**1.2 History of adenomyosis**

In the mid-nineteenth century, Rokitansky described a condition in which elongated endometrial glands were embedded in the hyperplastic endometrial layer. The author mentioned two variants of this condition: the first, in which the glands developed in the muscular wall of the uterus and the second, in which the glands extended to the intrauterine cavity, forming polyps [10]. Several researchers in the 1880s and 1890s considered adenomyosis to be either an embryonic error in the distribution of Müller's ducts or the penetration of the hyperplastic basal endometrium into the myometrium [10–14]. Von Recklinghausen, then argued that adenomyosis is the result of displacement of the mesonephric elements. The researcher reported that these ectopic glands are more commonly found in the posterior wall of the uterus and the area of the cornea, and that these areas consist of remnants of Wolff's pores rather than Müller's ducts [10–14]. Marcus, later described the lymphatic transmission of endometrial elements [14]. Although, this theory has been used to interpret pelvic endometriosis, it also provides a possible explanation for adenomyosis. Marcus, then suggested that there are some miller pluripotent cells in the myometrium, which can differentiate into endometrial cells, offering another possible interpretation for the development of adenomyosis [14]. The cycle is now complete, and most researchers believe that adenomyosis is caused by the penetration of the basic endometrium into the hyperplastic layer of the myometrium. It should be noted that all the organs of the human body, which show cavities, present a sub-orogenic area, except for the uterus. It is believed that the main function of the sub-orogenic region is to inhibit the growth of the glands that line these cavities. The term "uterine adenomyosis" was first used by Frankl in 1925. In 1972 Bird and his colleagues defined adenomyosis as "benign, penetration of the endometrium into the myometrium, which causes diffuse enlargement of the uterus and microscopically presents ectopic, non-neoplastic, endometrial glands and layer, surrounded by hypertrophic and hyperplastic endometrium" [15]. This definition still applies today.

However, it has been described by some researchers as "the presence of endometrial glands and a layer, which are diffuse and deep inside the myometrium". The issue of depth is important as the normal endometrial contribution is usually irregular. Thus, adenomyosis must be distinguished from cases in which there is minimal adhesion of the basal layer of the endometrium surrounded by myometrium and there are two ways to treat it. The first case is the detection of myometrial hypertrophy ("collar around the foci of adenomyosis"), because this type of change is not observed in the intramuscular junction. The second way is to measure the distance between the endomyometrial junction and the nearest adenomyotic site, the size of which must correspond to at least 25% of the total thickness of the myometrium. The second approach is particularly useful in the postmenopausal and pregnant uterus, as in these cases there is generally no muscle hypertrophy around the foci of adenomyosis. Although, many researchers consider adenomyosis as a variety of endometriosis and call it internal endometriosis, adenomyosis should be defined as the presence of endometrial glands and mattresses, located outside the myometrium [10–18].

#### **1.3 Epidemiology**

The incidence of adenomyosis varies widely, with rates ranging from 5.7% to 69.6% [19, 20]. Although, some of this discrepancy can be explained by the different histological definitions of adenomyosis, the difference is mainly due to the interest of pathological volumes in making the diagnosis. As a result of the local entity of the condition, the diagnosis of adenomyosis is particularly difficult. In the excellent prospective study by Bird et al. [15], 200 consecutive hysterectomy

specimens were examined histologically. When three sections of the myometrium were examined, adenomyosis was found in 62 women (31%). When six more incisions were made, three from the anterior and three from the posterior wall of the uterus, another 61 cases of adenomyosis were diagnosed, increasing the rate from 31 to 61.5% [21–25].

