Surgical Methods for the Treatment of Uterine Fibroids – Risk of Uterine Sarcoma and Problems of Morcellation: Position Paper of the DGGG

• Introduction
• Data Base of the Position Paper
• Basics of Uterine Sarcomas
• Epidemiology
• Risk factors
• Diagnostics
• Histological classification
• Prognostic factors
• Treatment strategies
• Surgery
• Surgical Procedures for Uterine Fibroids
• Minimally invasive surgical procedures
• Preservation of the uterus
• Removal of the uterus
• Surgery and other procedures to treat uterine fibroids
• Summary of the Basic Stance of the Position Paper
• Hypothesis
• International Opinions (Overview)
• DGGGʼs Consideration of Individual Points
• Coincidental finding of uterine sarcoma
• DGGG Statement #1
• DGGG Demand #1
• Preoperative diagnosis
• DGGG Recommendation #1
• DGGG Recommendation #2
• DGGG Demand #2
• Surgical management
• DGGG Statement #2
• DGGG Recommendation #3
• Pathological evaluation
• DGGG Recommendation #4
• Prognostic relevance
• DGGG Statement #3
• Treatment alternatives
• Information for patients
• DGGG Recommendation #5
• DGGG Demand #3
• Recall/Prohibition of Morcellators
• Summary
• References

Abstract

The appropriate surgical technique to treat patients with uterine fibroids is still a matter of debate as is the potential risk of incorrect treatment if histological examination detects a uterine sarcoma instead of uterine fibroids. The published epidemiology for uterine sarcoma is set against the incidence of accidental findings during surgery for uterine fibroids. International comments on this topic are discussed and are incorporated into the assessment by the German Society for Gynecology and Obstetrics (DGGG). The ICD-O-3 version of 2003 was used for the anatomical and topographical coding of uterine sarcomas, and the “Operations- und Prozedurenschlüssel” (OPS) 2014, the German standard for process codes and interventions, was used to determine surgical extirpation methods. Categorical qualifiers were defined to analyze the data provided by the Robert Koch Institute (RKI), the German Federal Bureau of Statistics (DESTATIS; Hospital and Causes of Death Statistics), the population-based Cancer Register of Bavaria. A systematic search was done of the MEDLINE database and the Cochrane collaboration, covering the period from 1966 until November 2014. The incidence of uterine sarcoma and uterine fibroids in uterine surgery was compared to the literature and with the different registries. The incidence of uterine sarcoma in 2010, standardized for age, was 1.53 for Bavaria, or 1.30 for every 100 000 women, respectively, averaged for the years 2002–2011, and 1.30 for every 100 000 women in Germany. The mean incidence collated from various surveys was 2.02 for every 100 000 women (0.35–7.02; standard deviation 2.01). The numbers of inpatient surgical procedures such as myoma enucleation, morcellation, hysterectomy or cervical stump removal to treat the indication “uterine myoma” have steadily declined in Germany across all age groups (an absolute decrease of 17 % in 2012 compared to 2007). There has been a shift in the preferred method of surgical access from an abdominal/vaginal approach to endoscopic or endoscopically assisted procedures to treat uterine fibroids, with the use of morcellation increasing by almost 11 000 coded procedures in 2012. Based on international statements (AAGL, ACOG, ESGE, FDA, SGO) on the risk of uterine sarcoma as an coincidental finding during uterine fibroid surgery and the associated risk of a deterioration of prognosis (in the case of morcellation procedures), this overview presents the opinion of the DGGG in the form of four Statements, five Recommendation and four Demands.

Zusammenfassung

In der Behandlung der Patientin mit Uterus myomatosus gibt es Diskussionen über die Art der Operationstechnik und das damit verbundene Risiko der eventuellen falschen Behandlung, wenn sich in der histologischen Aufarbeitung keine Uterusmyome, sondern ein Uterussarkom herausstellt. Die publizierte Epidemiologie von Uterussarkomen wird hier ins Verhältnis zu Zufallsbefunden bei Operationen zur Behandlung von Uterusmyomen gesetzt. Die internationalen Stellungnahmen zu diesem Thema werden diskutiert, um eine Bewertung seitens der Deutschen Gesellschaft für Gynäkologie und Geburtshilfe (DGGG) abzugeben. Zur anatomischen und topografischen Codierung der Uterussarkome wurde der ICD-O-3 in der Ausgabe von 2003 und für die Operations- und Prozedurenschlüssel der exstirpierenden Verfahren der OPS 2014 benutzt. Um die übermittelten Daten des Robert Koch-Instituts (RKI), des Statistischen Bundesamts (DESTATIS; Abteilung Krankenhausstatistik und Todesursachenstatistik), des bevölkerungsbezogenen Krebsregisters Bayern auswerten zu können, wurden eindeutige Abfragekriterien definiert. Zusätzlich wurde eine systematische Literaturrecherche in MEDLINE von 1966 bis November 2014 und bei der Cochrane Collaboration durchgeführt. Die Inzidenz von Uterussarkomen und Uterusmyomen bei Operationen der Gebärmutter wurden in den verschiedenen Registern und in der Literatur verglichen. Die altersstandardisierte Inzidenz im Jahr 2010 für Uterussarkome war für Bayern 1,53, respektive 1,30 auf 100 000 Frauen gemittelt über die Jahre 2002–2011, in Deutschland bei 1,30 auf 100 000 Frauen. Die mittlere Inzidenz aus verschiedenen Erhebungen beträgt 2,02 auf 100 000 Frauen (0,35–7,02; Standardabweichung 2,01). Stationär durchgeführte Operationen wie Myomenukleation, Morcellation, Hysterektomie oder Zervixstumpfresektion sind bei der Indikation Uterusmyom in Deutschland gleichbleibend über alle Altersgruppen hinweg zurückgegangen (absoluter Rückgang von 17 % im Jahr 2012 zum Jahr 2007). Es zeigt sich eine Verschiebung des operativen Zugangswegs von abdominal/vaginal zu endoskopisch bzw. endoskopisch assistierten zur Behandlung von Uterusmyomen mit einer ansteigenden Benutzung der Morcellation von fast 11 000 codierten Prozeduren im Jahr 2012. Nach den Veröffentlichungen von internationalen Stellungnahmen (AAGL, ACOG, ESGE, FDA, SGO) zum Risiko Uterussarkom als Zufallsbefund im Rahmen einer Myomoperation und dem damit verbundenen Risiko einer Prognoseverschlechterung (im Falle einer Morcellation) wird in dieser Übersichtsarbeit die DGGG-Stellungnahme in Form von 4 Statements, 5 Empfehlungen und 4 Forderungen dargestellt.

