Three-dimensional laparoscopy: is it as good as it looks?—a review of the literature

Introduction

Laparoscopy enabled the advent of minimally invasive surgery, encompassing many advantages such as smaller surgical wounds, less postoperative pain and shorter hospital stays (1,2). However, it also has its unique limitations (3); one of them being loss of depth perception and surgeons need to acquire the psychomotor skills to work with two-dimensional (2D) images. Three-dimensional (3D) laparoscopy has been introduced to address this issue.

3D imaging techniques were available for many years, but initial data had yet to demonstrate any advantages of the 3D technology over the 2D version. This might be attributed to the suboptimal image quality, poor illumination and high equipment cost with earlier prototypes (4). Recent technological breakthrough in stereoscopy has greatly enhanced the image quality. With high-definition resolution being the new standard, results from earlier trials are now obsolete. Yet, the benefits of 3D laparoscopy remained controversial. To better define the role of 3D laparoscopy, we reviewed the evidence behind the application of 3D laparoscopy, as well as discussing the limitations of the current technology. The following review included experimental and clinical trials comparing 3D and 2D laparoscopy in abdominal, pelvic and gynaecological surgery over the past 10 years.

Principles of 3D laparoscopy

Depth perception is the ability to estimate and interpret the relative distances of different objects by our eyes. The human brain estimates the depth of the object based on five major principles: stereopsis, parallax, depth of field, environmental context, and tactile feedback. Parallax is the difference in relative positions of objects as the observer move and views the objects from different point of views, in which monocular vision is sufficient. On the other hand, stereopsis relies on the identification of disparities between two eyes in binocular vision to allow the brain to compute the relative depth of an object (4). When viewing a motion picture on a monitor, as in the case of a laparoscopic procedure with the conventional 2D laparoscopy, stereopsis is lost and relative distance is perceived by analyzing visual clues. 3D laparoscopy uses two cameras instead of one to recapitulate the effect of human binocular vision: producing two different views of the same object, which are then co-displayed on the screen with oppositely polarized lights. Eyeglasses containing oppositely arranged polarizing filters on each side allow each eye to view differently in accordance with the two cameras’ arrangement, permitting depth perception by stereopsis. It is worthy of note that not everyone possess the ability to perceive depth by stereopsis, and 3D laparoscopy would not have any additional effects in these individuals.

Experimental trials on task performance

Studies evaluating the performance of various laparoscopic tasks were predominantly based on experimental trials. Currently, there is no consensus on the choice of tasks for comparison. The majority of tasks in these studies were from validated curriculum of basic laparoscopy training, such as fundamentals of laparoscopic skills (FLS) and basic laparoscopic urologic surgery (BLUS) (5-7). Examples included peg transfer, rope pass, paper cut, needle capping and knot tying. For outcome measurement, parameters used for comparisons included average performance time and error rate of individual tasks as well as the whole set of exercise.

The results from these experimental trials were consistent in demonstrating variable degrees of benefit in shortening performance time and reducing error rates in 3D laparoscopy over 2D laparoscopy. Smith et al. compared the performance time of four laparoscopic tasks by 20 novices, showing a significant improvement with 3D laparoscopy (P<0.001), with an average of 35.8% difference (8). Honeck et al. concluded operators benefited from 3D laparoscopy regardless of experience level, with 89.6% error reduction (1.34 vs. 0.14, P<0.0001) in the expert group and 71.6% error reduction (2.57 vs. 0.73, P<0.0001) in the novice group (9). While some of these benefits may potentially be translated into better task performance in in vivo setting (see below), others have shown equivocal results (9,10). Limitations of these studies included small sample size, discrepancy in the classification of experience levels of the subjects, heterogeneity in tasks used for comparison and difference in test equipment (Table 1) (8-14).