The main reason for the difficulty in determining the true incidence of adenomyosis is mainly due to the fact that published studies report the number of adenomyosis cases, but without mentioning the total number of hysterectomies per age group, so the relative impact of adenomyosis with age has not been defined. Another problem is determining the true frequency is also the fact that in the various studies, only women who undergo a hysterectomy are evaluated, and a selection of cases is applied. Ιn two necropsy studies, the incidence of adenomyosis was reported between 50 and 53.7% [21–25]. Although, these studies had a different choice of cases (excluding women who underwent hysterectomy), they show that the true incidence of adenomyosis is at the highest end of the published frequency range. The woman's interest appears to be related to adenomyosis, as 93% of the women treated had children [21–25]. Although, the numbers tend to mimic the general population, their importance is questionable. If these numbers are real, the observation will confirm an interesting paradox, that is, the number of pregnancies protects against endometriosis, but it is a risk factor for the development of adenomyosis. There does not appear to be a significant association between adenomyosis and another gynecological entity. In a retrospective study of 134 women who underwent a hysterectomy, Vercillini and colleagues found a similar coexistence of adenomyosis with fibroids (23%), with uterine prolapse (19%), with endometrial cancer (28%), with ovarian cancer (28%) and with ovarian cysts (21%) [26].

#### **1.4 Pathogenesis**

Although, the exact etiological factors of endometriosis have not been clarified yet, there are many theories on this subject, such as the ones proposed by Ridley [27]. According to the most popular view, adenomyosis is the result of the attachment of the basal layer of the endometrium to the myometrium. In non-uterine areas, the predominant theory concerning the pathogenesis of adenomyosis is the de novo development of ectopic fetal residues of Müller's ducts, since an invasive mechanism of the endometrium into the myometrium has not been established. There are significant differences in the cellular level between the basal layer of the endometrium and the functional layer, such as increased DNA synthesis in the nucleus, and margin formation in the functional layer. In general, the functional layer is considered to be the site of blastocyst implantation while the basal layer provides the possibility of intrauterine regeneration after menstruation. During the period of regeneration of the endometrium, cells from the basal layer glands are in close contact with the endothelial cells having intracellular microfiber/tubular and squamous cell systems [28–30].

These findings support the location of possible migration through amoebic contraction-extension. Such morphological changes have not yet been described in the intrauterine epithelium of adenomyosis. However, in vitro studies have shown that endometrial cells have the penetrating capacity and that their penetration rate is similar to that of cell lines from metastatic bladder carcinoma. This penetrating ability can facilitate the expansion of the basal layer of the endometrium to the myometrium. In MCF-7 cells from breast cancer, tenascin production is stimulated by epidermal growth factors (EGF), which are regulated by hormones. The fact that fibroblasts of the endometrial layer produce tenascine, a fibronectin inhibitor that in turn facilitates the migration of epithelial cells, suggests that there is a complex

#### *Uterine Embolization as a New Treatment Option in Adenomyosis Uteri DOI: http://dx.doi.org/10.5772/intechopen.101480*

physicochemical relationship during the growth process of the endometrium in the production phase. Tenascin has been immunohistochemically located around the endometrial glands during the productive phase of the cycle, but not in this position after ovulation [28–30]. Tenascin may mediate the interactions between epithelial and mesenchymal cells, where it inhibits cell adhesion to fibronectin in the endometrial adenomyotic type in the same way as in the normal endometrium.

