Macular hole formation, progression, and surgical repair: case series of serial optical coherence tomography and time lapse morphing video study

To assess the potential of a new diagnostic technique called optical coherence tomography for imaging macular disease. Optical coherence tomography is a novel noninvasive, noncontact imaging modality which produces high depth resolution (10 microns) cross-sectional tomographs of ocular tissue. It is analogous to ultrasound, except that optical rather than acoustic reflectivity is measured. Optical coherence tomography images of the macula were obtained in 51 eyes of 44 patients with selected macular diseases. Imaging is performed in a manner compatible with slit-lamp indirect biomicroscopy so that high-resolution optical tomography may be accomplished simultaneously with normal ophthalmic examination. The time-of-flight delay of light backscattered from different layers in the retina is determined using low-coherence interferometry. Cross-sectional tomographs of the retina profiling optical reflectivity versus distance into the tissue are obtained in 2.5 seconds and with a longitudinal resolution of 10 microns. Correlation of fundus examination and fluorescein angiography with optical coherence tomography tomographs was demonstrated in 12 eyes with the following pathologies: full- and partial-thickness macular hole, epiretinal membrane, macular edema, intraretinal exudate, idiopathic central serous chorioretinopathy, and detachments of the pigment epithelium and neurosensory retina. Optical coherence tomography is potentially a powerful tool for detecting and monitoring a variety of macular diseases, including macular edema, macular holes, and detachments of the neurosensory retina and pigment epithelium.

To update the biomicroscopic classification and anatomic interpretations of the stages of development of age-related macular hole and provide explanations for the remarkable recovery of visual acuity that occurs in some patients after vitreous surgery. Recent biomicroscopic observations of various stages of macular holes are used to postulate new anatomic explanations for these stages. Biomicroscopic observations include the following: (1) the change from a yellow spot (stage 1-A) to a yellow ring (stage 1-B) during the early stages of foveal detachment is unique to patients at risk of macular hole; (2) the prehole opacity with a small stage 2 hole may be larger than the hole diameter; and (3) the opacity resembling an operculum that accompanies macular holes is indistinguishable from a pseudo-operculum found in otherwise normal fellow eyes. The change from a yellow spot (stage 1-A) to a yellow ring (stage 1-B) is caused primarily by centrifugal displacement of retinal receptors after a dehiscence at the umbo. The hole may be hidden by semiopaque contracted prefoveolar vitreous cortex bridging the yellow ring (stage 1-B occult hole). Stage 1-B occult holes become manifest (stage 2 holes) either after early separation of the contracted prefoveolar vitreous cortex from the retina surrounding a small hole or as an eccentric can-opener-like tear in the contracted prefoveolar vitreous cortex, at the edge of larger stage 2 holes. Most prehole opacities probably contain no retinal receptors (pseudo-opercula). Surgical reattachment of the retina surrounding the hole and centripetal movement of the foveolar retina induced by gliosis may restore foveal anatomy and function to near normal.

To establish the sequence of events leading from vitreofoveal traction to full-thickness macular hole formation. Both eyes of 76 patients with a full-thickness macular hole in at least 1 eye were examined by biomicroscopy and optical coherence tomography. Sixty-one fellow eyes had a normal macula. Optical coherence tomograms showed central detachment of the posterior hyaloid over the posterior pole in 19 cases (31%) and a perifoveal hyaloid detachment not detected on biomicroscopy in 26 cases (42%). In the 4 impending macular holes, optical coherence tomography disclosed various degrees of intrafoveal split or cyst, with adherence of the posterior hyaloid to the foveal center and convex perifoveal detachment. In the 14 stage 2 holes, eccentric opening of the roof of the hole was observed, and in the 24 stage 3 holes, the posterior hyaloid was detached from the entire posterior pole. In fellow eyes of eyes with macular holes posterior hyaloid detachment begins around the macula, but the hyaloid remains adherent to the foveolar center, indicating the action of anteroposterior forces. This results in an intraretinal split evolving into a cystic space, and then to the disruption of the outer retinal layer and the opening of the foveal floor, thus constituting a full-thickness macular hole.