Clinical trials on operative outcomes

In addition to the experimental trials, there were trials comparing the clinical use of 3D and 2D laparoscopy. In a single-surgeon cohort study by Bove et al., the operative data of 3D and 2D laparoscopic radical prostatectomy in 86 patients with prostate cancer was compared (15). The study showed that 3D laparoscopy significantly reduced the mean total operating time (241 vs. 162 minutes, P=0.010), the mean anastomosis time (32 vs. 24 minutes, P=0.030) and the mean number of anastomosis stitches used (6.45 vs. 5.65, P=0.018). Currò et al. conducted a randomized controlled trial on laparoscopic cholecystectomy, involving both experienced and novice surgeons, and yielded mixed results (16). A significantly shorter operating time was observed in novice surgeons (60 vs. 48 minutes, P=0.02), but not in experienced surgeons (40 vs. 38 minutes, P=0.10). Table 2 summarized published clinical trials on 3D laparoscopy (15,16,19,20,22). Given the heterogeneity of the study design and their mixed results, it is hard to conclude that 3D laparoscopy is superior to 2D laparoscopy in clinical use. More data are required to demonstrate if 3D imaging system results in shorter operating time, and whether such advantage is consistent across different types of surgical procedures and with surgeons of different experience levels.

In terms of intraoperative blood loss, two studies found statistically significant differences between 2D and 3D laparoscopies (18,21). Lu et al. demonstrated in a randomized controlled trial that 3D laparoscopic gastrectomy resulted in reduced blood loss compared to 2D laparoscopic gastrectomy (78 vs. 58 mL, P=0.047) (21). This was echoed by another retrospective study by Aykan et al. which demonstrated less blood loss in 3D laparoscopic radical prostatectomy (138 vs. 102 mL, P<0.001) (18). However, similar finding was not seen in studies involving other surgical procedures (17,23,24).

With regard to postoperative complication, hospital stay and operative mortality, the current literature did not show any difference between 2D and 3D laparoscopic procedures (17,21,23). For example, Velayutham et al. compared 3D and 2D laparoscopic hepatectomy and demonstrated similar complication rates: bile leak (P>0.999), postoperative ascites (P>0.999) and respiratory complications (P=0.544) (24). The two groups were also comparable in terms of the severity grading of complications, i.e., minor complications (Clavien I to II complications) and major complication rates (Clavien III to IV complications). There was no postoperative mortality observed in both groups.

Regarding long-term outcomes, Aykan et al. showed a higher 3 months post-radical prostatectomy continence rate in the 3D laparoscopy group (50% vs. 25%, P=0.020) (18). However, long-term results were generally limited and remained a subject of future research.

Surgeons’ perspective

Several surveys suggested that surgeons subjectively preferred 3D laparoscopy over 2D laparoscopy (13,25-28). Tanagho et al. studied 33 subjects performing four standardized laparoscopic tasks from the FLS skill set (13). 81.8% of the subjects found 3D laparoscopy improved their performance, and 87.9% indicated that they preferred 3D to 2D laparoscopy. Spille et al. further evaluated preference among different levels of experience (27). A total of 277 subjects from three subgroups (students, residents and specialists) were required to perform four laparoscopic tasks with both 3D and 2D laparoscopies and they were asked to fill in a questionnaire afterwards. Overall, 68.8% of the participants preferred 3D to 2D laparoscopy and this was consistent within all three subgroups.

Kinoshita et al. compared surgeon’s self-rated satisfaction score and their choice of imaging system with certain tasks in laparoscopic radical prostatectomy (19). The satisfaction score was significantly higher in 3D laparoscopy (4.2 vs. 3.1, 0 being lowest, 6 being highest, P<0.001). Surgeons also preferred 3D laparoscopy with certain tasks like moving instruments to an intended position (4.4 vs. 3.1, P<0.001) and adjusting the needle direction (4.5 vs. 2.7, P<0.001).

Headache, nausea and eye strain from 3D laparoscopy have been reported (29-32), although these were not consistently demonstrated across different studies and subjects (13,14). Three studies reported increased adverse reactions with 3D laparoscopy (25,30,33). In a randomized prospective study by Usta et al., 24 participants were required to perform 10 standardized tasks and asked to report any adverse reactions experienced when using 3D or 2D laparoscopy. There was no difference in visual strain (P=0.087), headache (P=0.134) or facial discomfort (P=0.090) (14). Gómez-Gómez et al. measured the mental workload using the NASA Task Load Index with five standardized tasks. Although 3D laparoscopy produced a smaller mental workload, more adverse reactions such as dizziness and headache were reported (33).

