Two cases of cartilaginous metaplasia in the sclera of Japanese White rabbits.

Spontaneous cartilaginous metaplasia of the sclera has not been reported in rabbits. Herein, we report two cases of spontaneous cartilaginous metaplasia in the sclera of Japanese White (JW) rabbits. Case 1 was noted in a 14-week-old male Kbs:JW rabbit that received a single ocular instillation of 20% isoproterenol (IP) a day before necropsy, and showed no abnormalities in clinical signs, ophthalmological assessments, and necropsy. Case 2 was noted in a 38-week-old male Kbs:JW rabbit that was housed under light-emitting diode (LED) lighting for 26 weeks and showed no effects of LED on clinical signs, ophthalmological assessments, and necropsy. Histological sections of the eyes of both animals were prepared and stained with hematoxylin and eosin (H&E) and Alcian blue, and immunohistochemical staining for vimentin was performed. The H&E-stained specimens showed focal hyaline cartilage-like tissues distributed between the scleral fibers at the posterior pole in both cases. The surrounding scleral fibers were compressed and/or partially destroyed by the cartilage-like tissue. The cartilage-like matrix was stained blue by Alcian blue, and immunohistochemistry showed that chondrocyte-like cells were positive for vimentin. Based on these findings, we diagnosed cartilaginous metaplasia in the sclera of Kbs:JW rabbits. The lesion was farther from the IP administration site in Case 1 and was not accompanied by other ophthalmological or histopathological abnormalities in either of the cases. This implies that the lesions occurred spontaneously owing to the abnormal differentiation of neural crest-derived cells.

Time-course changes in DNA damage of corneal epithelial cells in rabbits following ocular instillation with genotoxic compounds.

BACKGROUND: In eye-drop drug development, the additional genotoxicity tests in some cases might be necessary to assess genotoxicity in the ocular surface since the ocular surface is exposed directly to high drug concentrations. Recently, an in vivo comet assay using corneal epithelial cells in rabbits following single ocular instillation was developed as an assay to evaluate genotoxicity in ocular tissues. In this study, we investigated the time-course changes in DNA damage after ocular instillation of genotoxic compounds to evaluate the optimal sampling timing for in vivo comet assay of the ocular surface tissue. Ethidium bromide (EtBr), methyl methanesulfonate (MMS), and 4-nitroquinoline 1-oxide (4-NQO) were administered to the eyes of the rabbits. Corneas were collected at 0.5, 2, 4, 6, and 24 h after administration, and the comet assay was performed. In addition, the in vitro comet assay was performed to assess the time-course changes in DNA damage induced by short-time exposure to the genotoxic compounds. RESULTS: The mean % tail DNA, which is an indicator for DNA damage, in the corneal epithelial cells treated with all compounds exhibited statistically significant increases compared with those in the negative controls of saline at 0.5, 2, 4, and 6 h. There was a difference in the DNA damage response between EtBr and the other two compounds. In the 3% MMS- and 1% 4-NQO-treated eyes, the values of the % tail DNA were the highest at 0.5 h and then decreased gradually. In contrast, in the 1% EtBr-treated eyes, the highest value was noted at 4 h. The results of the in vitro comet assay showed that the % tail DNA increased in all groups. A further increase in the % tail DNA occurred in the EtBr-treated cells even after removing the compound but not in the MMS- and 4-NQO-treated cells. CONCLUSION: Relatively high values of the % tail DNA were maintained from 0.5 to 6 h after administration, suggesting that the optimal sampling time is any one point from 0.5 to 6 h in the comet assay of the corneal surface.

Presumed congenital nictitating membrane dysplasia in a Japanese white rabbit.

OBJECTIVE: The present report characterises a spontaneous nictitating membrane abnormality in a Japanese white rabbit. ANIMAL STUDIED: The animal was a male Japanese white rabbit (Oryctolagus cuniculus, Kbs:JW, 10 weeks old at the time of purchase) that had not received any treatment. A morphological abnormality of the nictitating membrane in the animal's right eye was detected. PROCEDURES: Ophthalmological examinations, including slit-lamp biomicroscopy, corneal and conjunctival staining with fluorescein and lissamine green, fundoscopy, blinking rate measurement, Schirmer's tear test, and tonometry were performed. The animal was euthanised at 15 weeks of age, and histopathological examinations of the abnormal nictitating membrane, palpebral conjunctiva, eyelid and eyeball were performed. RESULTS: The tip of the nictitating membrane adhered to the palpebral conjunctiva of the medial canthus. The eye and periocular tissues showed no abnormalities in the ophthalmological examinations, except for the structure of the nictitating membrane. Histopathological examination revealed that the adhered site of the nictitating membrane and the palpebral conjunctiva consisted of dense fibrous connective tissue that was consecutive to the conjunctiva adjacent to the eyelid margin and lamina propria of the nictitating membrane. The fibrous connective tissue was covered with stratified squamous epithelium. CONCLUSION: Based on these results, we diagnosed this abnormal finding as congenital nictitating membrane dysplasia. This paper is the first case report describing a congenital structural abnormality of the nictitating membrane in a Japanese white rabbit.