In a study within situ hybridization and immunohistochemistry, it was found that the endometrial glands in adenomyosis selectively express more human chorionic gonadotropin (hCG) receptor mRNA and immunoreactive receptor protein, compared to the present [31–34]. It seems that ΗCG/LH receptor expression levels do not differ at different sites of the normal endometrium, but increased expression of this receptor may give epithelial cells the ability to invade the myometrium and form adenomyotic islets. Furthermore, quite interesting is the fact that there is an increased expression of hCG/LH receptors in endometrial carcinomas as well as in non-invasive choriocarcinoma trophoblast cells [31–34]. Studies on steroid hormone receptors in adenomyosis foci have shown dubious results. Thus, some studies reported the absence of progesterone receptors in 40% of adenomyosis cases, while others showed higher concentrations of progesterone receptors than estrogens. Relatively high concentrations of estrogen and progesterone receptors were found in both the basal and adenomyotic endometrium using immunohistochemical detection techniques. Estrogen receptors are a prerequisite for the development of the uterus, which is caused by estrogen [35–38]. Although, there is no clear evidence of a disturbed hormonal environment in most women with adenomyosis, hyperestrogenemia may play a role in the process of endometrial infiltration, as women with adenomyosis have a high rate of endometrial hyperplasia. According to some researchers, a relatively high concentration of estrogen is necessary for the development of both endometriosis and adenomyosis [31–38]. The clinical observation that the destruction of the estrogenic environment with danatrol causes regression of the ectopic endometrium and remission of the associated symptoms of menorrhagia and dysmenorrhea reinforces this hypothesis [31–38]. As in uterine fibroids, estrogen is synthesized and secreted in adenomyotic tissues [31–38]. It was found, therefore, that there is aromatase activity of estrogen sulfatase in the upper part of the myometrium, which contained foci of adenomyosis, by the method of steroid biochemical analysis. The activity of estrogen sulfatase and, in particular, aromatase was higher than that observed in normal adjacent endometrium, leiomyomas and suprauterine endometrium. In addition, endometrial aromatase enzyme activity was inhibited in vitro by up to 50% with the addition of 106 M of danatrol [31–38]. Finally, the presence of aromatase was confirmed in foci of adenomyosis from human matrices by immunohistochemical method and, in particular, in the cytoplasm of glandular epithelial cells, but not in the cytoplasm of stratum cells. The production of estrogen by adenomyotic tissue is further enhanced by the finding of a large number of women with adenomyosis and a high concentration of estradiol (30 pg/ml) in menstrual material compared to those without adenomyosis and normal menstrual cycles [31–38].

Adenomyotic tissue appears to respond well to progesterone with secretory differentiation. Progestogens also enhance aromatase activity in both eutopic endometrium and adenomyotic tissues, thus contributing to the biosynthesis of estrogen in adenomyotic foci.

It is possible, however, that the bioavailability of race steroids alone is not sufficient to develop adenomyosis. It is possible that the myometrium, in cases of adenomyosis, is either predisposed to penetrate the main endometrium, so that benign "penetration" of the endometrium occurs secondarily due to "weak" myometrium, or the morbidity of the uterine scraping, fibromyectomy and cesarean section. Thus,

adenomyosis was induced in pregnant rabbits, after scraping one horn of the uterus and fallopian tube, while maintaining the pregnancy in the opposite horn [31–38]. Penetration into the myometrium of the basal layer of the endometrium is enhanced, possibly, by increased intrauterine pressure, which, according to Cullen, can be caused by high circulating progesterone concentrations. The immunohistochemical method has been observed, increased expression of class II antigens of the major histocompatibility complex (HLA-DR) in the glandular cells of the idiopathic endometrium, endometriosis and adenomyosis [31–38]. In addition, the number of macrophages in the myometrium of women with adenomyosis appears to be increased. These macrophages can activate helper T- and B-cells to produce antibodies [31–38]. Phospholipid autoantibodies and significant deposition of immunoglobulins (lgs) or complement factors have been found in women with endometriosis or adenomyosis [31–38]. The exact importance of these immune aberrations in adenomyosis or endometriosis is not currently understood. In vitro experiments have shown that activated CD3+ T cells in the uterus and their secretory product, interferon γ, promote the expression of HLA-DR immunoreactivity in endometrial glandular cells and inhibit their proliferation [31–38]. The closer the endometrial cells are to the activated T cells, the greater the inhibition of their growth. It appears that lymphocyte-like formations, located mainly at the endomyometrial junction, are rich in activated T cells. Their appearance coincides with the maximum suppression of endometrial growth, which is observed both morphologically and with proliferation indices [31–38]. On the contrary, the proliferation of the endometrium is observed, to the greatest extent, near the surface of the endometrium, that is, far enough away from the basal layer, in which these lymphoid formations are found [31–38].