Introduction

In April 2014 the US Food and Drug Administration (FDA) published a communication entitled “Laparoscopic Uterine Power Morcellation in Hysterectomy and Myomectomy” [1]. Up to this point, no overall opinion or guideline on this topic had ever been issued by an authority, organization or medical society. Prior to this, only the American Society of Gynecologic Oncology (SGO) had briefly commented on the issue in 2013 [2], followed by a more detailed comment [3] after the publication of the FDA communication. After a meeting of the “Obstetrics and Gynecological Medical Device Advisory Panel” in July 2014, the FDA communication of April 2014 was updated in November 2014 [4]. Most recently, the communication concerning the most common surgical procedure to treat benign uterine fibroids led to lively and sometimes controversial global debates [5], [6], [7], [8]. In June 2014, one manufacturer of morcellators (Johnson & Johnson, Ethicon Inc.) stopped its “global commercialization […]” and in August 2014 the company initiated a voluntary worldwide recall [9], [10]. At the beginning of August 2014 the Bundesinstitut für Arzneimittel und Medizinprodukte (BfArM), the Federal Institute for Drugs and Medical Devices responsible for approval and licensing in Germany, sent an official letter of enquiry to the German Society for Gynecology and Obstetrics (Deutsche Gesellschaft für Gynäkologie und Geburtshilfe, DGGG). The Society answered the letter at the end of August, publishing their response on the homepage of the DGGG [11]. The DGGG shares the opinion that, in the interests of patients and users, the Society has an obligation to compile a comprehensive opinion which will also take account of the specifics of Germanyʼs national healthcare system and the surgical techniques currently used in Germany. In this context, the opinion will also consider the risks and probability of coincidental uterine sarcoma; however, this written opinion will not address the potential risk or probability of developing endometrial or cervical cancer subsequent to surgical procedures for the benign indication “uterine leiomyoma”.

Data Base of the Position Paper

The anatomical classification (uterus) was done using the topographical codes and histological classification (sarcoma) which are based on the morphological codes of the International Classification of Diseases for Oncology, third edition (ICD-O-3), from 2003 [12].

The coding of inpatient surgical procedures follows the Operationen- und Prozedurenschlüssel (OPS), the German code set for coding procedures and interventions, in the version from 2014. The codes used in this paper were classified either under the main category or in a subcategory, depending on the question ([Table 1]) [13].

To retrieve data from the Robert Koch Institute (RKI) and the population-based Cancer Register of Bavaria, 15 specific codes for gynecological sarcomas out of 88 possible codes used to encode sarcomas were selected for histological classification, based on the ICD-O-3 ([Table 2]). This histological classification was combined with the topographical code set for the affected organ. These include cervical intraepithelial neoplasias (C53.*), malignant neoplasm of corpus uteri (C54.*) and malignant neoplasm of uterus, part unspecified (C55.*).

Data from the Health Statistics and Causes of Death Statistics of the German Federal Bureau of Statistics (DESTATIS), which are based on the DRG (Diagnosis-Related-Groups) Statistics for 2005–2012, was retrieved using a combination of topographical and morphological ICD-10-GM axes as follows: “D25.* and OPS 2014 (5-681.2* or 5-681.3* or 5-681.4 or 5-681.5 or 5-682.* or 5-683.* or 5-684.4)” ([Table 1]). They described the primary surgical procedures carried out following a primary diagnosis of leiomyoma (D25.*). These were listed according to the respective federal state in Germany, the date of the survey and the age of the patient [13], [14].

A systematic keyword-based literature search was done in MEDLINE. The query searched for English or French abstracts and full publications between 1966 and November 2014 on uterine sarcomas after morcellation, hysterectomy or myomectomy procedures. The search algorithm was “((uterine sarcoma AND morcellation) OR (uterine sarcoma AND hysterectomy) OR (uterine sarcoma AND myomectomy) OR (Fibroids[MeSH] and morcellation) OR (Fibroids[MeSH] AND myomectomy) OR (Fibroids[MeSH] AND hysterectomy)) AND ("1966/01/01"[Date – Publication]: "2014/11/30"[Date – Publication])”. An additional search was done of the Cochrane Database or Library in November 2014 looking for the terms “sarcoma” or “morcellation” or “hysterectomy” or “myomectomy”.

Basics of Uterine Sarcomas

The German S1 Guideline (AWMF registry number 015-074) on “Uterine Sarcomas” will soon be published. The Guideline will give a detailed overview of the basics of uterine sarcomas including epidemiology, diagnostics, classifications, therapy and follow-up [15]. The statements quoted below in this paper are only those relevant for this opinion.

Epidemiology

The data on the annual incidence of uterine sarcomas in the international literature ranges from 0.35 to 7.02 for every 100 000 women, depending on the investigated cohort ([Table 3]) [16], [17], [18], [19], [20].

Targeted queries of the RKI and the population-based Bavarian Cancer Register found an age-standardized incidence in 2010 (standardized for the European population) of 1.32 per 100 000 women in Germany and of 1.53 per 100 000 women in Bavaria [21]. The mean age-standardized incidence for a longer observation period (between 2002 and 2011) was 1.30 for every 100 000 women in Bavaria [22]. It is known from the literature that the overwhelming majority of the 1164 cases listed for the period 2002–2011 for Bavaria ([Table 4]) and the 2079 cases recorded for the period 2009–2011 across all of Germany were postmenopausal women [5], [21], [22], [23]. This means that more than 80 % of women in Bavaria and Germany are older than 50 years when they receive a primary diagnosis of uterine sarcoma ([Figs. 1] and [2]) [21], [22].