Histological Features of the Nasal Passage in Juvenile Japanese White Rabbits.

Rabbits are sometimes used for intranasal toxicology studies. We investigated the postnatal development of the nasal passage in juvenile Japanese white rabbits from just after birth to 6-week-old to provide information for conducting intranasal toxicological evaluation using juvenile animals. On postnatal day (PND) 1, the nasal passage consisted of the septum with mostly cartilaginous nasal wall and turbinates. The lining squamous, transitional, respiratory, and olfactory epithelia were already distributed similar to adults and were still underdeveloped. The nasal passage gradually expanded with age, as did the nasal wall, including the turbinates formed by endochondral ossification. The maxilloturbinate elongated, during which it branched complexly. The respiratory epithelium takes the form of columnar epithelium together with a reduction in goblet cells. In addition, the olfactory epithelium had clear cytoplasm in the ethmoturbinate, the olfactory nerve bundles thickened, and Bowman's gland acini increased in size and number. Other tissues, including the vomeronasal organ, nasal-associated lymphoid tissue, and nasolacrimal duct, also developed histologically with age. This investigation characterized the postnatal histological development of the nasal passage in Japanese white rabbits, providing basic knowledge regarding the histological examination and rationale for appropriate study design of intranasal toxicology studies in juvenile rabbits.

Orbital malignant schwannoma and embryonal rhabdomyosarcoma in rats caused by leakage of locally injected nickel subsulfide to the orbit.

Nickel subsulfide (Ni3S2) is known to induce intraocular neoplasms when injected intravitreally into the eyes of rats. Here, we found two extraocular orbital neoplasms in two different rat strains, presumably due to the leakage of locally injected Ni3S2 to the extraocular orbital tissues. In the F344/DuCrlCrlj rat, an orbital mass arose at 30 weeks after injection, and invaded into the cranium. Histologically, the orbital mass was composed of areas arranged in parallel bundles formed by densely packed elongated or spindle-shaped cells with indistinct cytoplasmic borders, and of areas of hypocellular arrangement consisting of round cells in eosinophilic myxoid-like substances. Metastases were observed in the right submandibular and cervical lymph nodes. The neoplastic cells were immunopositive for S-100 protein and vimentin. Transmission electron microscopy revealed that the neoplastic cells had cellular processes and pericytoplasmic basal laminae. In the RccHanTM:WIST rat, an orbital mass arose at 36 weeks after injection. Histologically, the mass consisted of rhabdoid-like large round cells with proliferation of small round-to-polygonal cells, and these neoplastic cells infiltrated into the extraocular muscles. Immunohistochemically, the neoplastic cells were positive for desmin and vimentin. Transmission electron microscopy detected immature myofibrils with Z-band structures in the cytoplasm of these neoplastic cells. Consequently, the tumors were diagnosed as an orbital malignant schwannoma in an F344/DuCrlCrlj rat and an orbital embryonal rhabdomyosarcoma in a RccHanTM:WIST rat. The results of this case report suggest that leakage of Ni3S2 to the orbit caused the induction of orbital malignant schwannoma or rhabdomyosarcoma in rats.

In vivo comet assay in rabbit corneal epithelial cells following ocular instillation with genotoxic compounds.

BACKGROUND: The in vivo comet assay is used to evaluate the genotoxic potential of compounds by detecting DNA strand breaks in cells isolated from animal tissue. The comet assay of hepatocytes is well established; however, the levels of systemic drug exposure following systemic administration are often insufficient to evaluate the genotoxic potential of compounds on the ocular surface following ocular instillation. To investigate the possibility of using the comet assay as a genotoxic evaluation tool for the ocular surface, we performed this assay on the corneal epithelial cells of rabbit eyes 2 h after the single ocular instillation of five genotoxic compounds, namely ethidium bromide, 1,1'-dimethyl-4,4'-bipyridinium dichloride (paraquat), methyl methanesulfonate (MMS), acrylamide, and 4-nitroquinoline 1-oxide (4-NQO). RESULTS: The mean % tail DNA, as an indicator of DNA damage, in the corneal epithelial cells treated with ethidium bromide, MMS, and 4-NQO exhibited statistically significant increases compared with those in the negative controls (saline or 5 % dimethyl sulfoxide in saline). However, paraquat and acrylamide did not increase the mean % tail DNA, presumably because of the high antioxidant levels and low cytochrome P450 levels present in the corneal epithelium, respectively. CONCLUSIONS: The comet assay was able to detect genotoxic potential on the ocular surface following ocular instillation with genotoxic compounds. The study findings indicate that the in vivo comet assay may provide a useful tool for assessing the genotoxicity of compounds topically administrated on the ocular surface under mimicking clinical condition.

