The sclera is the outermost coat of the eyeball and provides structural support and protection for intraocular structures. In contrast to the other coats, the sclera is hypovascular, hypocellular, and composed of dense con-nective tissue. Histologically, it consists of interwoven collagen fibrils and a dense extracellular matrix. Scleral rigidity is imparted by glycation-induced cross-linking of collagen fibrils.1 Despite a low metabolic activity, the sclera undergoes remodeling throughout life. For example, fibroblastic activity and increased scleral thickness have been reported in response to thermal stimuli.2 Scleral metabolism plays an integral role in emmetropization by precisely regulating the growth of the extracellular matrix, suggesting that the sclera is metabolically active.3 Although sparsely populated, scleral fibroblasts can be activated to proliferate after injury, pathology, or infection.4
Treatment of benign and malignant intraocular (e.g., uveal, retinal, neural) tumors as well as extraocular (e.g., ocular surface and orbital) often require episcleral or trans-scleral modalities. Therefore, scleral toxicity can be an adverse effect, manifesting as scleral thinning or scleral melt. In addition, these tumors can directly invade and thus weaken the sclera in select cases. Resultant scleral thinning can lead to perforation and expulsion of intraocular contents. Early diagnosis and appropriate management can prevent the consequences of scleral toxicity.
This chapter discusses the various mechanisms of scleral toxicity, scleral complications of cancer therapy, indications, and techniques of scleral repair.