A synopsis of age-standardized incidence rates (European or American population) resulted in a mean value of 2.02 for every 100 000 women (0.35–7.02; standard deviation 2.01) per year ([Table 3]). The prevalence cannot be ascertained from these individual surveys without matching the data to that from a register of residents or other sources showing changes in populations.

Risk factors

Risk factors – some of them identified based on very small sample sizes – include age [18], [24], ethnicity [16], [17], [18], [25], prior pelvic radiotherapy [26], prior administration of anti-estrogens with partial uterine estrogen effect such as tamoxifen [27], [28], [29], [30], [31], and genetic predisposition (Lynch syndrome and others) [32], [33].

Diagnostics

Despite taking a thorough patient history including the patientʼs familial history, carrying out a physical exam and the use of imaging methods (cf. Preoperative Diagnosis), it is not possible to differentiate a myoma from a sarcoma; this can only be done postoperatively during the histopathological workup.

Histological classification

A sarcoma is a malignant neoplasm which develops in mesenchymal tissue. This heterogeneous tissue can consist of connective tissue, fat tissue, musculature, bones or cartilage. In gynecological oncology, the sarcoma is located in the uterus in 7 % of cases [34]. In ⅔ of these cases these soft-tissue sarcomas originate in the smooth musculature of the myometrium and take the form of leiomyosarcomas (LMS). The second most common histological type is endometrial stromal sarcoma (ESS), without using the now obsolete differentiation into low-grade and high-grade types. The third most common entity is undifferentiated endometrial stromal sarcoma (UES). Rhabdomyosarcomas originating from striated muscles or adenosarcomas of the Mullerian ducts are very rare. Carcinosarcomas, better known as malignant Mullerian mixed tumors (MMMT), are no longer classed as belonging to the entity of sarcomas but are now classed as malignancies of epithelial origin, in other word as pure carcinomas [35], [36].

Prognostic factors

The prognosis of patients with uterine sarcomas depends on the sarcomaʼs histological type. However, there are other factors which do not affect the prognosis quite so strongly ([Table 5]) [23], [35], [37], [38], [39], [40], [41], [42], [43]. This paper looks particularly at the risk factor “malignant disseminated ‘peritoneal’ iatrogenic tumor cell spread” [44].

Treatment strategies

The therapeutic approach depends on the therapeutic setting (curative, palliative). In the curative setting, it is important to differentiate between obligatory surgery and facultative chemotherapy [15].

Surgery

Irrespective of the sarcomaʼs histological type, the recommendation must always be surgery with non-preservation of the uterus. In principle, no morcellation should be done during organ removal of any sort because of its potential to worsen prognosis (cf. chapter: Prognostic relevance). Total abdominal hysterectomy is the surgery of choice for LMS, the most common histological type. After weighing up the benefits and risks, bilateral salpingo-oophorectomy (BSO) should always be carried out in premenopausal and postmenopausal women or when surgical findings are normal. Total abdominal hysterectomy, always accompanied with bilateral adnexectomy, is also recommended for ESS, the second most common histological type. The adnexa can be preserved in selected cases with FIGO stage I sarcoma [45]. Systematic pelvic and paraaortal lymphonodectomy is not routinely recommended for LMS and ESS [36], [46].

This paper does not cover systemic therapies in the curative and palliative setting.

Surgical Procedures for Uterine Fibroids

Surgery to treat uterine fibroids can include organ preservation or involve partial or total organ removal [47]. Three different approaches (abdominal, laparoscopic, vaginal) or a combination of the three are used for the surgical treatment of uterine fibroids ([Fig. 3]) [48].

A German S2k Guideline (AWMF register number 015-070) on “Indications and Methods for Hysterectomy” will also be published in the near future [49]. For this reason, we only present specific data on morcellation.

Minimally invasive surgical procedures

The most commonly used approach used in Germany since 2010 to remove leiomyomas is a laparoscopic approach: myoma enucleation is done in procedures with organ preservation, and subtotal or total hysterectomy is done in procedures with organ removal ([Fig. 3]). Coincidental findings of uterine sarcomas therefore occur most commonly with this approach. Some of the benefits of laparoscopic hysterectomy procedures compared to abdominal hysterectomies have been evaluated and were found to be statistically significant, although they may not be economically and/or clinically relevant:

• Shorter convalescence time (mean difference [MD] of 13.6 days; 95 % CI: 11.8–15.4 days; p = 0.004) [50];

• Lower intraoperative blood loss (MD 45 ml; 95 % CI: 17.9–72.7 ml) [50],

• Fewer postoperative wound infections (odds ratio 0.31; 95 % CI: 0.12–0.77) [50],

• Lower postoperative pain (using the VAS) after 8 h (MD − 2.4 VAS; 95 % CI: − 2.88 to − 1.92) and 48 h (MD − 1.9 VAS; 95 % CI: − 2.8 to − 1.0) [48],

• Shorter hospital stay (MD 2 days; 95 % CI: 1.9–2.2 days; p < 0.00001) [50], and

• Better cosmesis.

Morcellation is part of the surgical technique. The morcellation of benign tissue reduces the size of the tissue pieces requiring removal, making it easier to retrieve them. Every morcellation leads to destruction of myometrial tissue. Two techniques are currently used:

1. using a scalpel or scissors, or

2. using an electromechanical device (“power morcellation”).

The above listed morcellation techniques can be used in all surgical procedures, irrespective of whether the approach is vaginal, minimally invasive. The technique may be supported using an assisted open approach with a mini-laparotomy for the incision to retrieve the fibroid to avoid a full abdominal incision [51]. The fibroid can be additionally retrieved using a specimen retrieval bag [2], [5].

The earliest case describing morcellation was published in 1993; since then, the distribution of minimally invasive surgery has meant that the procedure has become increasingly sophisticated [52], [53]. Associated complications included injuries of the ureters, the bladder and the bowel [54].

