Animal histologic studies have confirmed the presence of Golgi tendon organs, muscle spindles, and myotendinous cylinders within the extraocular muscles,
28 including the LPS of domestic sheep and the moufflon, a wild sheep.
29,30 These specialized structures can detect LPS stretch, and additionally stimulate ipsilateral frontalis recruitment. Fujita et al.
31 have claimed that cell bodies of the trigeminal proprioceptive neurons, that stimulate reflexive contraction of the LPS muscle, are located in the mesencephalic trigeminal nucleus in rats. Human histologic studies have also yielded supporting evidence of eyelid proprioception. Yuzuriha et al.
3,4 found fine neural myelinated structures in MMs of human cadaver eyelids and claimed that these structures act as mechanoreceptors. They concluded that MM is innervated by the unmyelinated sympathetic efferent fibers, as well as by the myelinated trigeminal proprioceptive afferent fibers, both of which run transversely on the proximal MM to join the lacrimal nerve. Yuzuriha et al.
32 stained interstitial cells of Cajal among MM fibers, and suggested that they may serve as mechanoreceptors by both contacting MM fibers and forming associations with trigeminal proprioceptive fibers to induce reflexive contraction of the LPS and frontalis muscles. Vrcek at el.
33 analyzed MM and LPS samples using anti-synaptophysin to label synaptic vesicles in nerve terminals, anti-neurofilament IgG to label nerve fibers, phalloidin to label muscle fibers, and α-bungarotoxin to label motor terminals. They described synaptophysin-positive free nerve terminals within the intermuscular connective tissue of MM. This is anatomically consistent with free nerve endings found in the extraocular muscles that have been implicated in proprioception, although their function is still debated.
34–37 The success of MMCR may be attributed to alterations in the proprioceptive structures, with a resultant change in LPS activity, as well as mechanical correction by means of posterior lamella (conjunctiva and MM) shortening and LPS advancement. Proprioception is suggested as an additional mechanism to maintain eyelid position above the pupillary margin, and to induce eyelid elevation in cases of ptosis. In this surgery, we do not remove the entire MM. Moreover, in failed cases, a repeated procedure commonly helps. Hence, it is possible that the decreased total number of remaining proprioceptive fibers and/or their altered spatial distribution within the postoperative posterior lamella tissue can influence eyelid elevation; the direction of this influence, however, remains unknown. Of note, in some cases, the primary postoperative eyelid position may be the same or even lower than the pre-operative position, even after the edema resolves, whereas the final outcome seen a few weeks later is significantly improved. This may imply a dynamic mechanism, rather than a purely mechanical surgical effect, with a possible “reset” of the neuronal mechanism taking place. Future studies can investigate the presence of remaining fibers in repeated surgeries, and explore whether their amount or anatomic distribution is associated with surgical success.