### **1.5 Pathological anatomy**

During a hysterectomy, the adenomyotic uterus is usually spherical or soft. It is swollen in 60% of cases, but rarely exceeds the size of a 12-week pregnant uterus [39]. The uterus weighs from 80 to 200 g. In his classic study, in which a woman's interest determined the weight of the uterus, Langlois reported the upper limit of the normal uterus weight at 130 g for the unmarried woman, at 210 g for the firstborn to the third child, and at 250 g for women with four or more children [40]. With these criteria, excluding cases of fibroids, the weight of the uterus does not increase significantly with adenomyosis. Uterines with adenomyosis are usually hyperemic with thick walls. Although, many researchers have reported that adenomyosis is more common in the posterior wall of the uterus than in the anterior. Bird and colleagues found that the foci of adenomyosis were evenly distributed when receiving six additional incisions for histopathology [15]. These foci may be diffusely dispersed in the myometrium, and may sometimes be large and localized, forming structures called adenomas. The characteristic macroscopic appearance of adenomyosis is due to hypertrophy of the myometrium, which surrounds the endometrium [40–44]. When the entire myometrium, or one of the layers of the uterine wall, is diffusely affected, the uterus increases in size and takes on a spherical shape. During the cross-section of the uterus, the hypertrophic muscular beams are visible, which develop in all directions and surround the foci of adenomyosis. The latter, in some cases, may contain "old" blood with a brown appearance, corresponding to hemolyzed blood and hemosiderin deposits [40–44].

Local infection of the uterus by adenomyosis resembles fibroid. The term adenomyoma is used for the frequent occurrence of adenomyosis. Because the treatment is not neoplastic, the term focal adenomyosis is preferred by Hendrickson and Kempson [40–44]. As adenomyoma is often confused clinically with leiomyoma, which is a benign but neoplastic condition, the term adenoma is accepted. Typically

#### *Uterine Embolization as a New Treatment Option in Adenomyosis Uteri DOI: http://dx.doi.org/10.5772/intechopen.101480*

the adenoma does not have clearly defined boundaries because they merge with the normal myometrial environment. In contrast, leiomyomas compress the myometrial environment and have well-defined boundaries [45–50].

Leiomyoma can be nucleated, while adenomyoma can not. Histologically, by the immunohistochemical method, the endometrial glands and the layer in foci of adenomyosis resemble the basal layer of the endometrium. Rarely do they respond to hormonal stimuli, a phenomenon that explains, at least in part, that only in certain cases are hemorrhagic or regenerative morphological findings observed in foci of adenomyosis. The reason for the increased tendency of focal bleeding in deep-seated adenomyotic foci is not understood [45–50]. In contrast, the ectopic endometrium at foci of endometriosis often undergoes circular changes, including degeneration, bleeding, and regeneration, which are similar to those seen in the functional layer of the endometrium. The different frequency of menstrual-type changes may be due to the relatively poor vascularity of the ectopic endometrium, which is a type of primary endometrium, compared to the endometriosis of the endometrium, which is rich in perspiration and is a type of functional layer of the endometrium. However, it appears to retain the ability to proliferate as a result it can develop and be responsible for the failure of amenorrhea or submenorrhea after endometrial destruction operations [45–50]. The secretory changes, which include the degradation of the layer in foci of adenomyosis, are observed mainly during pregnancy and treatment with exogenous progestogens and these changes are made through estrogen and progesterone receptors.

Progesterone effect in the non-pregnant uterus is observed in approximately 30–50% of foci of adenomyosis. During intrauterine pregnancy, 57% of the studies evaluated by Azziz found degeneration [39]. Other authors observed degeneration during pregnancy, only in deep foci, at a depth of at least two low-magnification optical fields, while degeneration was absent or insignificant in foci less than two low-magnification optical fields, the boundary of the basal layer of the endometriummyometrium [45–52]. It is worth to be mentioned that adenomyosis can often be complicated by hyperplastic disorders up to atypia, while squamous cell carcinoma, mucosal metaplasia, and adenocarcinoma can occur in parallel with adenomyosis.