Preservation of the uterus

If the fibroid is removed using an minimally invasive approach with preservation of the uterus, then morcellation of the leiomyoma with preservation of the uterus during laparoscopic or hysteroscopic myomectomy of the abdomen or uterine cavity is indispensible. Supplementary or new wound surfaces are created for laparoscopic retrieval through a secondary abdominal or vaginal incision. Primary abdominal myomectomy to preserve the uterus is indicated in exceptional cases if minimally invasive surgical procedures cannot be used. Hysterotomy with incision of the myometrium occurs even with these abdominal myomectomies, with the potential for sarcoma and tumor cell dissemination.

Removal of the uterus

Supracervical hysterectomy using a minimally invasive or open approach is indicated for partial – i.e. subtotal – uterus removal. Laparoscopy-assisted supracervical hysterectomy (LASH) includes intra-abdominal destruction of myometrial tissue using a morcellator.

Total removal of the uterus can be done using a minimally invasive, open or vaginal approach. If the volume of the uterus is very large vaginal exstirpation is often not possible due to the surrounding soft tissue. If vaginal retrieval is possible after total laparoscopic hysterectomy (TLH) or laparoscopy-assisted vaginal hysterectomy (LAVH) procedures intra-abdominal destruction of uterine tissue is often not necessary. Morcellation becomes necessary even vaginal approach is used, if the uterus is too large to the surrounding soft tissue. Use of a morcellator is one option; however, morcellation can also be done using an open vaginal approach.

Surgery and other procedures to treat uterine fibroids

The data of the DRG statistics was collected for the years 2005–2012. The analysis investigated which preselected operation was used to treat uterine fibroids, grouped according to diagnosis using the main category or the subcategory (cf. [Table 1]) and depending on whether the uterus was preserved or removed.

The total number of uterine fibroids coded as ICD-10 D25.* in women operated as inpatients has continually decreased since 2007 (17 % decrease in absolute numbers by 2012). This decrease is not only due to a drop in the specially selected coded surgical procedures. There has also been a reduction in the overall number of myomas classified as ICD-10-GM D25.*. Either the absolute number of women with uterine leiomyomas has not increased, or surgical procedures are increasingly done on an outpatient basis, meaning that they are coded using a different data entry system. It is not possible to make any statements here about patients operated on an outpatient basis.

The decreased age distribution of patients operated on for uterine fibroids has remained approximately the same during the data collection period 2005–2012 ([Fig. 5]) [14].

There was a linear correlation between laparoscopic subtotal hysterectomies (5-682.02) and coded morcellation procedures (5-681.4) for the primary diagnosis of uterine fibroids D25.* ([Fig. 6]). A similar correlation was found between total laparoscopic hysterectomy procedures (5-683.03 or 5-683.13 or 5-683.23 or 5-683.x3) and morcellation (5-681.4) ([Fig. 7]). No correlation was found for myoma enucleation (5-681.2*) and approach. In absolute numbers, in 2012, the last year of the survey, morcellation for uterine fibroids was carried out in 10 987 cases compared to the year 2005 where the number of coded procedures was 4005; this would correspond to an increase of approximately 175 % [14].

Summary of the Basic Stance of the Position Paper

Uterine sarcoma is a very rare malignancy in women. The incidence in Germany in 2010, standardized for age, was 1.32 for every 100 000 women. Known risk factors are age, pelvic irradiation and tamoxifen use. LMS is the most common histological type, followed by ESS and UES. Rhabdomyosarcomas and adenosarcomas are very rare. MMMTs are no longer classified as sarcomas but as carcinomas. There are a number of suspected prognostic factors but the scientific evidence for these is ambiguous.

Primary treatment for uterine sarcomas in the curative setting should be surgery. The decision for a BSO depends on the patientʼs age and the histological type. Staging lymphonodectomy is not indicated.

Leiomyomas can be treated with different surgical procedures. Procedures are differentiated according to the preferred approach, which can be minimally invasive (endoscopic), open surgical, vaginal, or a combination of these approaches. Surgery can involve preservation of the uterus or uterus removal. A minimally invasive approach can offer significant benefits compared to open surgery. One disadvantage can be the destruction of myometrial tissue through morcellation with an associated risk of malignant dissemination of a uterine sarcoma. In principle, all extirpating procedures used for hysterotomy, whether performed with or without morcellation, involve the risk of disseminating malignant cells in the abdominal cavity.

Analysis of the DRG statistics for the years 2005–2012 obtained from the Federal Bureau of Statistics in Germany showed that the absolute numbers of surgeries for leiomyoma carried out in hospitals have significantly decreased. The age distribution remained constant across all types of operations. Despite this decline in surgical procedures, there was a linear correlation between the increase in the absolute number of morcellations and laparoscopic subtotal and total hysterectomy procedures. As expected, the data showed a shift towards the preferred approach from abdominal/vaginal to endoscopic with a concurrent increase in the number of morcellations.

Hypothesis

Hysterotomy as single technique and the additional morcellation during hysterectomy or myomectomy is associated with a low probability of iatrogenic spread of a previously unknown, very rare uterine sarcoma. There is a minimal risk of dissemination of sarcoma cells associated with this procedure in individual cases, which, in these cases, could worsen the patientʼs prognosis. There is therefore an ongoing debate about whether morcellators should no longer be used in surgical procedures for uterine leiomyomas. The FDA has generally advised against the continued use of morcellators, and this position paper of the DGGG will specifically consider the individual aspects of this advice and give its own considered opinion about the risk of mistakes when treating uterine sarcomas.