Limitations of 3D laparoscopy

As mentioned previously, 3D laparoscopy has the advantage of allowing depth perception. However, a normal stereopsis is a prerequisite for individuals to experience this effect. In a study by Bloch et al., stereopsis-normal and stereopsis-absent subjects were recruited to perform simulated fine motor surgical tasks under 2D and 3D systems respectively. Results showed that the two groups demonstrated comparable performance with 2D laparoscopy, while the stereopsis-absent group had poorer performance compared to the stereopsis-normal group using 3D laparoscopy (34). An evaluation regarding stereopsis in surgeons by Biddle et al. revealed that 74–83% of surgeons possessed high-grade stereopsis while 2–14% had reduced stereopsis (35). Another study by Fergo et al. found that 10% of the evaluated surgeons did not have measurable stereopsis (36). The implication of these two studies was that approximately 10% of surgeons would not be able to appreciate depth perception despite 3D laparoscopy.

Limitations of the current literature

Experimental trials on simple task performance, albeit their superior results with 3D laparoscopy, may not necessarily reflect the complexity of real-life surgeries. Some randomized control trials had limited sample sizes with possible biases and type II errors, and this might partly explain the mixed results aforementioned in this review. It remained a possibility that 3D laparoscopy might benefit certain types of surgical procedures but not others. Even so, the main effect would be in terms of facilitating certain tasks and reducing operating time. Operative outcome, and ultimately patient care, however, is affected by a multitude of factors, and the effect of a mere enhanced vision is expected to be small. Studies have to possess a formidably large sample in order to detect such effect. Even if such advantage existed, cost-effectiveness is another issue, which was hardly addressed. Nevertheless, the ‘upgrading’ of minimally invasive surgery theatres with 3D laparoscopies is expected to press on, in the hope that surgeons would benefit from advancing technologies, despite limitations with the current evidences.

Conclusions

The current technology of 3D laparoscopic imaging system provided depth perception and spatial orientation, which was absent in conventional 2D system. This revolutionized laparoscopic surgery with enhanced operative vision and studies have demonstrated enhanced results in experimental settings with faster performance time and lower error rates. However, evidence was still inconclusive on whether this translates into better operative outcomes. Future randomized control clinical trials on a larger scale with more patient-related long-term outcomes will be of benefit. But perhaps it is ultimately up to the decision of individual surgeons and institutions whether binocular vision would help with their work in a way that additional cost is justified.

Acknowledgments

Funding: None.

Footnote

Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at http://dx.doi.org/10.21037/ales.2017.08.01). The authors have no conflicts of interest to declare.

Ethical Statement: The authors are accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved.

Open Access Statement: This is an Open Access article distributed in accordance with the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International License (CC BY-NC-ND 4.0), which permits the non-commercial replication and distribution of the article with the strict proviso that no changes or edits are made and the original work is properly cited (including links to both the formal publication through the relevant DOI and the license). See: https://creativecommons.org/licenses/by-nc-nd/4.0/.

