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Tenon's capsule

Tenon's capsule, also known as the fascial sheath of the eyeball or bulbar sheath, is a thin, dense, and translucent fascial membrane that envelops the posterior two-thirds of the eyeball, extending posteriorly from the sheath to fuse anteriorly with the approximately 3 mm posterior to the corneoscleral limbus. This structure, named after the French surgeon Jacques René Tenon who described it in 1805, consists primarily of and fibers and is nearly avascular, providing a smooth, shiny inner surface separated from the by the episcleral or sub-Tenon , a potential lymph-filled compartment. Anatomically, Tenon's capsule is divided into an anterior portion, which is thicker and contains fibers forming an orbital smooth muscle network, and a posterior portion, which is thinner, more translucent, and composed of condensed without , enveloping the up to the . It fuses with the approximately 3 mm posterior to the limbus anteriorly and with the dural sheath of the posteriorly, while enclosing the extraocular rectus and muscles at points about 10 mm behind their insertions, thereby functioning as a system for efficient transmission during eye movements. The capsule's primary roles include acting as a protective socket that isolates the globe from intraconal and extraconal orbital fat, enabling frictionless rotation of the eyeball, and maintaining structural integrity during ocular motility. Clinically, Tenon's capsule is significant in procedures such as sub-Tenon anesthesia, where the space beneath it allows to the globe, and in surgeries like correction, where its integrity prevents complications such as fat prolapse or scarring; it also thins with age, potentially affecting surgical outcomes.

Overview

Definition and Location

Tenon's capsule, also known as the fascia bulbi, bulbar sheath, or Tenon's fascia, is a thin, fibrous that envelops the eyeball, extending to the corneoscleral limbus anteriorly to the sheath of the posteriorly. As the innermost layer of the orbital , it forms a socket-like structure for the globe, separating the eyeball from the surrounding orbital fat and providing a between the capsule and the . Anteriorly, the capsule fuses with the bulbar near the limbus and extends into the fornices, while posteriorly it adheres to the near the globe's equator before blending with the dural sheath of the ; additionally, it forms sleeves around the insertions of the , allowing their passage through the structure.

Etymology and History

Tenon's capsule is named after the and pathologist Jacques René Tenon (1724–1816), who provided the first detailed description of this fascial structure. Tenon made his original observations during dissections in the late , identifying the capsule as a distinct fascial layer enveloping the eyeball, separate from surrounding orbital tissues. He documented these findings in his seminal 1806 publication, Mémoires et observations sur l'anatomie, la pathologie et la chirurgie, presented to the Institut National de France, where he emphasized its role as a protective envelope facilitating ocular mobility. Early 19th-century anatomical literature recognized Tenon's capsule primarily as a simple membranous , but subsequent refinements in the late 19th and 20th centuries highlighted its integrations with extraocular muscle sheaths and orbital , enhancing understanding of its structural complexity. This evolution is evident in authoritative texts such as , which from its 20th edition onward (and in later iterations like the 1918 American edition) described the capsule's fibrous composition and attachments in greater detail, solidifying its place in orbital .

Anatomy

Gross Anatomy

Tenon's capsule is a thin, loose-fitting fascial sac that envelops the posterior two-thirds of the eyeball, forming a protective socket within the . It extends posteriorly to fuse with the dural of the and anteriorly to the corneoscleral limbus, fusing with the at the limbus and with the approximately 3 mm posterior to it. This structure indirectly lines the orbital walls through fibrous reflections, separating the globe from the surrounding periorbital fat and enabling smooth gliding of the eyeball. The capsule features distinct anterior and posterior divisions. The anterior portion, located near the limbus, is thicker and more fibrous, extending to the of the . In contrast, the posterior portion is thinner and more translucent, covering the toward the . Between the inner surface of the capsule and the outer scleral surface lies the episcleral space, a potential cavity that facilitates mobility. Fibrous septa arise from the capsule and extend to the extraocular rectus muscles, forming sleeve-like sheaths around their tendons. These sleeves fuse with the at the rectus muscle insertions and connect posteriorly to the sheath via condensations of . Such attachments maintain the capsule's spatial relationships, positioning it as an intermediary layer between the and orbital contents.