International Opinions (Overview)

Various authorities/organizations/professional societies have reported on the incidence of uterine sarcoma as an coincidental finding during extirpation procedures to treat uterine leiomyomas or hysterectomies using morcellators and made a number of general recommendations or demands ([Table 6]). The five opinions published to date include a statement by the American SGO published in December 2013 [2] and updated in April 2014 [3], a comment by the FDA published in April 2014 [1] and updated in November 2014 [4], statements by the American College of Obstetricians and Gynecologists (ACOG) [6] and the Advancing Minimally Invasive Gynecology Worldwide (AAGL) published in May 2014 [5], [8], and a statement submitted by European Society for Gynaecological Endoscopy (ESGE) in December 2014, which is still in press [55]; all of them advocate informing patients extensively and in detail. The information given to patients about intra-abdominal morcellation using laparoscopy or robot-assisted techniques must include mentioning of the surgical benefits of this method, all potential risks involving the spread of malignant tissue, and possible alternatives. The second general consensus is the comprehensive rejection of morcellation if there is any suspicion of uterine malignancy. The probability of a coincidental finding of a sarcoma verified on pathological examination during hysterectomy or myomectomy is between 1/204 and 1/7400, depending on the opinion [1], [2], [3], [4], [5], [6], [55].

As the authority responsible for licensing and approval in the United State, the FDA has a significant impact on clinical practice in the USA. After recommending in April 2014 that the indications for surgery be reviewed, the recommendations in November 2014 were more specific [1], [4]. The FDA was the only institution at the time to generally advise against the use of morcellators to remove leiomyomas in the following statement: “the FDA discourages the use of laparoscopic power morcellation during hysterectomy or myomectomy for uterine fibroids” [1]. Since then, this recommendation has been rephrased and the following two contraindications have been included [4]:

1. Morcellators are contraindicated for removal of uterine tissue containing suspected fibroids in patients who are peri- or post-menopausal or are candidates for en-bloc tissue removal through the vagina or mini-laparotomy incision.

2. Morcellators are contraindicated in patients with uterine fibroids suspicious for malignancy.

The scientific basis of the first statement made by the FDA in its most recent communication is unclear.

Based on the communication of the SGO [2], which the FDA initially referenced, the AAGL and the ACOG published their own communications one month later, followed by the ESGE at the beginning of 2015 [5], [6], [55]. The communication of the ESGE is publicated. These communications are scientific reviews; they are far more comprehensive, include information on the evidence and sometimes criticize the recommendations issued by the FDA in its first communication on this subject. One of the initial points of criticism was the lack of a medical weighing up of the potential risks of morcellation of leiomyomas against the well-known benefits of a minimally invasive surgical approach. The AAGL and the SGO thus do not agree with the recommendation of the FDA prescribing an inexplicably restrictive use of morcellators [3], [5], [8]. A second point of criticism was the lack of stratification of patient characteristics and a lack of information about the data underpinning the FDAʼs probability calculation, which gave a 1/350 probability of a coincidental finding of uterine sarcoma during hysterectomy or myomectomy [5]. The latter point of criticism was discussed in somewhat greater detail in the FDA update issued in November 2014 [4]. The limited published studies were severely criticised for their study design [3], [8].

In addition to recommendations, a number of demands were also made to the authorities, the manufacturers and the physicians. Data which could answer critical questions is currently not sufficient to make strong recommendations based on scientific literature with high levels of evidence. As with most demands, there is an urgent need for better and more robust scientific data ([Table 6]).

DGGGʼs Consideration of Individual Points

Coincidental finding of uterine sarcoma

The DGGG supports the critical comments by the AAGL and the ESGE against the line of reasoning taken by the FDA regarding the coincidental finding of uterine sarcoma during hysterectomy or myomectomy. In its first analysis, the FDA describes the source of the data used for its communications as follows: “based on an FDA analysis of currently available data”. This statement was included in the first communication and was amended in the most recent communication of the FDA where it now reads “The FDA conducted a review of published and unpublished scientific literature, including patients operated on from 1980 to 2011 to estimate the prevalence of unsuspected uterine sarcoma and uterine leiomyosarcoma in patients undergoing hysterectomy or myomectomy for presumed benign fibroids (leiomyoma)”. This most recent statement still does not permit any conclusion to be drawn about the methodology, the literature reviewed, or the method of analysis used [1], [4], [5], [55]. Nevertheless, the frequencies given in the five communications are between 1/204 and 1/7400 (0.49–0.014 %), which generally corresponds to those in other papers which have reported mean frequencies of about 1/420 (0.24 %) ([Table 7]). However, the frequencies given in the five international communications ([Table 6]) refer without exception to hysterectomy or myomectomy procedures and not to the real topic of the communication, i.e. the incidence and risk associated with morcellation [1], [2], [6]. Three papers have been published which discussed the coincidental finding of uterine sarcoma in actual morcellation procedures, and the reported incidence has ranged from 1/250 to 1/545 (0.40 to 0.18 %) [44], [51], [56]. This gives a mean incidence of 1/416 (0.24 %) for the finding of a uterine sarcoma during morcellation carried out as part of a myomectomy or hysterectomy procedure ([Table 7]). A further paper on morcellation could not be evaluated because it did not include information about the basic population size and its relation to the eight detected sarcomas [57]. One evaluation published this year included 232 882 patients who underwent minimally invasive hysterectomy; morcellation was carrried out in 36 470 cases (15.7 %). Uterine malignancy was found in 99 cases. This would correspond to an incidence of 1/368 (0.27 %) based on more than 36 000 morcellations. No separate evaluation was done of the histological findings or of the individual uterine sarcomas [58]. The probability for uterine sarcoma is probably much lower than the incidence reported for not otherwise specified uterine malignancies. It is generally assumed that the percentage of uterine sarcomas in uterine malignancies is 3–7 % [17], [59]. The precise surgical setting in which the morcellations were carried out in this study were also not described in detail. The papers refers to 59 non robot-assisted procedures and 40 robot-assisted surgical operations [58].

The conclusion was that the data was sufficient to determine the incidence for the combined endpoint “coincidental finding of uterine sarcoma” and the therapeutic setting of “uncomplicated hysterectomy, myomectomy and/or morcellation for a mass previously assumed to be benign”; the incidence across all studies was found to be 21/8753 or 1/417 (0.24 %), respectively ([Table 7]). Based on three selected studies out of the ten referenced papers, the probability of coincidental uterine sarcoma on morcellation was approximately 1/416 (also 0.24 %) ([Table 7]). Based on the meeting of the Obstetrics and Gynecology Devices Panel of the FDA Medical Devices Advisory Committee on July 11, 2014, after which the FDA subsequently updated its communication [4] and the as yet unpublished ESGE communication, the reported figure is 1/7400 (0.014 %) [55], [60].