When the carcinoma is confined to an adenomyotic lesion, it should be considered "intravenous" as the prognosis is no worse than the carcinoma for which the patient underwent surgery. It is not possible to determine histologically whether the adenocarcinomas found in the supracervical uterus in foci of adenomyosis are the primary foci or the expansion of the endometrium into the foci of adenomyotic foci [45–52].

### **1.6 Clinical symptoms**

Approximately 35% of adenomyosis cases are symptomatic [53–56]. In other cases, the most common symptoms are menorrhagia (50%), dysmenorrhea (30%) and uterine bleeding (20%). In some cases, discomfort may be an additional symptom. The frequency and severity of symptoms depend on the extent and depth of adenomyosis [53–56].

The exact cause of menorrhagia in patients with adenomyosis is not known. Menorrhagia may be due to poor contractility of the adenomyotic myometrium and compression of the endometrium by submucosal adenomas or leiomyomas. Mefenamic acid may reduce blood loss, suggesting that prostaglandin F2a (PGF2a) may play a role in the greater blood loss in women with adenomyosis [53–57]. Other factors may include anovulation, hyperplasia and, rarely, endometrial adenocarcinoma. Dysmenorrhea, finally, is due to the irritability of the uterus, which in turn is secondary to the increased amount of blood loss [58–60]. The symptoms associated with adenomyosis have not been analyzed by all researchers. For example, in

a study of 136 patients with histologically confirmed adenomyosis, the symptoms were varied, non-specific and, according to the researchers, associated with coexisting pathological conditions such as leiomyomas, endometriosis and polyps, rather than with adenomyosis [58–60]. In another prospective study, there were no differences in the incidence or severity of dysmenorrhea and pelvic pain between 28 women with adenomyosis and 157 controls [58–62]. A study of 23 women with myometrial adenomyosis reported no qualitative differences in spontaneous motility of isolated myometrial tissue during the menstrual cycle, compared with normal uterine fibroids [58–62]. The type of mobility was low-intensity and high-frequency automatic contractions during the reproductive phase, both of which increased during the secretory phase. Histamine-induced contractions of the myometrium were similar to all myometrial tissues tested [58–62].

Because the symptoms of adenomyosis are not specific, it is natural for the disease to be rarely diagnosed preoperatively. Most researchers report a correct preoperative diagnosis in less than 10% of cases [58–62]. However, due to the way the cases are selected, the incomplete pathological examination of the surgical specimens, and the limited number of well-designed studies, the true ability to diagnose adenomyosis is difficult to assess.

#### **1.7 Diagnosis**

The clinical diagnosis of adenomyosis is, at best, hypothetical (50%) and more often, it either does not occur (75%) [63–66] or the disease is overdiagnosed (35%) [63–66]. Menorrhagia and dysmenorrhea in a large woman, aged 40–50 years, raise the suspicion, but not the diagnosis, of adenomyosis. The uterus may be diffusely swollen, about the size of a 12-week pregnant uterus, and soft and tender to the touch. In addition, the presence of endometrial hyperplasia at the time of hysterectomy is the only variable directly related to adenomyosis [63–66].

Several researchers have used radiological methods to diagnose adenomyosis. In the largest hysterosalpingography study, Marshak and Eliasoph diagnosed adenomyosis in only 38 of 150 patients with proven adenomyosis [67]. However, they did not report either the total number of patients examined or the frequency of a false-positive diagnosis. The most common findings in hysterosalpingography are endometrial diversions and cellular invasions within the myometrium [67].

