Treatment of herpes zoster related corneal neovascularisation and lipid keratopathy by photodynamic therapy

Photodynamic therapy-a promising treatment of oral mucosal infections

The treatment of oral mucosal infections is increasingly challenging owing to antibiotic resistance. Therefore, alternative antimicrobial strategies are urgently required. Photodynamic therapy (PDT) has attracted attention for the treatment of oral mucosal infections because of its ability to effectively inactivate drug-resistant bacteria, completely heal clinical infectious lesions and usually offers only mild adverse reactions. This review briefly summarizes relevant scientific data and published papers and discusses the potential mechanism and application of PDT in the treatment of oral mucosal infections.

Lipid Keratopathy: A Review of Pathophysiology, Differential Diagnosis, and Management

Lipid keratopathy is a disease in which fat deposits accumulate in the cornea, leading to opacification and decrease of visual acuity. This condition can be idiopathic without signs of previous corneal disease or secondary to ocular or systemic diseases. Lipid keratopathy is usually associated with abnormal vascularization of the cornea, and the lipid classically deposits adjacent to these vessels. Treatment of this condition usually aims to eliminate or prevent abnormal vessel formation, and several modalities have been described. In this review we summarize the etiology, pathophysiology, and clinical presentation of lipid keratopathy and describe current and emerging treatment regimens.

Lipid keratopathy and septal abscess: Case report

RATIONALE

Epistaxis is a common otorhinolaryngological emergency, but septal abscess has not been reported before as a complication of epistaxis.

PATIENT CONCERNS

We report a case of a 51-year-old man complaining of nasal obstruction and facial numbness for 3 weeks. He had a history of epistaxis, and had been treated with electrocauterization of the left nasal septum at a local clinic 1 month earlier.

DIAGNOSES

On nasal endoscopy, swelling of the septum was noticed; computed tomography (CT) was performed, and revealed a septal abscess.

INTERVENTIONS

The patient was treated with incision and drainage under local anesthesia. A left vertical hemitransfixion incision was made and 4 mL of purulent material was drained. There was no quadrangular septal cartilage.

OUTCOMES

On the 5th postoperative day, the patient complained of blurred vision in his right eye. Visual acuity of the left eye was 0.5, but acuity of the right eye was finger count at 50 cm. Examination of the right eye revealed a whitish fan-shaped corneal opacity on the medial side with neovascularization, diagnostic of lipid keratopathy.

CONCLUSION

Electrocautery of epistaxis should be performed carefully during hemostasis, and there should be careful follow-up after the procedure to detect the occurrence of septal hematoma or septal abscess. These conditions should be treated as early as possible to avoid further serious complications. Since lipid keratopathy is difficult to treat once it occurs, care should be taken to avoid a septal abscess.

In Vivo Confocal Microscopic Study of Hard Contact Lens-Induced Lipid Keratopathy Secondary to Corneal Neovascularization in a Rabbit Hypercholesterolemic Model

OBJECTIVES

In vivo confocal microscopy was used to observe the morphological presentations and anatomical correlations between corneal neovascularization (NV) and intracorneal lipid deposition in a rabbit model of contact lens (CL)-induced lipid keratopathy secondary to corneal NV.

METHODS

Rabbits were divided into 3 groups: (1) 8-week normal diet, (2) 8-week high-cholesterol diet, and (3) 4-week normal diet followed by 4-week high-cholesterol diet. Corneal NV was induced by closed-eye CL. The formation and maturation of corneal NV were shown by immunohistochemical staining against CD31 and high-molecular-weight melanoma-associated antigen. In vivo confocal microscopy identified corneal NV and lipid deposition. Acquired images for each eye were arranged and mapped into subconfluent montages.

RESULTS

In group 1, corneal NV sprouting formed from the peripheral to the central cornea by the end of week 4. Pericytes around vessels were shown after 2 weeks of CL wear. In group 2, lipid deposition started from the peripheral cornea and progressively covered the whole cornea. In group 3, lipid deposition was found first in the central cornea after 2 weeks of high-cholesterol diet and progressed to cover the peripheral cornea. In vivo confocal microscopy demonstrated four different patterns of intracorneal lipid deposition: spindle shapes arranged randomly or in parallel, amorphous shapes, multiangular shapes, and mixed types. Intracorneal lipid deposition was distributed from basal corneal epithelium to deep stroma.

CONCLUSIONS

Intracorneal lipids tend to accumulate around newly formed corneal NV but can extend to the area covered with mature NV. In vivo confocal microscopy can demonstrate various shapes and depths of intracorneal lipid deposition.