Histology and Composition

Tenon's capsule exhibits a biphasic histological structure, with the anterior portion consisting of thick fibrous tissue rich in bundles and interspersed with a network of orbital fibers. This anterior region also incorporates elastic fibers, contributing to its density and resilience. In contrast, the posterior portion is a thin, translucent layer composed of condensed , providing a that separates the from orbital fat. These components are arranged parallel to the scleral surface, forming a compact fascial layer without significant glandular or epithelial elements. The vascular supply to Tenon's capsule is sparse, rendering it nearly avascular overall, with small perforating vessels derived from the that supply the anterior segments. Lymphatic drainage occurs through channels within the periscleral space, ultimately directing to the orbital lymph nodes. Innervation is provided by sensory branches of the ophthalmic division of the (CN V), which enter via the long and short posterior ciliary nerves, conveying proprioceptive and nociceptive signals. Developmentally, Tenon's capsule arises from mesodermal condensations surrounding the optic vesicle, establishing a continuous fascial layer by the eighth week of as the and extraocular structures differentiate.

Function

Support and Positioning

Tenon's capsule serves as a socket for the eyeball, enveloping the from the to the limbus and separating it from the surrounding orbital fat to form a lubricated . This arrangement creates a between the capsule and the , containing , which functions like a , cushioning the eye against the orbital fat and preventing adhesions during passive movements. As a protective barrier, Tenon's capsule shields the from direct pressure exerted by the orbital contents, thereby reducing friction on the 's surface. It maintains structural integrity between the and intraconal fat. In terms of positioning, Tenon's capsule stabilizes the within the bony through fascial condensations that anchor it posteriorly to the and anteriorly near the limbus, ensuring central alignment independent of extraocular . These condensations form a supportive framework that suspends the eye, limiting excessive displacement while allowing smooth mobility. Additionally, Tenon's capsule contributes to orbital volume management by acting as an elastic reservoir, its fibrous and elastic composition—primarily and fibers—enabling adaptation to changes in orbital volume or minor without compromising position.

Role in Ocular Motility

Tenon's capsule plays a crucial role in ocular motility by incorporating posterior condensations that function as fibrous pulleys for the rectus . These pulleys, consisting of dense rings of , , and embedded within the capsule near the 's , serve as the effective proximal insertion for the orbital layer of the muscles, while the global layer inserts directly onto the . First described by Jacques René Tenon in 1806, the pulleys redirect muscle forces to optimize rotational vectors, constraining paths to prevent lateral slippage and aligning movements within Listing's plane for efficient gaze shifts. The capsule further reinforces muscle action through intermuscular and intrinsic fibers, which enhance tension and elasticity during dynamic eye movements. These , extending from the capsule to connect muscles with orbital walls, form a supportive framework that stabilizes the and facilitates low-friction gliding, particularly as the muscles sleeve through the capsule's perforations. Anterior fibers within the capsule actively adjust pulley positions along the muscle axis, providing adaptive elasticity that supports rapid saccades and tracking by maintaining coordinated force transmission. Alterations in capsule elasticity contribute to restrictive strabismus patterns, where adhesions or scarring between muscles and the capsule limit duction, often following surgical recession or resection. Preserving Tenon's integrity during these procedures is essential for favorable outcomes, as disruptions can lead to persistent restrictions by altering the low-friction interface and connective tissue balance. Biomechanically, Tenon's capsule integrates the globe with orbital walls via its pulley attachments and fascial extensions, coupling movements to avert slippage in extreme gazes and ensuring stability across the visual field. This connective framework also underlies pattern strabismus, such as A-pattern deviations, where minor oblique pulley displacements—typically less than 2 mm—shift vertical force components, resulting in incomitant elevation or depression without primary oblique muscle involvement.

Clinical Significance

Local Anesthesia

The sub-Tenon's space, a potential compartment formed between Tenon's capsule and the due to the capsule's loose attachment to the underlying , serves as a targeted site for injecting local anesthetics in ocular . This space allows for the administration of agents such as 2% lidocaine alone or in combination with 0.5-0.75% bupivacaine, typically in volumes of 2-5 ml, to achieve analgesia and akinesia through posterior diffusion into the retro-orbital area. The procedure involves positioning the patient , cleaning the with , and creating access via a small conjunctival incision, often in the inferonasal quadrant 5-6 mm posterior to the limbus. A blunt-ended , such as a 21-gauge Rycroft or sub-Tenon cannula, is then inserted to follow the globe's curvature past the , enabling slow injection of the while minimizing . This method facilitates rapid along extraocular muscle sheaths, producing akinesia and analgesia within 3-5 minutes without the need for sharp that could risk optic nerve perforation or globe injury associated with retrobulbar techniques. Sub-Tenon's anesthesia offers several advantages over peribulbar or retrobulbar blocks, including a reduced incidence of complications such as orbital hemorrhage, subarachnoid injection, and elevated spikes, with studies demonstrating safer profiles using smaller anesthetic volumes. It is commonly employed in extraction, procedures, and vitreoretinal surgeries, particularly for elderly patients with comorbidities. A survey of over 180,000 cases reported rare serious adverse events, underscoring its favorable safety. Originally described in 1884, sub-Tenon's block gained popularity in the 1990s following the introduction of a safer blunt cannula technique by Mein and colleagues, establishing it as a preferred alternative to traditional methods with evidence of faster onset and lower postoperative complications.