Investigation of in vivo unscheduled DNA synthesis in rabbit corneas following instillation of genotoxic agents.

PURPOSE: An unscheduled DNA synthesis (UDS) test is used for in vitro or in vivo genotoxicity evaluation. The UDS test with hepatocytes is well established; however, drug exposure levels at the application site for topically administered drugs (e.g. ophthalmic drugs) often exceed the exposure levels for systemic administration. To establish in vivo genotoxicity on the ocular surface, we performed the UDS test using rabbit corneas from eyes subjected to instillation of genotoxic agents. MATERIALS AND METHODS: Five genotoxic agents - 1,1'-dimethyl-4,4'-bipyridinium dichloride (paraquat); acridine orange; ethidium bromide; acrylamide; and 4-nitroquinoline 1-oxide (4-NQO) - were instilled once onto both eyes of male Japanese white rabbits. Physiological saline or a general vehicle for ophthalmic solution were instilled as the negative controls. Dimethyl sulfoxide was instilled as the vehicle control. Isolated corneas were incubated with tritium-labelled thymidine and the number of sparsely labelled cells (SLCs, cells undergoing UDS) was counted by autoradiography. RESULTS: Statistically significant increases in the mean appearance rates of SLCs in the corneal epithelium were noted in paraquat-, acridine orange-, ethidium bromide-, and 4-NQO-treated eyes compared with those of the controls. These increases generally appeared in a dose-dependent manner. Acrylamide did not induce an increase in the mean appearance rates of SLCs, presumably because it caused the generation of fewer metabolites in the cornea. CONCLUSIONS: UDS tests revealed DNA damage in the cornea epitheliums treated with well-known genotoxic agents. These results suggest that the UDS test is one of the useful tools for the assessment of in vivo genotoxicity on the ocular surface in the development of ophthalmic drugs.

Histological Features of Postnatal Development of the Eye in White Rabbits.

Rabbits are frequently used in studies assessing the toxicity of ophthalmic drugs; however, the postnatal histological changes that occur in the rabbit eye have not been fully described. To characterize postnatal ocular development in white rabbits, a histological investigation of the eyes and eyelids was sequentially performed between postnatal days (PNDs) 1 and 42. The eyes opened during PNDs10 to 12. Significant changes prior to eyelid opening included the proliferation of uveal and optic nerve cells, regression of the lenticular vasculature, and thinning of the retina with a decreasing number of retinal cells. After eyelid opening, several significant changes occurred in the anterior segment, including thickening of the cornea and the development of lacrimation-related tissues in the eyelid and conjunctiva. Additionally, the differentiation of retinal layer-derived cells and optic nerve thickening occurred. The lens size continued to increase throughout the postnatal period. The histological structure of the eyes and eyelids was nearly mature by PNDs28 to 42. This study characterizes the postnatal changes in the histological features of the eyes in juvenile white rabbits, providing fundamental knowledge on the appropriate design of histological studies of the eyes in juvenile rabbits, particularly ophthalmic drug evaluations.

Investigation of comet assays under conditions mimicking ocular instillation administration in a three-dimensional reconstructed human corneal epithelial model.

Purpose: A comet assay is one of the genotoxicity methods for evaluating the potential of chemicals to induce DNA strand breaks. To investigate the usefulness of comet assays for evaluating the genotoxic potential of ophthalmic solutions, a three-dimensional (3D) reconstructed human corneal epithelial model (3D corneal model) was exposed to conditions mimicking topical ocular instillation administration. Methods: The 3D corneal model was exposed to acridine orange, ethidium bromide, hydrogen peroxide, 1,1'-dimethyl-4,4'-bipyridinium dichloride (paraquat), 4-nitroquinoline 1-oxide (4-NQO), acrylamide and methyl methanesulfonate (MMS). To mimic the ocular surface condition to which ophthalmic solutions are administered, the exposure time was set to 1 minute. Likewise, human corneal epithelial (HCE-T) cells, as monolayer cultured cells, were exposed to the same chemicals, for comparison. Results: In the 3D corneal model, the amount of DNA fragments was statistically significantly increased in cells treated with each of the test chemicals except acrylamide. In HCE-T cells, the amount of DNA fragments was statistically significantly increased in acridine orange-, ethidium bromide-, hydrogen peroxide-, 4-NQO- and MMS-treated cells but not in paraquat- or acrylamide-treated cells. In the 3D corneal model, the lowest concentrations at which we observed DNA damage were about 100 times higher than the concentrations in HCE-T cells. Since the 3D corneal model is morphologically similar to human corneal tissue, form a multilayer and having tight junctions, it may be that the test chemicals only permeated about 1% into the 3D corneal model. Conclusion: These results suggest that the comet assay using 3D cell culture models may reflect in vivo conditions better than do monolayer cultured cells, and that the comet assay may be useful for the evaluation of genotoxic potential of topical ophthalmic solution.

