Comparative Study for Evaluating the Cosmetic Outcome of Small ...

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Aim: To compare the scars and cosmetic results of trocars of 3, 5, and 10 mm in cases by small-incision access retroperitoneoscopic technique pyeloplasty ...
JOURNAL OF ENDOUROLOGY Volume 28, Number 12, December 2014 ª Mary Ann Liebert, Inc. Pp. 1409–1413 DOI: 10.1089/end.2014.0142

Comparative Study for Evaluating the Cosmetic Outcome of Small-Incision Access Retroperitoneoscopic Technique (SMART) with Standard Retroperitoneoscopy Using the Observer Scar Assessment Scale: Are Small Incisions a Big Deal? Murad Al Nasser, MD, Giovannalberto Pini, MD, Ali Serdar Go¨zen, Osama M. Elashry, Yigit Akin, Jan Klein, Turky Almouhissen, and Jens Rassweiler, MD

Abstract

Aim: To compare the scars and cosmetic results of trocars of 3, 5, and 10 mm in cases by small-incision access retroperitoneoscopic technique pyeloplasty (SMARTp) and standard laparoscopy pyeloplasty (SLp). Methods: Between January 2012 and October 2013, 20 pyeloplasties were performed: 12 with SMARTp and 8 with SLp techniques. A 5-mm homemade balloon trocar was used to create the retroperitoneal space. In SMARTp, 3- and 5-mm trocars were used and in SLp, 5- and 10-mm trocars were used. All patients underwent a ureteral (Double-J) stent placement preoperatively. The study included a total of 72 trocar-site scars: 3 mm (24 scars), 5 mm (24 scars), and 10 mm (24 scars). Cosmetic outcome was assessed at the 3rd, 12th, and 24th month of surgeries by the Observer Scar Assessment Scale (OSAS). Results: Mean age was 34.7 – 10.5 (19–52) years, and mean follow up was 18.7 – 9.2 months. Fifteen patients (75%) underwent Y-V plasty, and 5 (25%) underwent Anderson–Hynes pyeloplasty. Mean operative time was 125.4 – 28.7 minutes. There was only minimal blood loss, no need for conversion to standard laparoscopic or open pyeloplasty, no intraoperative complications, and only two postoperative complications were recorded: retroperitoneal hemorrhage and wound infection and both were treated conservatively. There were significant differences between objective questions of ‘‘vascularization’’ in a 3-mm trocar and ‘‘thickness’’ in a 10-mm trocar. Twenty-four months after surgery, the cosmetic data assessed by OSAS showed statistically significant differenecs in favor of the 3-mm trocar sites versus the 10-mm trocar sites (OSAS: 13.8 – 3.9 vs 24.6 – 1.7; p = 0.006) with no statistically significant difference between 3- and 5-mm port sites. Conclusions: The SMARTp is proved to be an efficacious and tolerable procedure with better cosmetic results and can be used for the treatment of ureteropelvic junction obstruction (UPJO) in suitable patients. We believe that this technique is likely to become an established procedure.

Introduction

L

aparoscopic pyeloplasty (LP) has become the treatment of choice for ureteropelvic junction obstruction (UPJO), in centers with expert laparoscopists.1 Studies have been ongoing for optimizing surgical treatments of UPJO, in terms of better outcomes and less invasive methods. Besides the good functional outcomes, cosmesis has been an important issue during the previous years, especially for the young patient population.

Therefore, new techniques such as laparoendoscopic singlesite surgery (LESS), natural orifice transluminal endoscopic surgery, and needlescopic surgery have been previously introduced.2–6 Besides these, mini-laparoscopy (ML) has been previously described in laparoscopic urology for transperitoneal approaching by using 3-mm instruments.2 Thus, functional and cosmetic outcomes were promising. Recently, the novel small-access incision retroperitoneoscopy technique (SMART) has been described in an attempt to improve the cosmetic outcomes, and to reduce the invasiveness of standard

Department of Urology, Klinikum Heilbronn, Heilbronn, Germany.

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laparoscopy (SL).7 SMART combines the cosmetic advantages of ML with the retroperitoneoscopic approach and it provides direct access to the retroperitoneal organs, potential reduction in time, needs less organ retraction, and eliminates the risk of intraperitoneal contamination, infection, and absence of peritoneal irritation by insufflating carbon dioxide. There is still a lack of data on the linear scar assessment after laparoscopic surgeries focusing on those cosmetic results using validated scar assessment methods with followup data. The Patient and Observer Scar Assessment Scale (POSAS) is a standard way for assessing the scars, and it takes the evaluation of the patients and the observers into account.8,9 The aim of this study is to compare the linear scars and cosmetic results of our SL (5/10 mm trocar incisions) and SMART (3/5 mm trocar incisions) pyeloplasty cases using the Observer Scar Assessment Scale (OSAS), which is a reliable and suitable tool mostly used for burn and linear scar assessment.9 In addition, we evaluated the changes in quality of the scars, in different time periods of follow up. Methods