This test was considered inaccurate because myometrial adhesions attributed to adenomyosis resemble lymphatic or vascular infiltrations of the pigment. Intraabdominal ultrasound is not useful in diagnosing adenomyosis. In the late 1970s, a group suggested that abnormal ultrasound areas of the myometrium, 5–7 mm in size, were an ultrasound finding characteristic of generalized adenomyosis [63–66].

This view was subsequently challenged by Siedler et al., who reported generalized uterine enlargement, normal uterine echogenicity, and retention of uterine shape in the majority of women with established adenomyosis. Subsequent studies have failed to clarify this issue [68].

Vaginal ultrasound has been used to diagnose adenomyosis since the early 1990s. Fedele estimated 43 women who would undergo hysterectomy for menorrhagia with preoperative transvaginal ultrasound. He described numerous small subsonic areas of the myometrium, with an abnormal ultrasound outline in 22 women [69].

The sensitivity of the method was estimated at 80% and specialization at 74%. Other researchers reported lower sensitivity, at 48 and 53% [70–80]. Other studies, with a larger number of women, are needed to address this issue [81–85].

Magnetic resonance imaging (MRI) has been applied to pelvic pathology and the initial results in women with adenomyosis are encouraging [75–84]. Mark and his colleagues predicted adenomyosis in eight of 20 women studied with T2 images. Ten

#### *Uterine Embolization as a New Treatment Option in Adenomyosis Uteri DOI: http://dx.doi.org/10.5772/intechopen.101480*

of the remaining 12 women were correctly diagnosed with adenomyosis free, while in two the diagnosis was uncertain [70].

The researchers described a typical, wide, low-density area surrounding the normal, high-density, endometrium in women with diffuse adenomyosis. Tiny foci of adenomyosis could not be diagnosed. T2 imaging has a significant advantage over shadowless imaging and that with T1 amplification. MRI has been used to differentially diagnose adenomyosis from leiomyomas [75–85].

Ninety-three patients were evaluated preoperatively and the results were related to surgical pathology. The 16 cases of adenomyosis were diagnosed preoperatively. The wider application of new technology needs, however, further evaluation. In addition, the cost can prevent MRI from becoming a widely used diagnostic test [75–85].

CA-125 is an antigen produced by the ovarian epithelial cells. It is secreted from these cells into the blood and is determined in a variety of gynecological diseases. Some researchers have used the determination of CA-125 levels to predict recurrences of non-mucosal ovarian cancers, while others have used it to diagnose recurrences of endometriosis. In the second case, successive determinations of CA-125 levels [75–85].

was required. In 1985, Takahashi and colleagues reported high preoperative CA-125 levels in six out of seven women with adenomyosis [70]. Although, CA-125 levels were elevated in these women, they were significantly lower than in patients with ovarian cancer. One month after hysterectomy, all women showed normal CA-125 levels. The same researchers, by immunohistochemical method, observed CA-125 production in the glandular epithelium of adenomyosis foci in eight hysterectomy specimens [75–88]. In another study, it was not possible to reproduce these results. In the report of 22 women, 11 of whom had adenomyosis, Halila and colleagues found normal preoperative CA-125 levels in all women with adenomyosis [71, 72]. These levels did not change significantly at one and five weeks after surgery. The cause of the different results in these studies was not clear, but it is hoped that future research will lead to some conclusions [71, 72].

Cysteine and leucine aminopeptidase levels have been used as possible markers of adenomyosis. Levels of these enzymes are elevated in various benign and malignant conditions of the uterus and ovaries [75–88].

However, no control studies have been performed to evaluate the clinical utility of these measurements. Although, adenomyosis can be diagnosed after a needle biopsy of the uterus, the sensitivity of this method is low and depends on the number of biopsies and the depth of penetration of the adenomyosis. This technique is of little or no importance in the diagnosis of minimal or moderate disease, but can provide histological confirmation in cases with extensive myometrial infiltration. If the biopsy confirms the diagnosis, women should be identified based on their history and tested for transvaginal ultrasound and MRI. These diagnostic methods can also help determine the location of the biopsy. However, myometrial biopsy, as a routine method, in women with pelvic pain should not be performed [75–88].