There are three criticisms which need to be made about the available data for the individual methods used, because they are particularly relevant for these ten studies:

1. Not all of the papers specified the approach used; this means that there is no information about the specific surgical procedure during which the sarcoma was detected [61], [62], [63].

2. Even if the approach used is mentioned, the specific surgical procedure during which the sarcoma was detected is sometimes still lacking [61], [62].

3. Even if the primary surgical procedure is included, the figures were not calculated with reference to the total patient population [57].

Moreover, the design of individual studies was also problematic: nine of the ten articles were single-center studies. Eight of the ten articles described retrospective studies. Not a single article describing a randomized multicenter design has been published to date. In seven of the ten articles, the period of data collection commenced before the millennium, which would affect the diagnostic and technical methods used ([Table 7]).

In Germany, the probability of finding uterine sarcoma during a procedure for a benign preoperative indication (uterine fibroids) must be set against the increasing number of laparoscopic organ-sparing (enucleation) or organ-removing (sub-/total hysterectomy) procedures ([Fig. 3]) being carried out, as the total number of operations for uterine fibroids carried out in hospital continues to decrease ([Fig. 4]). The percentage of laparoscopic approaches increased from 13 % in 2002 to 47 % in 2012. In the same period, the percentage of coded morcellations (irrespective of the chosen approach) increased from 5.6 % in 2002 to 19.6 % in 2012. However, the calculated ratio for morcellation of uterine fibroids in laparoscopic procedures remained fairly constant for this decade at 0.39 to 0.43. This means that morcellation is carried out in every 2nd or 3rd woman with an indication of surgery for leiomyoma using neither a vaginal nor an abdominal approach.

As the age-specific incidence of uterine sarcoma has remained approximately the same at 1.32 and 1.30 for every 100 000 women in Germany and Bavaria, respectively, and the number of laparoscopies and morcellations of leiomyomas has increased, the statistical probability of finding uterine sarcoma during surgery decreases ([Table 4]) [14], [21], [22].

DGGG Statement #1

The risk for coincidental uterine sarcoma during hysterectomy with hysterotomy and/or myomectomy is approximately 1/416 (0.24 %). Based on an evaluation of the most recent literature it is ultimately not possible to quantify precisely the risk of uterine sarcoma after hysterotomy with or without morcellation.

DGGG Demand #1

Every morcellation which is accompanied by coincidental finding of uterine sarcoma should be reliably documented in the Cancer Register as this will permit the probability of uterine malignancy (including uterine sarcoma) to be quantified more precisely in future. The Register should include the following items:

1. indications

2. preoperative diagnosis

3. general patient characteristics

4. surgical approach and surgical technique

5. histological data

6. progress of disease

7. precise histological description

Preoperative diagnosis

All five communications agree that it is not possible to make an unambiguous and precise diagnosis preoperatively, nor are there any surrogate markers which are capable of differentiating preoperatively between benign leiomyoma and malignant uterine sarcoma (LMS or ESS) [1], [2], [5], [6].

The most common clinical symptoms for uterine sarcoma reported in 47 to 70 % of cases were atypical vaginal bleeding and pain [34], [36], [61], [64], [65]. Another possible clinical sign is a rapid increase in uterine size. The few existing studies on this topic were unable – given the limited number of cases with uterine sarcoma in the total patient population and the retrospective design of the studies – to identify “rapid growth” as a surrogate marker of malignancy. Many patients presented with rapid uterine growth without having uterine sarcoma or had uterine sarcoma without rapid uterine growth. This clinical symptom cannot therefore be used as a confirmation of the suspicion of uterine sarcoma [43], [62], [66], [67], [68].

There are few reports on preoperative histopathological investigation for suspicion of malignancy prior to laparoscopy with planned morcellation [69]. One study investigating 63 patients carried out ultrasound-guided core-needle biopsy for previously unclear uterine mass on MRI. Malignancy was found in 12 cases (19 %) and histology was benign in 51 cases (81 %), 27 of which underwent surgery. Only one histological evaluation of a surgical specimen (4 %) found previously undetected uterine sarcoma contrary to the preoperative findings of core-needle biopsy. This corresponds to a positive predictive value (PPV) of 100 % and a negative predictive value (PNV) of 96.2 % [70]. A large review of 730 patients documented 142 uterine sarcomas (20 %). 72 uterine sarcomas (51 %) were identified histologically prior to surgery using pipelle biopsy or fractional curettage. There was no significant difference in the method used for histological sampling between biopsies and curettage (p = 0.84). The study did not include detailed information on patients or whether they were a high-risk patient population [71].

Use of such well-known imaging procedures as transvaginal ultrasound (VUS) [46], computer tomography (CT) [72], magnetic resonance imaging (MRI) [46], [72], [73], [74] or positron emission tomography (PET) with CT [46] has been proposed and described. But these imaging methods have been found to have limitations, particularly in younger patients suspicious for ESS. As expected, the group of authors who compiled this paper have come to the conclusion that imaging cannot exclude uterine sarcoma (LMS or ESS), it can only confirm the suspicion [46]. It is also not possible to differentiate the various histological types (LMS, ESS, UES, adenosarcoma, MMMT) preoperatively [74].

The usefulness of well-known tumor markers such as LDH or CA 12–5 for preoperative diagnosis is very limited [15].

Some authors have proposed carrying out a PAP test in all patients scheduled to undergo hysterectomy with morcellation [75]. This could also be used to diagnose cervical or endometrial cancer.

All relevant communications strongly advise against performing minimally invasive procedures in patients with unclear uterine findings suspicious for malignancy [1], [2], [4], [5], [6], [55].

