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Videosurgery and Other Miniinvasive Techniques
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Original paper

Videoscopic adrenalectomy – when does retroperitoneal seem better?

Piotr Myśliwiec
,
Magda Marek-Safiejko
,
Jerzy Łukaszewicz
,
Kamil Safiejko
,
Robert Kozlowski
,
Piotr Wojskowicz
,
Jacek Dadan

Videosurgery Miniinv 2014; 9 (2): 226–233
Online publish date: 2014/03/24
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Introduction

Lately, we have been witnessing intense development of laparoscopic surgery, which is less invasive than classical interventions, and involves fewer complications. Paired adrenal glands are small, frail and located deep inside the adipose tissue of the retroperitoneal area; hence, their adequate exposure is challenging. Open adrenalectomy requires a large incision, quite disproportionate to the size of the organ involved [1]. Therefore, since Gagner described the first laparoscopic adrenalectomy in 1992, the technique has rapidly gained popularity and is now recognised as the gold standard for the treatment of tumours smaller than 6 cm [2, 3].
Clinical trials conducted in various centres worldwide have confirmed the technological capacity, safety and efficacy of the laparoscopic method [4]. In comparison with the open approach, laparoscopy requires longer operative time at the early phase of training, but is associated with less postoperative pain, shorter hospital stay, faster recovery, reduced mortality, less intraoperative bleeding, a better cosmetic effect and lower costs [4, 5].
As a result of continuous development of laparoscopy, obesity, age, circulatory and respiratory diseases are no longer contraindications to such interventions. Operative injury reduction made it easier for the elderly, obese or those suffering from circulatory diseases to qualify for treatment.
There are four methods of accessing adrenal glands: anterior transperitoneal, lateral transperitoneal, lateral retroperitoneal, and posterior retroperitoneal approaches. The two most popular approaches are the lateral transperitoneal approach (LTA) and posterior retroperitoneal approach (PRA), described by Mercan in 1995 and popularised by Martin Walz [6].
A new trend in videoscopic surgery is to minimise the number of access sites and to reduce the size of the operative wound. This is where single-port interventions originated [7]. The Da Vinci Surgical System was also employed in videoscopic adrenalectomy in all approaches. It significantly increased the cost of the procedures with no benefits over conventional PRA or LTA.

Indications and contraindications for laparoscopy

In the case of small ( 6 cm), benign adrenal tumours, videoscopic treatment is the gold standard [1, 4]. The technique is most often used to remove adenoma known to cause Conn’s syndrome, Cushing’s syndrome, pheochromocytoma (PCC) or hormonally inactive incidentaloma.
Pheochromocytoma, a rare tumour of chromaffin cells secreting catecholamines, may result in haemodynamic disturbances due to manipulation in the adrenal gland area during an operative procedure [8]. Said complications have disqualified patients with PCC from videoscopic treatment for a long time. Nowadays, it is known that videoscopic adrenalectomy is feasible, safe [9–12] and may successfully be employed in over 90% of pheochromocytomas [13]. The technique is associated with a decreased complication rate, and fewer negative haemodynamic consequences and perioperative hypertensive incidents when compared to classical procedures [11, 12]. A prerequisite for a safe intervention is preoperative pharmacotherapy inhibiting tumour hormonal activity and an experienced surgical-anaesthetic team.
Thanks to innovative technologies and growing surgical experience, large tumours (> 6 cm) and malignant lesions, previously restricted to classical interventions only, are increasingly reported to be removed videoscopically. Laparoscopic excision of tumours larger than 8 cm is associated with a prolonged operative time, increased blood loss and longer hospitalisation period, as compared to smaller tumours. However, perioperative morbidity remains comparable to adrenalectomies for smaller masses [14]. Tumours exceeding 10 cm in diameter should probably be operated on in a classical manner [1, 11].
If the results of diagnostic imaging suggest a malignant lesion infiltrating into surrounding tissues, classical adrenalectomy is indicated. However, in the case of malignant tumours of 4–6 cm, which seem not to infiltrate into surrounding tissues, as evidenced by diagnostic imaging, selected patients may benefit from minimally invasive adrenalectomy [15].
In the case of a rare, but highly aggressive, adrenocortical carcinoma (ACC), adrenalectomy is the only potentially effective treatment [16]. Recently, there have been some reports on a successful stage I and II ACC resection with the application of the videoscopic technique [17]. Porpiglia et al. [18] compared open and videoscopic adrenalectomy in the case of ACC, finding no difference between the two as per the postoperative recurrence rate, which at the same time invalidated the theory of increased risk of disease recurrence and dissemination of cancer cells following videoscopic treatment. However, decisions to operate on those patients videoscopically need to be taken cautiously, considering the devastating outcome of ACC.
Adrenal glands are areas of metastasis development for mammary, pulmonary, skin and renal tumours in particular. Often, the sole purpose of operative treatment in the course of the above is to extend the life of the patient [19], as it usually does not cure the neoplastic disease. If a negative margin can be achieved during adrenalectomy, the videoscopic technique, dubious initially, has now become a standard treatment procedure for such lesions as it is associated with lower mortality and a low recurrence rate, comparable to open adrenalectomy [20].
The resection of both ACC and adrenal metastases should be performed by highly qualified surgeons, as it may be necessary to convert to the classical method if difficulties or complications occur during the procedure.