This was a prospective study. Pre- and postoperative data of patients in whom SMART pyeloplasty (SMARTp) and SL pyeloplasty (SLp) were performed by retroperitoneal route were recorded in a Microsoft excel sheet. Exclusion criteria were irregular follow up, pediatric patients (age 30 kg/m2, concomitant urolithiasis, skin disease, known allergies to chemical products, and history of scars or keloids. Nine patients were excluded from the study. Between January 2012 and October 2013, 20 patients underwent LP. Of the 20 patients, n = 12 underwent SMARTp and n = 8 underwent SLp. All surgical procedures were performed by a single experienced surgeon ( J.R.). In SMARTp cases, 3- and 5-mm trocars were used; while in SRTp, 5- and 10-mm trocars were used. The study included a total of 72 trocar-site scars. Out of the 72 scars, we had 24 scars of each size (3, 5, and 10 mm) (Table 1). All patients were assessed preoperatively with physical examination, abdominal ultrasound, intravenous urography, or computed tomography scan and renal scintigraphy. Demographic, perioperative data and data on complications were recorded and classified according to the Clavien system. The SMARTp and SLp surgical techniques were previously described in detail.7 Briefly, after a 5-mm incision, a homemade balloon trocar was used for creating retroperitoneal space. Subsequently, a 5-mm trocar (10.5 mm length) was introduced as an optical port through the same incision.

Table 1. The Number and Size of Trocars Scars Assessed During the Period of Follow Up

3rd month of surgery 12th month of surgery 24th month of surgery

3-mm trocar

5-mm trocar

10-mm trocar

8 8 8

8 8 8

8 8 8

After performing the surgery by using 3- and 5-mm trocars, the 5 mm port site incision was closed by only a single stitch and the 3.5-mm incision was closed by adhesive material (Dermabond, San Lorenzo, CA). We objectively evaluated the cosmetic results based on a standardized assessment score system—the OSAS developed by plastic surgeons to evaluate scars.9 The OSAS consists of numeric scale and contains six items: vascularity, pigmentation, thickness, relief, pliability, and surface area. Each item scored numerically on a ten-point scale. The lowest score for each item in the scale is 1, and it corresponds to the normal skin; the highest score is 10, and it corresponds to the worst scar situation. To objectively assess scars, the OSAS scores of two observers (urologists) not directly involved in surgery were taken into consideration for statistical analysis. The evaluations were made with the observers blinded to each other. The urologists evaluated scars by OSAS scoring at the 3rd, 12th, and 24th month of surgery. In statistical analysis, descriptive results were reported for all studied parameters. The one-way Anova was used for statistical analysis. Statistical significance was considered at p < 0.05. All statistical analyses were performed with the Statistical Package for Social Sciences (SPSS) for windows 16.0 (SPSS, Inc., Chicago, IL).

Table 2. Demographic, Operative, and Follow-Up Data of Patients Demographic data Total no. of patients Female, n (%) Male, n (%) Age, mean(range), years BMI (mean – SD) ASA (mean – SD) Left sided, n (%) Right sided, n (%) Significant hydronephrosis ( > grade II), n (%) Symptomatic (flank pain), n (%) Recurrent UTI, n (%) Type of pyeloplasty Anderson-Hynes, n (%) Y-V plasty, n (%) Operative data Presence of crossing vessels, n (%) Conversion, n (%) Operative time, (mean – SD) minutes Blood transfusion, n (%) No. of ports 3, n (%) 4, n (%) Intraoperative complications, n (%) Postoperative complications, n (%) Drainage removal, (mean – SD), hours Length of hospitalization, (mean – SD), days VAS (sum 1–4 day – SD) Follow-up length, (mean – SD), months

20 10 (50) 10 (50) 34.7 (19–52) 22.1 – 6.2 1 – 0.8 12 (59.6) 8 (40.4) 13 (65) 17(85) 4 (20) 5 (25) 15 (75) 12 (59.6) 0 (0) 125.4 – 28.7 1 (5) 17 (85) 3 (15) 0 (0) 2 (10) 34.5 (4.2) 5 – 2.1 4.4 – 3.8 18.7 – 9.2

ASA = American Society of Anesthesiologists; BMI = body mass index (kg/m2), UTI = urinary tract infection; VAS = visual analogue scale.

SMART SCAR ASSESSMENT BY OSAS

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FIG. 1. Appearance of 3- and 5-mm scars at 3 (a) and 24 (b) months postoperatively.