DGGG Recommendation #1

There are no means of obtaining an unambiguous diagnosis preoperatively, and there are no clear criteria to evaluate suspicious findings detected during preoperative examination. Thorough patient history (including risk factors and symptoms), vaginal ultrasound examination and possibly preoperative cytological and/or histological evaluation (hysteroscopy, curettage) of abnormalities could be useful, but these methods cannot entirely rule out the possibility of sarcoma. CT, MRI or PET/CT may provide useful imaging support when assessing the risk in individual patients, but they cannot rule out the presence of uterine sarcoma in any patient, too.

DGGG Recommendation #2

If the preoperative diagnosis is unclear or doubtful, no minimally invasive procedure or morcellation should be recommended or carried out in patients where there is a suspicion of potential uterine malignancy.

DGGG Demand #2

A prospective risk score should be developed, e.g. a nomograph, which would include the few scientifically proven items and could be used to identify groups at risk for uterine sarcoma preoperatively.

Surgical management

Together with the patient, the treating physician should carry out a benefit/risk analysis of a minimally invasive procedure with morcellation. In addition to preoperative measures such as correct indication and diagnostic workup of suspicious uterine findings, surgical techniques must include intraoperative measures to avoid malignant peritoneal spread. These can include the use of specimen retrieval bags or the use of closed systems in general [5], [9]. Whether these methods will reduce the risk of dissemination compared to an investigated control group has only been investigated in small cohorts with limited cases numbers (n = 8–12) and without comparable control groups [76], [77]. If specimen retrieval bags are used, then this needs to be done consistently in the interests of oncological safety [2], [5]:

1. Puncture of the specimen retrieval bag must be avoided,

2. Visualization should be extracorporeal, and should be covered access ports.

In the event of coincidental uterine sarcoma, primary surgery should be done as a two-stage procedure. If the planned procedure prior to the coincidental finding was myoma enucleation or LASH, then the entire uterus or cervix uteri should be completely removed [34], [78]. A second operation should be carried out as an open surgical procedure and must include careful inspection of the entire abdomen with careful histological workup of suspicious areas because higher-stage disease with regional spread is associated with a poorer prognosis [39]. The decision for adjuvant therapy subsequent to surgery must be discussed individually with the patient. In principle, it is recommended that the patient is presented to a certified gynecological cancer center which has the appropriate expertise.

If a suspicion of malignancy arises intraoperatively, then the operation should be discontinued. Usually, if the preoperative indication was benign, the patient will not have been informed about one-stage procedures for malignancy. Intraoperative frozen section assessment is often not diagnostically conclusive and should therefore not be carried out.

DGGG Statement #2

Because of the limited number of studies, it is not possible to give a definitive recommendation concerning the use of specimen retrieval bags.

DGGG Recommendation #3

If the preoperative indication was benign mass and a uterine sarcoma is identified intraoperatively, surgery should consist of a two-stage open procedure. The second operation should comply with current oncological principles and be carried out in a certified oncological institution.

Pathological evaluation

The final pathological evaluation which includes the option of additional immunhistochemical staining of the primary surgical specimen is a relevant prognostic factor and directly affects the decision for therapy [36].

DGGG Recommendation #4

Histopathological evaluation should be done using formalin-fixed paraffin-embedded (FFPE) surgical specimens. Correct histological classification is only possible using a specimen obtained during surgery.

Prognostic relevance

A number of factors are assumed to be prognostic factors ([Table 5]). But almost no studies have carried out a prospective evaluation in a multivariate model (cf. Prognostic factors). The prognostic relevance of the factors described in the literature is unclear, and they are therefore not necessarily synonymous with a deterioration or improvement of prognosis. Morcellation or rupture of a uterine sarcoma should receive more attention, and the issue is currently an important topic of discussion. Some studies showed a clear deterioration of prognosis after primary morcellation of a uterine sarcoma which had not been identified preoperatively [43], [79], [80], [81]. One study group from Seoul carried out a retrospective single-center study of 56 patients (Group 1 morcellation: n = 25, Group 2 no morcellation: n = 31) and found a lower disease-free survival (DFS) and overall survival after morcellation on univariate analysis with a 5-year survival rate of 73 vs. 46 % (OR 3.07; 95 % CI: 1.19–8.93; p = 0.040). This was also confirmed on multivariate analysis (OR 3.11; 95 % CI: 1.07–9.06; p = 0.038) [43]. Another study reported that perioperative tumor rupture reduced the 5-year survival rate of 382 patients from 64 to 27 % with a hazard ratio (HR) of 3.24 (95 % CI: 2.34–4.48; p = 0.0001). On multivariate analysis the HR was 2.12 (95 % CI: 1.39–3.25; p = 0.0005) for tumor rupture [79]. This was similar to intraoperative macroscopic tumor remnant, which had a HR of 3.99 (95 % CI: 2.72–5.86; p = 0.0001). Other studies have confirmed the findings of a poorer prognosis after morcellation [80], [81]. But these findings were contradicted by one study which reported that the prognosis did not differ between groups [82]. Higher-stage disease did not always lead in every case to a poorer prognosis with a lower 5-year overall survival, for example from stage I (51 %) to stage II (25 %) LMS or from stage I (84 %) to stage II (62 %) ESS [39]. In patients with higher-stage disease, morcellation probably had less impact because prognosis was already poor compared to patients with early-stage uterine sarcoma and a better prognosis.

When assessing the deterioration of prognosis, studies did not differentiate between hysterotomy alone with myoma manipulation and extirpation of the myoma with morcellation. The incidence of retained benign parasitic tissue reported for the latter method was 0.12–1.2 %. It is not clear whether a second operation carried out within a short space of time could solve this problem of prognosis or whether patients with residual tissue have a particularly poor prognosis [55].

DGGG Statement #3

Dissemination of malignant tumor cells in the abdominal cavity results in a poorer prognosis. It is not possible to give precise figures about the extent of the deterioration of prognosis.

Treatment alternatives

Alternative surgical und interventional procedures such as uterine artery embolization (UAE) or radiofreqency ablation can be offered to selected patients with uterine fibroids not suspicious for malignancy. Additional innovative procedures to treat uterine leiomyomas include non-invasive procedures such as MR-guided focussed ultrasound (MRgFUS) [83], [84], [85], [86], [87]. The data (case reports) on coincidental uterine sarcomas for these less common alternatives is even less conclusive [88], [89].