References

1. Tjandra JJ, Chan MK. Systematic review on the short-term outcome of laparoscopic resection for colon and rectosigmoid cancer. Colorectal Dis 2006;8:375-88. [Crossref] [PubMed]
2. Leung KL, Kwok SP, Lam SC, et al. Laparoscopic resection of rectosigmoid carcinoma: prospective randomised trial. Lancet 2004;363:1187-92. [Crossref] [PubMed]
3. Gallagher AG, O'Sullivan GC. Fundamentals of Surgical Simulation. 1 ed. London: Springer-Verlag London, 2012.
4. McDougall EM, Soble JJ, Wolf JS Jr, et al. Comparison of three-dimensional and two-dimensional laparoscopic video systems. J Endourol 1996;10:371-4. [Crossref] [PubMed]
5. Kowalewski TM, Sweet R, Lendvay TS, et al. Validation of the AUA BLUS Tasks. J Urol 2016;195:998-1005. [Crossref] [PubMed]
6. Sweet RM, Beach R, Sainfort F, et al. Introduction and validation of the American Urological Association Basic Laparoscopic Urologic Surgery skills curriculum. J Endourol 2012;26:190-6. [Crossref] [PubMed]
7. Hur HC, Arden D, Dodge LE, et al. Fundamentals of laparoscopic surgery: a surgical skills assessment tool in gynecology. JSLS 2011;15:21-6. [Crossref] [PubMed]
8. Smith R, Day A, Rockall T, et al. Advanced stereoscopic projection technology significantly improves novice performance of minimally invasive surgical skills. Surg Endosc 2012;26:1522-7. [Crossref] [PubMed]
9. Honeck P, Wendt-Nordahl G, Rassweiler J, et al. Three-dimensional laparoscopic imaging improves surgical performance on standardized ex-vivo laparoscopic tasks. J Endourol 2012;26:1085-8. [Crossref] [PubMed]
10. Alaraimi B, El Bakbak W, Sarker S, et al. A randomized prospective study comparing acquisition of laparoscopic skills in three-dimensional (3D) vs. two-dimensional (2D) laparoscopy. World J Surg 2014;38:2746-52. [Crossref] [PubMed]
11. Lusch A, Bucur PL, Menhadji AD, et al. Evaluation of the impact of three-dimensional vision on laparoscopic performance. J Endourol 2014;28:261-6. [Crossref] [PubMed]
12. Storz P, Buess GF, Kunert W, et al. 3D HD versus 2D HD: surgical task efficiency in standardised phantom tasks. Surg Endosc 2012;26:1454-60. [Crossref] [PubMed]
13. Tanagho YS, Andriole GL, Paradis AG, et al. 2D versus 3D visualization: impact on laparoscopic proficiency using the fundamentals of laparoscopic surgery skill set. J Laparoendosc Adv Surg Tech A 2012;22:865-70. [Crossref] [PubMed]
14. Usta TA, Ozkaynak A, Kovalak E, et al. An assessment of the new generation three-dimensional high definition laparoscopic vision system on surgical skills: a randomized prospective study. Surg Endosc 2015;29:2305-13. [Crossref] [PubMed]
15. Bove P, Iacovelli V, Celestino F, et al. 3D vs 2D laparoscopic radical prostatectomy in organ-confined prostate cancer: comparison of operative data and pentafecta rates: a single cohort study. BMC Urol 2015;15:12. [Crossref] [PubMed]
16. Currò G, La Malfa G, Lazzara S, et al. Three-Dimensional Versus Two-Dimensional Laparoscopic Cholecystectomy: Is Surgeon Experience Relevant? J Laparoendosc Adv Surg Tech A 2015;25:566-70. [Crossref] [PubMed]
17. Abou-Haidar H, Al-Qaoud T, Jednak R, et al. Laparoscopic pyeloplasty: Initial experience with 3D vision laparoscopy and articulating shears. J Pediatr Urol 2016;12:426.e1-426.e5. [Crossref] [PubMed]
18. Aykan S, Singhal P, Nguyen DP, et al. Perioperative, pathologic, and early continence outcomes comparing three-dimensional and two-dimensional display systems for laparoscopic radical prostatectomy--a retrospective, single-surgeon study. J Endourol 2014;28:539-43. [Crossref] [PubMed]
19. Kinoshita H, Nakagawa K, Usui Y, et al. High-definition resolution three-dimensional imaging systems in laparoscopic radical prostatectomy: randomized comparative study with high-definition resolution two-dimensional systems. Surg Endosc 2015;29:2203-9. [Crossref] [PubMed]
