in ameliorating the initial inflammatory response and in postponing the development of corneal NV, when given during the first week after exposure. When DEX was administered as a symptomatic treatment against NV, a significant regression in the angiogenic process was observed, however, the effect was temporal and blood vessels reappeared after therapy ceased. Chronic administration (8 weeks) of the MMP inhibitor Doxycycline was also effective in attenuation of the acute and delayed injury. Preliminary results, using amniotic membrane transplantation revealed some decrease of corneal edema with no effect on corneal NV. It is suggested that the chronic inflammation and prolonged impairment of corneal innervation are playing a role in the pathogenesis of the delayed LSCD following SM exposure by creating a pathological microenvironment to limbal epithelial stem cells, thus, leading to their slow death and to a second cascade of pathological events eventually resulting in severe long-term injuries. As of today, only topical anti-inflammatory drugs reached the criteria of an applicable efficient post-exposure ocular treatment for SM injuries. Further studies are required to investigate the effects of SM on epithelial stem cells and their involvement in the pathogenesis of the long-term injuries.

Amelioration of sulfur mustard skin injury following a topical treatment with a mixture of a steroid and a NSAID.

The ability to ameliorate sulfur mustard (HD)-induced oedema by treatment with anti-inflammatory drugs was reported previously after screening four steroids and four non-steroidal anti-inflammatory drugs (NSAIDs) using the mouse ear vesicant model. Following the screening study, one steroid and one NSAID (Adexone and Voltaren) were selected as the most effective, and a mixture of the two was chosen for the present more extensive research. The effect of the combined treatment on clinical, biochemical and histopathological parameters following HD insult was studied. Mice ears were exposed to 0.2 micro l of HD for 10 min to produce a moderate skin injury. Oedema development peaked ca. 48 h following exposure, as determined by weighing ear biopsies. Histological observations at that time exhibited damage to the epidermis and dermis. An increase in prostaglandin E (PGE) was measured in skin homogenates, starting 8 h following exposure and lasting at least up to 48 h post-exposure. A topical treatment using the above anti-inflammatory mixture significantly reduced inflammatory parameters when applied up to 4 h following exposure. These parameters included extent of oedema, levels of PGE, area of clinical damage and extent of cytotoxic injury (vesications and damaged epithelial cells). Thus, a combination of a steroid and NSAID was found to be effective in reducing the intensity of HD skin injury and possibly shortening the time to full recovery. The treatment, however, did not prevent completely the ensuing cytotoxic processes in the epithelial layer.

A topical skin protectant against chemical warfare agents.

BACKGROUND: Sulfur mustard and VX are potent chemical warfare agents that penetrate rapidly through the skin, causing severe prolonged injuries and sometimes death. OBJECTIVES: To develop a topically applied pretreatment that will act as a barrier and prevent the absorption of these agents through the skin, reducing morbidity and saving life. METHODS: Several formulations were developed and tested in preclinical animal studies in pigs. The protecting cream was applied as a single application (0.5-1 ml/100 cm2) prior to exposure (10 minutes to 12 hours) to sulfur mustard or VX. Assessment of sulfur mustard-induced skin damage was based on clinical and histologic evaluations. When tested against VX, clinical signs and blood cholinesterase activity were monitored. At the final stage of development, safety studies were conducted in animals and in human volunteers. RESULTS: The formulation that gave the best results, coded IB1 (under patent application), provided significant protection against a 1 hour exposure to sulfur mustard (droplets or vapor). All the pigs pretreated with IB1 cream survived a 1-4 hour challenge of 2xLD50 VX and did not exhibit any overt clinical signs. Protection was exhibited even when the cream was applied 12 hours (single application) prior to exposure. IB1 was found to be non-irritating in animals and humans. No adverse effects were found in a Phase I clinical study in young healthy volunteers when the cream was applied to around 20% of the skin surface (results presented elsewhere). CONCLUSIONS: IB1 cream has been shown to be a safe and effective topical skin protectant against the chemical warfare agents sulfur mustard and VX.