Pathological Features of Corneal Phospholipidosis in Juvenile White Rabbits Induced by Ocular Instillation of Chloroquine or Amiodarone.

Cationic amphiphilic drugs (CADs) can induce phospholipidosis (PLD) in organs/tissues. Several ophthalmic pharmaceuticals containing CADs are marketed and used in children. To investigate the effect of PLD on the developing cornea, chloroquine and amiodarone, which are representative CADs, were applied topically to the eyes of juvenile rabbits, and the effects in juvenile rabbits were compared with those in young adult rabbits. Diffuse corneal cloudiness was observed in chloroquine- and amiodarone-treated eyes. Histopathologically, vacuolation was observed in the corneal epithelium and keratocytes. On ultrastructural examination, these vacuoles contained multilamellar inclusion bodies, which are a characteristic of PLD. The size of the vacuoles in the corneal epithelium was reduced in juveniles compared with young adults. Cytoplasmic lamellar bodies and exocytosis in the corneal endothelium were observed in young adult rabbits but not in juvenile rabbits. This study revealed that topical application of chloroquine or amiodarone induces corneal PLD in juvenile and young adult rabbits. Corneal endothelial changes occurred only in young adult rabbits, but ophthalmological changes were similar between juveniles and young adults. The results of the study suggest that the effects of corneal PLD were similar among age groups based on risk assessment.

Absence of histopathological changes in the retina of zebrafish treated with sodium iodate.

In ophthalmological research, the use of zebrafish to investigate visual behaviors has been increasing, but can produce misleading, false-positive results if compounds adversely affect their motor functions or central nervous system. Therefore, histological analysis to identify a target organ is important in zebrafish toxicity assay. We investigated the retinal degeneration in zebrafish, using typical retinal toxicants, mainly sodium iodate and N-methyl-N-nitrosourea (MNU). No histopathological changes were found after sodium iodate exposure at 1.0 mM for 5 or 7 days in the retina of larval, juvenile, and adult zebrafish. There were also no obvious histopathological changes in the retina of adult zebrafish at 0.1 mM, even after 30 days treatment with sodium iodate. In addition, many proliferating cell nuclear antigen-positive cells were found not only in the ciliary marginal zone, but also in the outer nuclear layer, especially in larval and juvenile zebrafish with or without sodium iodate exposure. However, the concentrations of iodine in the blood and the eyeballs of adult zebrafish increased remarkably after the treatment. General retinal damage emerged after MNU exposure at 150 mg/l for 60 min in adult zebrafish, but first pyknotic cells appeared in the inner nuclear layer and the ganglion cell layer. Our findings indicate that zebrafish retina have a different reactivity pattern from mammalian animals against some retinal toxicants, and in them it is difficult to detect histopathological changes.

Characteristics of corneal phospholipidosis induced by topical ocular application of chloroquine and amiodarone in rabbits.

Several cationic-amphiphilic drugs such as chloroquine and amiodarone are known to induce phospholipidosis in the cornea by systemic administration. However, the characteristics of ophthalmological and pathological changes when phospholipidosis-inducing drugs are topically applied have not been well studied. This study was conducted to investigate the characteristics of corneal changes caused by topical application of chloroquine and amiodarone to Japanese white rabbits. The changes were evaluated by ophthalmological, histopathological, and ultrastructural examinations. An in vivo confocal microscopy was also applied to the chloroquine-treated corneas. In both chloroquine- and amiodarone-treated corneas, diffuse cloudiness was observed by slit-lamp biomicroscopy, and its transparency increased with duration of dosing. Confocal microscopy showed punctate dots in the corneal epithelium. Histopathologically, cytoplasmic vacuolation was found in the corneal epithelium and keratocytes in both chloroquine- and amiodarone-treated eyes. Furthermore, foamy cytoplasm of the corneal endothelium was observed in the chloroquine-treated eyes. Ultrastructural examination showed multi-lamellar inclusion bodies or membrane-like debris in the lysosome-like vacuoles in the cytoplasm of corneal cells, which is a characteristic of the lesions of phospholipidosis. These changes disappeared after a withdrawal period. Continuous dosing of chloroquine resulted in corneal erosion and focal corneal opacity as shown by gross observation and slit-lamp biomicroscopy. Confocal microscopy could detect the corneal changes prior to the appearance of these ophthalmological changes. The present study showed that phospholipidosis caused by ocular administration of chloroquine and amiodarone first induces reversible diffuse corneal cloudiness. Confocal microscopy is a useful method for monitoring induction of corneal phospholipidosis.