Results

Out of the 20 patients included in the study, 10 were men and 10 were women with the mean age of 34.7 – 10.5 (19–52) years. All the patients were Caucasian race with 12 patients included in the SMARTp group and 8 patients included in the SLp group. Fifteen patients (75%) underwent Y-V plasty, and 5 (25%) underwent Anderson–Hynes pyeloplasty. Mean operative time was 125.4 – 28.7 minutes. There was only minimal blood loss, no need for conversion to standard laparoscopic or open pyeloplasty, no intraoperative complications, and only two postoperative complications were recorded in the SLp: one retroperitoneal hemorrhage and one wound infection, both had a Clavian category 1 or 2 complication and were treated conservatively. There were no statistically significant differences between the two groups in age and BMI. Mean follow up was 18.7 – 9.2 months. Demographic, operative, and follow-up data were summarized in Table 2. In the scar assessment, the overall mean OSAS evaluating 3-, 5-, and 10-mm trocar sites showed no significant

difference among them during the first year of follow up (Figs. 1 and 2). OSAS Single objective question ‘‘pigmentation,’’ ‘‘relief,’’ and ‘‘pliability’’ showed no statistically significant difference between the three port sites scars during the whole period of follow up. We found significant differences between objective questions of ‘‘vascularization’’ in a 3-mm trocar and ‘‘thickness’’ in a 10-mm trocar (Table 3). Vascularization of the 5-mm port site at a 3 month follow up was statistically significantly higher than that of the 3-mm port site at 3 and 24 months ( p < 0.05). The OSAS questionnaire of ‘‘Surface area’’ showed statistically significant differences in favor of the 3-mm port site when compared with the 10mm port site at 3rd, 12th, and 24th month of follow up ( p < 0.05). Similarly, ‘‘thickness’’ in OSAS scoring showed statistically significant differences in favor of the 3-mm port site scars compared with the 5- and 10-mm sites at 24 months of follow up ( p < 0.04). However, 24 months after surgery, the cosmetic data assessed by OSAS showed statistically significant differences in favor of the 3-mm trocar sites versus the 10-mm sites

FIG. 2. Appearance of 5- and 10-mm scars at 3 (a) and 24 (b) months postoperatively.

3.8 – 1.1 4.6 – 1 4 – 1.2 3.8 – 1.1 3.4 – 0.7 4.9 – 1.2 24.6

0.4 0.6 0.04a 0.6 0.1 0.1 0.1

(OSAS: 13.8 – 3.9 vs 24.6 – 1.7; p = 0.006) (Fig. 3) with no statistically significant difference between 3- and 5-mm port sites. In addition, the overall comparison at 24 months showed no statistically significant difference between the three port site scars ( p = 0.1).

3.9 – 1.9 3.5 – 1.4 3 – 1.3 3 – 1.4 2.6 – 0.9 3.1 – 0.7 19.1

0.02a 0.4 0.9 0.7 0.8 0.3 0.1

2.9 – 1.1 3.4 – 1.1 3 – 1.2 2.4 – 0.8 2.9 – 1.2 3.2 – 0.8 18

3.3 – 0.8 3.1 – 1 2.6 – 1.1 2.6 – 0.8 2.7 – 0.8 3.6 – 0.7 18

3.5 – 1.4 4.3 – 1.6 2.3 – 0.5 2.5 – 0.9 2.5 – 0.8 4.2 – 1.1 19.5

0.9 0.7 0.9 0.9 0.9 0.9 0.9

2.1 – 1.4 2.7 – 1.1 2.1 – 0.5 2.1 – 0.7 2 – 0.5 2.5 – 0.6 13.8

2.7 – 1.3 3.6 – 1.7 2.8 – 0.9 2.6 – 0.7 2.4 – 0.6 3.8 – 1.1 18.1

Discussion

a

Statistically significant p-value.

3.8 – 1.4 3.5 – 1.4 2.6 – 0.7 2.6 – 0.7 2.8 – 0.8 3 – 0.9 18.9 2.6 – 1.1 2.6 – 0.9 2.5 – 0.7 2.1 – 0.9 2.3 – 0.7 2.3 – 0.4 14.9 Vascularization Pigmentation Thickness Relief Pliability Surface area Total OSAS

Variables

At 12 month (24 scars) At 3rd month (24 scars)

Table 3. Mean Observer Scar Assessment Scale Scores in Follow Up

3 mm 5 mm 10 mm 3 mm 5 mm 10 mm 3 mm 5 mm 10 mm (Mean – SD) (Mean – SD) (Mean – SD) p-Value (Mean – SD) (Mean – SD) (Mean – SD) p-Value (Mean – SD) (Mean – SD) (Mean – SD) p-Value

AL NASSER ET AL.