Aim

The study aimed to compare the two most common approaches for videoscopic adrenalectomy, LTA and PRA, based on a literature review and our own experience.

Material and methods

We reviewed the literature (PubMed and Cochrane 1990 – current) for the following key words: videoscopic adrenalectomy, laparoscopic adrenalectomy, retroperitoneal adrenalectomy retroperitoneoscopy.
The clinical analysis included patients treated in the 1st Department of General and Endocrinological Surgery, Medical University of Bialystok (UMB), between February 2009 and April 2013, who underwent videoscopic adrenalectomy. Most patients were prepared for operations in the Department of Endocrinology, where the functional status of adrenal glands was evaluated, and where diagnostic imaging (CT) was performed. Every patient suspected of having adrenal carcinoma or tumour > 12 cm was qualified for the classical approach surgery, and as such was excluded from this analysis. 43 females and 28 males aged 34 to 79 (mean age: 56.7) were operated on.
The analysis covered patient characteristic features, tumour morphological characteristics, reasons for qualification for the PRA and LTA surgery, operative time, perioperative blood loss and postoperative complications. Non-parametric tests were used for statistical analysis.

Recommended videoscopic access methods

For LTA, the patient is positioned in the lateral decubitus position on the side that is opposing the adrenal gland involved (Photo 1). The operating table is flexed at the waist to open up the space between the iliac crest and the ribs. Because of relocation of the skin against the costal arch when placing the patient in a lateral position, it is well worth marking the border of the costal arch before doing so. The first 10 mm trocar is introduced 3–4 cm below the ribs – at the extension of the midclavicular line. Pneumoperitoneum is insufflated to 12–15 mm Hg. Then, two 5 mm trocars are placed 6–8 cm laterally to the optical trocar.
During left adrenalectomy it is necessary to incise the spleno-renal and spleno-diaphragmatic ligaments. Thanks to gravity, the free falling spleen and pancreatic tail expose the adrenal gland. Sometimes, the left adrenal gland is difficult to locate due to abundant retroperitoneal fat and a small tumour. A laparoscopic ultrasound device was reported as useful in such cases. Next, the left adrenal gland is exposed and dissected.
On the right side, care must be taken to avoid injury to the liver, especially when the organ is pushed forward by an enlarged adrenal gland. In our experience the Hasson technique is advisable. An additional trocar is necessary to introduce the liver retractor. The procedure starts with freeing the right hepatic triangular ligament and retracting the liver. Upon identification of the right kidney, Gerota’s fascia is incised. When the inferior vena cava, which runs in the direct vicinity of the adrenal gland, is dissected, the central adrenal vein requires precise identification and securing. Next, additional right adrenal veins and arteries are sealed and the gland is dissected and removed in an extraction bag.
Posterior retroperitoneal approach usually begins with intubation on the trolley. The patient is then transferred onto the operating table and placed on his abdomen (Photo 2). The trunk of the patient is fitted on a rectangular foam frame, which makes the belly hang loose. Lower limbs are flexed at hip and knee joints. In such a position the space between the 12th rib and the posterior superior iliac spine expands, which facilitates access to the retroperitoneal space. For unilateral PRA, the operated side can be slightly elevated. A 2-cm long dissection at the tip of the 12th rib allows blunt creation of retroperitoneal access. Guided by the index finger, a 10-mm trocar is introduced paravertebrally ca. 3–4 cm beneath the 12th rib. The trocar and the skin should form a 45 angle in order to avoid difficulties when operating the camera, especially in obese or muscular patients. Then, a 5-mm trocar is introduced underneath the 11th rib, ~6 cm laterally. A trocar fitted with a balloon to prevent gas escape is placed in the initial wound. CO2 is insufflated to 20–24 mm Hg, or even 28 mm Hg in obese patients [21]. Dissection of the tumour-affected adrenal gland begins with finding the upper renal pole and then it is continued medially, between the crura of the diaphragm and the adrenal gland. Main adrenal vessels are located in this position. The vein and artery are dissected and sealed with clips or a vessel-sealing device. Subsequently, the adrenal gland with the tumour is dissected free and removed in the extraction bag. The use of percutaneous ultrasound pre- or perioperatively, particularly in the case of massive retroperitoneal adipose tissue, has been described [22].