20. Leon P, Rivellini R, Giudici F, et al. 3D Vision Provides Shorter Operative Time and More Accurate Intraoperative Surgical Performance in Laparoscopic Hiatal Hernia Repair Compared With 2D Vision. Surg Innov 2017;24:155-61. [Crossref] [PubMed]
21. Lu J, Zheng CH, Zheng HL, et al. Randomized, controlled trial comparing clinical outcomes of 3D and 2D laparoscopic surgery for gastric cancer: an interim report. Surg Endosc 2017;31:2939-2945. [Crossref] [PubMed]
22. Ruan Y, Wang XH, Wang K, et al. Clinical evaluation and technical features of three-dimensional laparoscopic partial nephrectomy with selective segmental artery clamping. World J Urol 2016;34:679-85. [Crossref] [PubMed]
23. Tao K, Liu X, Deng M, et al. Three-Dimensional Against 2-Dimensional Laparoscopic Colectomy for Right-sided Colon Cancer. Surg Laparosc Endosc Percutan Tech 2016;26:324-7. [Crossref] [PubMed]
24. Velayutham V, Fuks D, Nomi T, et al. 3D visualization reduces operating time when compared to high-definition 2D in laparoscopic liver resection: a case-matched study. Surg Endosc 2016;30:147-53. [Crossref] [PubMed]
25. Ko JK, Li RH, Cheung VY. Two-dimensional versus three-dimensional laparoscopy: evaluation of physicians' performance and preference using a pelvic trainer. J Minim Invasive Gynecol 2015;22:421-7. [Crossref] [PubMed]
26. Romero-Loera S, Cárdenas-Lailson LE, de la Concha-Bermejillo F, et al. Skills comparison using a 2D vs. 3D laparoscopic simulator. Cir Cir 2016;84:37-44. [Crossref] [PubMed]
27. Spille J, Wenners A, von Hehn U, et al. 2D Versus 3D in Laparoscopic Surgery by Beginners and Experts: A Randomized Controlled Trial on a Pelvitrainer in Objectively Graded Surgical Steps. J Surg Educ 2017; [Epub ahead of print]. [Crossref] [PubMed]
28. Kong SH, Oh BM, Yoon H, et al. Comparison of two- and three-dimensional camera systems in laparoscopic performance: a novel 3D system with one camera. Surg Endosc 2010;24:1132-43. [Crossref] [PubMed]
29. Cicione A, Autorino R, Laguna MP, et al. Three-dimensional Technology Facilitates Surgical Performance of Novice Laparoscopy Surgeons: A Quantitative Assessment on a Porcine Kidney Model. Urology 2015;85:1252-6. [Crossref] [PubMed]
30. Zhou J, Xu HJ, Liang CZ, et al. A Comparative Study of Distinct Ocular Symptoms After Performing Laparoscopic Surgical Tasks Using a Three-Dimensional Surgical Imaging System and a Conventional Two-Dimensional Surgical Imaging System. J Endourol 2015;29:816-20. [Crossref] [PubMed]
31. Guanà R, Ferrero L, Garofalo S, et al. Skills Comparison in Pediatric Residents Using a 2-Dimensional versus a 3-Dimensional High-Definition Camera in a Pediatric Laparoscopic Simulator. J Surg Educ 2017;74:644-649. [Crossref] [PubMed]
32. Chan AC, Chung SC, Yim AP, et al. Comparison of two-dimensional vs three-dimensional camera systems in laparoscopic surgery. Surg Endosc 1997;11:438-40. [Crossref] [PubMed]
33. Gómez-Gómez E, Carrasco-Valiente J, Valero-Rosa J, et al. Impact of 3D vision on mental workload and laparoscopic performance in inexperienced subjects. Actas Urol Esp 2015;39:229-35. [Crossref] [PubMed]
34. Bloch E, Uddin N, Gannon L, et al. The effects of absence of stereopsis on performance of a simulated surgical task in two-dimensional and three-dimensional viewing conditions. Br J Ophthalmol 2015;99:240-5. [Crossref] [PubMed]
35. Biddle M, Hamid S, Ali N. An evaluation of stereoacuity (3D vision) in practising surgeons across a range of surgical specialities. Surgeon 2014;12:7-10. [Crossref] [PubMed]
36. Fergo C, Burcharth J, Pommergaard HC, et al. Age is highly associated with stereo blindness among surgeons: a cross-sectional study. Surg Endosc 2016;30:4889-4894. [Crossref] [PubMed]