Information for patients

Patients should be provided with information on the benefits, risks or disadvantages, and alternatives. By giving her consent, the patient indemnifies the physician against claims for bodily harm by negligence pursuant to section 229 of the German Criminal Code (Strafgesetzbuch § 229). The information given to the patient must also cover risks which are extremely rare but which – if they do occur – can have life-threatening implications [90].

The information on minimally invasive extirpation procedures to treat uterine fibroids should include information on the potential use of morcellation. The explanation of the advantages associated with a laparoscopic approach already largely covers the benefits of morcellation. The specific risks and disadvantages of morcellation outlined in the recommendations of the AAGL need to be listed and communicated to the patient in a modified and comprehensible form [5]. Risks include:

1. injury to adjacent organs, vessels or nerves [54];

2. dissemination of benign tissue in the abdomen and pelvis [91];

3. dissemination of potentially malignant tissue in the abdomen and pelvis which may worsen the prognosis [44];

4. histopathological evaluation of the tissue specimen may be more difficult because the specimen is fragmented;

5. a potential need for re-operation or further treatment (second operation, chemotherapy, radiotherapy) [51].

One hospital in Germany (Tübingen, personal communication) has already developed and amended an addendum to the established information sheets for all vaginal, abdominal, laparoscopic and hysteroscopic procedures ([Fig. 8]). This information sheet which describes the risk of disseminating malignant tumor cells for the above listed procedures serves as a good example for the relevance of this topic.

DGGG Recommendation #5

During preoperative discussions the patient must be informed in detail about the benefits, risks and disadvantages of planned minimally invasive procedures without/with morcellation as well as the potential alternatives.

DGGG Demand #3

The informed consent forms currently used in hospitals need to be modified or supplemented by additional information sheets for patients.

Recall/Prohibition of Morcellators

The manufacturer Ethicon Inc. (Johnson-Johnson) announced in June 2014 that it would “suspend global commercialization (sales, distribution and promotion) of its Morcellation Devices” [9]. A worldwide voluntary recall action was initiated in August 2014. The notice for the voluntary recall stated: “… the risk-benefit assessment associated with the use of these devices in hysterectomy and myomectomy procedures for removing fibroids remains uncertain. Because of this uncertainty, Ethicon believes that a product recall of Ethicon Morcellation Devices is the appropriate course of action at this time until further medical guidelines are established and/or new technologies are developed to mitigate the risk.” The notice references the FDA recommendations of April 2014 as the reason for this recall. Detailed instructions on how to proceed with the recall are appended to the recall notice [10].

DGGG Statement #4

Both the probability estimate and the risk assessment of a deterioration of prognosis must be completely resolved. Whether, after proper consideration of all aspects, patient safety will increase following the prohibition ban or sales ban of morcellators cannot currently be answered definitively. Benefits and risks of morcellator use must be weighed up in discussions with each individual patient. In this context, weighing up means outlining all the risks and the benefits of open versus laparoscopic procedures and weighing up one against the other.

DGGG Demand #4

The product information needs to be modified. Even a minimal risk is still a risk that needs to be mentioned.

Summary

1. Uterine sarcoma is a rare malignancy which affects women. The incidence in Germany standardized for age is estimated to be approximately 1.32 for every 100 000 women. Over 80 % of patients are more than 50 years old.

2. A number of risk factors (age, tamoxifen use, pelvic irradition) and various clinical, pathological and therapeutic prognostic factors have been described. A prospective risk score to identify risk groups should be developed (Demand #2).

3. According to the current scientific evidence, the incidence for the coincidental finding of uterine sarcoma for a combined endpoint (hysterectomy, myomectomy, morcellation) is estimated to be about 1/416 (0.24 %). It is not possible to make a scientific statement about the risk of coincidental uterine sarcoma differentiated according to individual surgical methods (Statement #1). Register studies to estimate the risk are necessary (Demand #1).

4. There are currently no preoperative examinations or diagnostics capable of differentiating unambiguously between benign and malignant entities (Recommendation #1).

5. In patients with diagnostically unclear uterine findings suspicious for malignancy it is recommended not to use a minimally invasive approach (Recommendation #2).

6. Use of a specimen retrieval bag is not suitable to prevent malignant peritoneal dissemination definitely and deterioration of prognosis. Use of a specimen retrieval bag does not justify an uncritical use of morcellators (Statement #2).

7. In the curative setting, uterine sarcomas should be treated by primary surgery in accordance with current oncological principles (Recommendation #3).

8. Complete histopathological evaluation should be done using a formalin-fixed surgical specimen (Recommendation #4).

9. Dissemination of malignant tissue may worsen the patientʼs prognosis. The current data is not sufficient to arrive at a definitive conclusion which would allow an estimate of the deterioration of prognosis for the individual patient (Statement #3).

10. The patient must be provided with detailed information; procedures require the patientʼs informed consent (Recommendation #5). The established information sheets in German hospitals need to be modified (Demand #3).

11. It is currently not possible to state whether a prohibition and sales ban of morcellators will improve patient safety. The benefits and risks of morcellator use must be weighed up in individual discussions with the patient (Statement #4). The product information needs to be modified (Demand #4).

Conflict of Interest

None.

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Correspondence

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  PubMedGoogle Scholar
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• 89 Common AA, Mocarski EJ, Kolin A et al. Therapeutic failure of uterine fibroid embolization caused by underlying leiomyosarcoma. J Vasc Interv Radiol 2001; 12: 1449-1452
  CrossrefPubMedGoogle Scholar
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  PubMedGoogle Scholar
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  PubMedGoogle Scholar
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  PubMedGoogle Scholar
• 94 Takamizawa S, Minakami H, Usui R et al. Risk of complications and uterine malignancies in women undergoing hysterectomy for presumed benign leiomyomas. Gynecol Obstet Invest 1999; 48: 193-196
  CrossrefPubMedGoogle Scholar

• Supplementary Material