To the Editor—Infectious complications after surgery are drivers of both costs and morbidity. We therefore read with considerable interest the recent paper “Challenging Residual Contamination of Instruments for Robotic Surgery in Japan” by Saito et al.Reference Saito, Yasuhara and Murakoshi 1 In their study, the authors assess residual protein concentration on reusable surgical instruments both immediately following surgery and after standard hospital cleaning. They found that, compared to traditional open instruments, robotic surgical instruments retained significantly more residual protein both immediately after surgery and after routine cleaning.
Robot-assisted surgery is an approach that has grown in popularity over the past decade. It has now become the most widely used approach for many common operations in the developed world.Reference Hatiboglu, Teber and Hohenfellner 2 In robotic surgery, instruments and cameras are inserted through small laparoscopic port sides and the surgeon sits at a console and manipulates the surgical instruments under direct video control. These robotic instruments contain miniaturized mechanical and electronic components that may be more difficult to clean than traditional surgical instruments.
Saito et al placed both robotic and open instruments in an ultrasonic sink and used sterile water flushes in combination with ultrasonication and protein assays to infer the amount of protein on instruments after surgery and after routine cleaning. They found that robotic surgical instruments had both higher residual protein concentration compared with open surgical instruments and a slower rate of decline in protein concentration.
These results make sense; instruments with complex miniaturized mechanical components have an exponentially larger surface area and probably should retain more protein compared to open surgical instruments, many of which are simple metal grasping tools like scissors or forceps. There are, however, some key questions that this paper does not address.
First, the authors did not control for size or surface area of instruments: robotic surgical instruments have a vastly greater length and surface area. In addition, the largest part of the robotic surgical instrument never enters the patient and is purely used to attach the instrument to the surgical robot. Another study of cleaning methods for robotic surgical devices showed false-positive results after cleaning robotic instruments because it was not clear whether the protein or substances were obtained from the distal working part or from the shaft.Reference Wehrl, Albers and Bühler 3
Second, the total number of instruments used during the operation was not assessed. For example, robot-assisted prostatectomy may be performed with a total of only 5 robotic instruments (2 needle drivers, a grasper, bipolar forceps, scissors, and large grasping forceps), whereas open surgery may require a larger number of individual instruments. A typical open prostatectomy may require multiple pairs of long and short forceps, both toothed and smooth, as well as many instruments that are obsolete in robotic surgery such as retractors, sponge sticks, or scalpels. Comparing the aggregate protein remaining on all instruments used in an operation may be more relevant than the per-instrument concentration.
Another methodological point relates to the measurement of protein remaining on the instruments. With the exception of rare entities like prion diseases, protein itself does not have the ability to cause wound infections. Why not perform assays that specifically measure pathogenic organisms (eg, cultures or PCR assays)? This approach would probably provide a more clinically relevant measure of whether viruses or bacteria are being retained on robotic instruments after cleaning.
Finally, and most importantly, there is a practical question: How do the findings of higher residual protein on robotic surgical instruments impact actual clinical outcomes? An extensive body of observational data suggests that minimally invasive surgeries may have lower rates of infectious complications than open surgeries.Reference Tollefson, Frank and Gettman 4 , Reference Trinh 5 Recently, 2 prospective randomized trials found no higher rates of infectious complications with robotic cystectomy and prostatectomy than with open operations. While the precise impact of robotic surgery on postoperative complications remains a topic of debate and active research, there is certainly no evidence for exponentially greater infectious rates with robotic surgical instruments.
In addition, the proven incidence of infection due to surgical devices is very low.Reference Chan-Myers, McAlister and Antonoplos 6 Surgical wound infections are vastly more likely to be due to contamination from the patient’s skin flora. Thus, benefits due to smaller incision could easily outweigh any theoretical increase in risk due to retained biomaterial on instruments.
The results of Saito et al underscore one of the ways that robotic surgical instruments differs from traditional open surgical instruments: The former tend to have a larger amount of residual protein left after cleaning, which makes sense given their design and size. While novel approaches for cleaning surgical instruments should adapt to new types of instruments, this should not dissuade innovators. Ultimately, new technologies and techniques are judged by their clinical outcomes. Specifically, the evaluation of novel techniques should include careful assessment of infectious risks in concert with careful basic scientific research. At the end of the day, this is what matters for patients, surgeons, and other stakeholders.
ACKNOWLEDGMENTS
Financial support: No financial support was provided relevant to this article.
Potential conflicts of interest: All authors report no conflicts of interest relevant to this article.