Lateral transperitoneal approach or posterior retroperitoneal approach?

To date, there has been no prospective, randomised study comparing both approaches. Thus, neither was proven superior. The choice depends primarily on the surgeon’s preference and contraindications for a particular approach in an individual case.
The majority of surgeons perform videoscopic adrenalectomy using LTA. It is the result of better expertise in the anatomy of the peritoneal cavity, greater skills acquired during other laparoscopic interventions, and a large operative field. Lateral transperitoneal approach allows for easier removal of some atypically located, larger adrenal gland tumours [23]. Additionally, this approach enables a potential simultaneous operation on other organs located intraperitoneally [24, 25].
Currently, PRA is becoming more and more common. Posterior retroperitoneal approach gives the most direct access to the adrenal gland without the need to mobilise intraperitoneal organs. Bilateral tumours can be operated on using PRA at the same time, without changing position [22]. In patients with a history of abdominal surgery, this approach provides an unaffected space free from adhesions. Some data suggested shorter operative time, less blood loss, shorter hospital stay and a comparable number of complications in the case of PRA, when compared to LTA; however, there is not enough evidence to prove the superiority of one technique over the other [21, 26–30]. A breakthrough for PRA was an increase in CO2 pressure from the standard 12–15 mm Hg up to 20–24 mm Hg, or even 28 mm Hg [21], which enlarged the operative field. What is more, there is better haemostasis of the operative area due to vessel compression. Opponents of the method have suggested that increased CO2 pressure creates a risk of gas embolism and ejection of catecholamines [31]. Those findings have not been confirmed in practice [14, 22].
Even though videoscopic techniques employing PRA and LTA pertain to the same organ, they are completely different surgical procedures that require separate training. According to some, the learning curve in the case of PRA is shorter and requires only 20 procedures [22].
A less common videoscopic technique is the lateral retroperitoneal approach. A prospective, randomised clinical trial including 57 patients and comparing this approach to LTA found no significant differences in the operative time, estimated blood loss or complication rate [32]. Also, the amount of analgesics, time needed for patient mobilisation, return to oral feeding and length of hospital stay were comparable in both techniques. Still, convalescence time was shorter in the case of the retroperitoneal approach [32].

Results

In the study period, 71 videoscopic adrenalectomies were performed, including 50 PRA and 21 LTA. A subtotal excision of the adrenal gland, where a morphologically unaffected part of the gland was left in situ, was performed 4 times – in patients after contralateral adrenalectomy and without suspicion of malignancy. The patient average ASA scale score was 2.56 (between 2 and 4). Body mass index (BMI) of patients who underwent surgery was within the range 22–44 kg/m2 (mean BMI – 29.9 kg/m2). Most PRA procedures (93%) were performed by a single operator, with application of either the PRA or LTA.
All the adrenalectomies reported were primary operations. The predominant preoperative diagnosis was a hormonally inactive tumour. In 39 (55%) cases, the tumour was located on the left, and in the remaining 32 (45%) it was on the right. Two patients had a two-stage, bilateral adrenalectomy performed; one was operated twice using PRA, and the other had LTA on the right and PRA on the left side. For simplicity and because they underwent operations in different years, they are presented as “4 separate” patients. Preoperative patient characteristics and the type of tumour are presented in Table I. The time of PRA operation ranged from 60 min to 170 min (mean time – 93 min), whereas for LTA it was from 95 min to 240 min (169 min on average). The size of tumours excised using PRA in the specimen ranged from 1 cm to 7 cm (4.7 cm on average), and for LTA between 2 cm and 11 cm (7.6 cm on average). Hospitalisation lasted 1 to 5 days (mean 2.0 days) after PRA, and 2 to 5 days (mean 2.8 days) after LTA. The outcomes are displayed in Table II. The most common postoperative diagnosis was that of adenoma. Three cases involved adrenocortical carcinoma: one in the PRA group (3 cm in diameter) and two in the LTA group (5.5 cm and 9 cm). Metastasis to the adrenal gland was also observed three times in the series: one in the PRA group (4.5 cm – of pulmonary origin) and two in the LTA group (8 cm and 7 cm, both of renal origin).
There were no mortalities. One patient operated on using LTA for phaeochromocytoma developed pulmonary oedema intraoperatively. The patient was hospitalised in the Intensive Care Unit, to be transferred to the Clinic on day 2, and discharged home on day 3. Inability of the patient to tolerate the full dose of - and -blockers in the preoperative period (the patient only tolerated 1/4 of the prescribed dosage) could predispose to this complication. In 1 case, a negative re-videoscopy was performed on day 2 after PRA owing to fever of unclear origin – the patient (a heavy smoker) turned out to have acute bronchitis. One patient from the PRA group aged 72 developed pneumonia postoperatively. Three (6%) PRA patients and 2 (10%) LTA patients reported pain radiating to the hypogastric area, lasting more than 7 days.

