Four-Dimensional Microscope-Integrated OCT Use in Argus II Placement

Intraoperative OCT-Guided Volumetric Measurements of Subretinal Therapy Delivery in Humans

Purpose: To evaluate a recently developed technique using intraoperative optical coherence tomography (OCT) to measure subretinal tissue plasminogen activator (tPA) volumes in patients with submacular hemorrhage secondary to exudative age-related macular degeneration (AMD). Methods: Three patients (72 to 83 years old) had 25-gauge pars plana vitrectomy, subretinal tPA, and a partial gas fill. An investigational intraoperative OCT system with a modified widefield noncontact indirect viewing apparatus was used to image subretinal tPA blebs. Using the recently developed technique, the volume and surface area in the segmented region of interest were determined. Results: In each case, the delivered tPA volume measured from the syringe differed from the intraoperative OCT-measured subretinal tPA volume: Patient 1, 130 µL from syringe, 118 µL based on intraoperative OCT, 9% difference; Patient 2, 140 µL, 50 µL, 64%; Patient 3, 110 µL, 122 µL, 11%. The total bleb surface area was 129 mm2 in Patient 1, 55 mm2 in Patient 2, and 106 mm2 in Patient 3. Conclusions: This was the first human study to implement and evaluate intraoperative OCT image-based methods to obtain volumetric bleb measurements in patients receiving subretinal tPA for exudative AMD. This proof-of-concept study showed that intraoperative OCT-obtained bleb volume differed from intraoperative recordings, which could be explained by tPA delivery into the vitreous, efflux through the retinotomy, or human error. Intraoperative OCT can provide visualization and quantification of subretinal tPA bleb volume and surface area, which has implications for improved safety, efficacy, and analysis of the effects of subretinal drug delivery.

Artificial Intelligence, Digital Imaging, and Robotics Technologies for Surgical Vitreoretinal Diseases

OBJECTIVE

To review recent technological advancement in imaging, surgical visualization, robotics technology, and the use of artificial intelligence in surgical vitreoretinal (VR) diseases.

BACKGROUND

Technological advancements in imaging enhance both preoperative and intraoperative management of surgical VR diseases. Widefield imaging in fundal photography and OCT can improve assessment of peripheral retinal disorders such as retinal detachments, degeneration, and tumors. OCT angiography provides a rapid and noninvasive imaging of the retinal and choroidal vasculature. Surgical visualization has also improved with intraoperative OCT providing a detailed real-time assessment of retinal layers to guide surgical decisions. Heads-up display and head-mounted display utilize 3-dimensional technology to provide surgeons with enhanced visual guidance and improved ergonomics during surgery. Intraocular robotics technology allows for greater surgical precision and is shown to be useful in retinal vein cannulation and subretinal drug delivery. In addition, deep learning techniques leverage on diverse data including widefield retinal photography and OCT for better predictive accuracy in classification, segmentation, and prognostication of many surgical VR diseases.

CONCLUSION

This review article summarized the latest updates in these areas and highlights the importance of continuous innovation and improvement in technology within the field. These advancements have the potential to reshape management of surgical VR diseases in the very near future and to ultimately improve patient care.

FINANCIAL DISCLOSURE(S)

Proprietary or commercial disclosure may be found in the Footnotes and Disclosures at the end of this article.

What Is the Impact of Intraoperative Microscope-Integrated OCT in Ophthalmic Surgery? Relevant Applications and Outcomes. A Systematic Review

Background: Optical coherence tomography (OCT) has recently been introduced in the operating theatre. The aim of this review is to present the actual role of microscope-integrated optical coherence tomography (MI-OCT) in ophthalmology. Method: A total of 314 studies were identified, following a literature search adhering to the preferred reporting items for systematic reviews and meta-analyses (PRISMA) guidelines. After full-text evaluation, 81 studies discussing MI-OCT applications in ophthalmology were included. Results: At present, three microscope-integrated optical coherence tomography systems are commercially available. MI-OCT can help anterior and posterior segment surgeons in the decision-making process, providing direct visualization of anatomic planes before and after surgical manoeuvres, assisting in complex cases, and detecting or confirming intraoperative complications. Applications range from corneal transplant to macular surgery, including cataract surgery, glaucoma surgery, paediatric examination, proliferative diabetic retinopathy surgery, and retinal detachment surgery. Conclusion: The use of MI-OCT in ophthalmic surgery is becoming increasingly prevalent and has been applied in almost all procedures. However, there are still limitations to be overcome and the technology involved remains difficult to access and use.