Inflammation and Infections

Inflammation of Tenon's capsule, known as tenonitis, is a rare condition often manifesting as a component of idiopathic orbital inflammation (IOI) or periscleritis, characterized by infiltration of inflammatory cells into the capsule and adjacent structures. This inflammation typically presents with abrupt orbital pain, proptosis, restricted extraocular motility, periorbital swelling, and tenderness, without systemic signs such as fever, distinguishing it from infectious processes. Risk factors include prior ocular trauma, recent surgery, or underlying systemic diseases like rheumatologic disorders, though many cases remain idiopathic. A variant termed posterior tenonitis involves the posterior portion of the capsule and may overlap with posterior , leading to globe displacement, , and eyelid edema, sometimes accompanied by or . Diagnosis relies on , such as MRI revealing capsule thickening or ultrasonography detecting the "T sign" from fluid accumulation in Tenon's space, which helps differentiate it from other orbital pathologies. Infectious involvement of Tenon's capsule is exceptionally rare and typically aggressive, progressing to in immunocompromised individuals. For instance, cases have been reported in children with and associated undergoing surgery, where lymphopenia exacerbates postoperative bacterial invasion, resulting in rapid capsule necrosis, severe pain, proptosis, and purulent discharge. Similarly, necrotizing infections from group A Streptococcus or have occurred post-surgery or in atypical presentations, causing extensive tissue destruction without initial systemic fever but leading to globe displacement and vision-threatening complications. The capsule's vascular supply may facilitate bacterial spread in these scenarios.

Surgical Applications

Tenon's capsule serves as a versatile autologous tissue source in ocular , particularly for reconstructive procedures requiring and minimal . In the of small corneal , typically 1-3 mm in diameter, a Tenon's patch graft is harvested from the superonasal or superotemporal , slightly larger than the defect, and secured over the site with and sutures to plug the and promote re-epithelialization over 2-3 weeks. This technique achieves anatomical stability in 80-90% of cases, allowing subsequent visual via lenses or keratoplasty, as reported in comprehensive 2021 reviews of outcomes. A 2024 further confirmed the efficacy of Tenon's patch grafts, with anatomical success rates exceeding 85% across various studies. In glaucoma surgery, such as , advancement of Tenon's capsule over the filtering bleb enhances coverage and reduces the risk of postoperative leaks and infections by promoting vascularized tissue integration. This approach mitigates the pro-fibrotic behavior of Tenon's , which can lead to excessive scarring; intraoperative application of mitomycin-C at 0.4 mg/mL for 3-5 minutes is employed to inhibit while preserving bleb function. Studies demonstrate significantly lower rates of avascular blebs (26.9% versus 64.5%) and late-onset leaks (0.6% versus 4.7%) with fornix-based flaps incorporating Tenon advancement compared to traditional limbus-based techniques. As of 2025, a modified technique with direct filtration into Tenon's capsule has been described, potentially improving filtration efficiency and reducing complications. In surgery and ocular implant procedures, closure of Tenon's capsule is performed, with postoperative changes in capsule thickness observed to correlate with corrective effects, though may affect tissue restoration. In port delivery system implants for conditions, the capsule is dissected subconjunctivally to expose , and upon closure, it is reapproximated with the using 8-0 sutures to seal the peritomy site securely. In repairing penetrating ocular trauma, autologous Tenon's capsule is packed into posterior exit wounds using during , providing immediate and structural reinforcement to maintain retinal apposition and . This method effectively closes full-thickness defects, such as spindle-shaped holes, with the graft integrating over time and preventing complications like leakage following gas-liquid exchange. Best practices for conjunctiva-Tenon interactions emphasize atraumatic with blunt to create a wide sub-Tenon's plane, minimizing tissue trauma during vitreoretinal or procedures, followed by layered reapproximation with absorbable sutures to reduce postoperative scarring and ensure conjunctival mobility. Anchoring sutures at the limbus with partial-thickness scleral bites during closure compensates for potential retraction, promoting a watertight seal and limiting fibrotic responses.

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