Discussion

Patients were qualified either for PRA or LTA based on diagnostic imaging results (ultrasound and computed tomography). In the case of tumours < 7 cm, interventions were performed using PRA. For tumours > 7 cm or in patients without a kidney on the same side due to previous nephrectomy or agenesis, LTA was employed. The reason for avoiding large PRA for large tumours is a relatively small operative space, characteristic for this approach.
The first 31 consecutive videoscopic adrenalectomies were performed using PRA. With acquired experience, the time of adrenalectomies performed in our department using PRA decreased from ~180 to ~70 min. Walz et al. scrutinised data regarding over 500 videoscopic adrenalectomies conducted with the application of PRA [21]. According to them, since 1992 the average operative time has shortened to 40 min, which makes the procedure comparable to cholecystectomy or laparoscopic hernia repair in terms of the time it takes. The above results have been confirmed by other studies [26].
To avoid intraoperative arterial pressure increase during surgery for phaeochromocytomas, we avoided tumour mobilisation before sealing of adrenal vessels. Intraoperative increase in arterial pressure > 170 mm Hg was noted in 2 patients (16.7%) operated on using PRA and in 1 patient (25%) during LTA. Dickson et al. [28] reported similar results, recording an intraoperative arterial pressure rise in 17% of patients operated on using PRA.
The CO2 insufflation pressure created in the retroperitoneal space during PRA interventions was 20–28 mm Hg, as opposed to 12–15 mm Hg for LTA surgery. Higher insufflation led to higher end-expiratory CO2 tension. This was not accompanied by a rise in intraoperative blood pressure or breathing disturbances after surgery.
Even though no randomised clinical trial has demonstrated superiority of either videoscopic approach, it has been suggested that PRA entails less pain in the postoperative period. Also, the learning curve was reported to be shorter for PRA than LTA [21, 26]. Our median PRA surgery time, 93 28.5 min, and the continuing downward trend, confirm the above observation.
It remains dubious whether videoscopic methods should be used for malignant tumours which do not infiltrate the surrounding tissues in preoperative imaging. We made efforts to avoid tumours suspected of malignant proliferation when qualifying patients for videoscopic adrenalectomy. Based on histopathological analyses of removed tumours, six primary or secondary malignant adrenal tumours were identified. Follow-up examinations of 6–18 months after surgery did not show any evidence of recurrence.
Our initial experience demonstrates that videoscopic adrenalectomy is a safe and efficient technique performed using both LTA and PRA. Despite the fact that the mean age in the PRA group was higher and that BMI, ASA or tumour location differences were insignificant, tumour size and the rate of patients with hormonally active tumours were significantly higher in the LTA group. Therefore, the groups were not comparable. Nevertheless, pronounced differences were found in the operative time, amount of blood lost intraoperatively, time of return to oral feeding and the time of hospital stay between PRA and LTA surgery, to the advantage of PRA.
The choice of technique should be guided, most of all, by surgeon experience, patient characteristics and tumour size and location. Our preferable approach is PRA and we recommend it for small (< 6 cm) benign adrenal tumours in particular. Posterior retroperitoneal approach makes it possible to remove both adrenal tumours simultaneously. For larger tumours, in patients lacking a kidney on the operated side, with tumours located high (difficult to reach from a retroperitoneal approach), ectopically, suspected to be malignant (peritoneum covering the adrenal gland may need removal) or when another laparoscopic procedure is needed, we opt for LTA.

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Received: 3.07.2013, accepted: 31.08.2013.
Copyright: © 2014 Fundacja Videochirurgii This is an Open Access article distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International (CC BY-NC-SA 4.0) License (http://creativecommons.org/licenses/by-nc-sa/4.0/), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material, provided the original work is properly cited and states its license.
  
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