At 24 month (24 scars)

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Scars that are a part of normal skin healing are one of the undesired manifestations of the surgeries. However, interventions by laparoscopy represent minimal invasive surgery, including minimal scars; cosmesis seems to be an important issue, notably for the young patient population who needs reconstructive surgery for UPJO.10 Viera et al. reported that scars might have a psychological impact and could affect the patient’s quality of life.11 Therefore, treating and also preventing skin scars has become an important issue. Thus, scar assessments come into question. In this study, we compared skin scars of different-sized trocars in SMARTp and SLp patients. According to the best of our knowledge, this is the first study dealing with this issue in the literature with midterm follow up. Up to now, many scales were reported for scar assessments such as Vancouver Scare Scale, matching assessment of scars and photographs, and Manchester scar scale in the literature.12 The OSAS is the most frequently used scale for scar assessments in published literature.13 We used OSAS in this series and we evaluated parameters of scars, such as vascularization, pigmentation, thickness, relief, pliability, and surface area. According to our results, at the 24th month of surgery, 3-mm trocar scars were statistically significantly lower OSAS scores. In addition, vascularization sub-variables of OSAS scoring were in favor of 3-mm trocars in SMARTp. Results of our series were parallel to our previous report on SMARTp, which seemed also to have better cosmetic results than MLp.14 Recently, LESS was introduced and promised better cosmetic results for pyeloplasty, but data are still lacking for cosmetic assessment of LESS, in the literature.10 We used 3- and 5-mm trocars, in SMARTp, and according to our results, better cosmetic results were obtained in the mid term. We believe that SMARTp is a plausible surgery for cosmesis. In the light of our study, clinicians should be aware of the scar characteristic that patients value the most. In the race of better cosmesis by minimally invasive surgery, there is a need to perform more studies with large cohorts. There are some limitations in this series. Numbers of patients were low. On the other hand, we could use the patient ‘‘Patient and Observer Scar Assessment Scale (POSAS)’’ but we did not use the Patient part of POSAS, as it might not be the objective. On the other hand, POSAS was not validated for scars of laparoscopic surgeries. The SMARTp is a new surgical technique, and patients of this series are from an ongoing SMARTp study of our institute. However, we previously described our technique; there is need to develop new devices for performing optimal cuts for trocars on the skin. The functional outcomes were not the subject of this study. In summary, scars of trocars heal with time. Statistically significant better scar aesthetics were shown by OSAS scores, in scars of 3- and 5-mm trocars of SMARTp surgeries, in this

SMART SCAR ASSESSMENT BY OSAS

FIG. 3.

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Statistically significant comparison between 3-, 5-, and 10-mm trocar site scars during the follow-up period.

series. The promising cosmesis can be provided by SMARTp. This is also important for young patients. Conclusion

The SMARTp is a promising surgical technique in minimally invasive treatment of UPJO. It can provide better cosmesis with 3- and 5-mm trocars in adults. Disclosure Statement

No competing financial interests exist. References

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10. Merseburger AS, Herrmann TR, Shariat SF, Kyriazis I, Nagele U, Traxer O, Laitsikos EN. EAU guidelines on robotic and single-site surgery in urology. Eur Urol 2013; 64:277–291. 11. Viera MH, Amini S, Konda S, Berman B. Do postsurgical interventions optimize ultimate scar cosmesis. G Ital Dermatol Venereol 2009;144:243–257. 12. Eskes AM, Bro¨lman FE, van de Kar AL, Niessen FB, Lindeboom R, Ubbink DT, Vermeulen H. Values of patients and caregivers for donor site scars: An inter-observer analysis between patients and caregivers and prediction of cosmetic satisfaction. Burns 2012;38:796–801. 13. Durani P, McGrouther DA, Ferguson MW. Current scales for assessing human scarring: A review. J Plast Reconstr Aesthet Surg 2009;62:713–720. 14. Pini G, Rassweiler J. Minilaparoscopy and laparoendoscopic single-site surgery: Mini- and single scar in urology. Minim Invasive Ther Technol 2012;21:8–25.

Address correspondence to: Jens Rassweiler, MD Department of Urology Klinikum Heilbronn Heilbronn 74078 Germany E-mail: [email protected]

Abbreviations Used ASA ¼ American Society of Anesthesiologists BMI ¼ body mass index LESS ¼ laparoendoscopic single-site surgery LP ¼ laparoscopic pyeloplasty ML ¼ mini-laparoscopy OSAS ¼ observer scar assessment scale POSAS ¼ patient and observer scar assessment scale SL ¼ standard laparoscopy SLp ¼ standard laparoscopic pyeloplasty SMART ¼ small-incision access retroperitoneoscopic technique SMARTp ¼ small-incision access retroperitoneoscopic technique pyeloplasty SPSS ¼ statistical Package for Social Sciences UPJO ¼ ureteropelvic junction obstruction VAS ¼ visual analog scale