#### **1.8 Treatment**

Hysterectomy surgery remains the key approach in both the diagnosis and treatment of adenomyosis until a safer and more effective method of immediate biopsy is found. The only way to accurately diagnose adenomyosis is to remove the uterus, which also provides treatment for this condition, whereas prolactin, progesterone and growth hormone appear to accelerate the development of the disease [89–94].

RU 486, an anti-progesterone agent that inhibits the action of progesterone on its receptors in the uterus, suppresses the development of adenomyosis if administered for 30 days. Of course, they also require studies in humans [89–94]. There is

evidence that progesterone promotes the development of adenomyosis in humans as well as in muscles [89–94]. Danazol, an antigonadotropic derivative of testosterone 17α-ethinyl, has not been widely used in the treatment of adenomyosis [88].

From June 1993 to August 2000, Tamaoaka et al. treated adenomyosis women with endometrial glomeruli containing danatrol, and observed a marked reduction in dysmenorrhea and levels of CA-125 in women with endometrial hyperplasia. The histopathological findings of hyperplasia disappeared during the use of these endometrial glomeruli. The mechanism of the direct action of danatrol in endometrial hyperplasia has not been fully elucidated [89–94].

Hormone therapy with progestogens or gonadotropin-releasing hypothalamic hormone analogs (GnRH-α) could be as effective as in endometriosis [94–96]. However, an increase in uterine size and a recurrence of symptoms occur within six months of stopping treatment. Conservative surgical treatment may be helpful in some patients, although follow-up of women after such surgery is limited to three years [96–98].

The activity of one orally administered metalloproteinase inhibitor (ONO-4817) in the development of adenomyosis was recently tested experimentally by anterior pituitary gland transplantation into muscle. The results indicate that this drug could be activated the development of adenomyosis [96–98].

## **2. Uterine artery embolization**

The uterine artery embolization (UAE) has been used successfully for refractory gynecologic problems in premenopausal women like: hemorrhage, pain, bulk symptoms, or a combination of them despite previously performed surgical procedures (myomectomy, adenomectomy) or medical treatment. The desire for minimally invasive alternatives for the management of symptomatic adenomyosis premenopausal women prompts interventional radiologists to propose UAE as an alternative treatment to surgical treatment of adenomyosis. According to various reports, the ability to improve menstrual disorders and symptoms of premenopausal women through UAE without the need for surgical procedures led to this method becoming famous. However, despite the positive comments of several reports exist no prospective randomized trials to determine the relative safety effectiveness of UAE compared either to surgical or medical options [78–84]. The cooperation between a gynecologist and interventional radiologist is obligatory to establish optimal clinical guidelines for premenopausal women care due to preinterventional consultation, procedural course and postprocedural follow up require gynecological and also radiological services.

#### **2.1 UAE technical procedure**

The target of the UAE is to administrate material polyvinyl alcohol (PVA). Microspheres or gelatin-coated tris-acryl polymer microspheres bilateral in uterine arteries to interrupt or reduce the blood supply at the level of the arterioles and to produce irretrievable ischemic damage, degeneration and shrinkage of adenomyosis focus without causing permanent damage to uterus. The target of UAE is an interruption or reduction of the blood supply of fibroids at the level of the arterioles after bilateral (from left and right) super-selective catheterization with microcatheters of the arteries that supply the fibroids and injection of acryl polymer embolospheres with a diameter of 500–900 μm for provocation of irretrievable ischemic damage to the fibroids. The aspects of the technical approach of UAE are summarized and described as follows: A single right femoral artery is typically catheterized after intravenous local analgesia and after that is performed pelvic arteriography to

#### *Uterine Embolization as a New Treatment Option in Adenomyosis Uteri DOI: http://dx.doi.org/10.5772/intechopen.101480*

define the vascular tree and identifiy both uterine arteries. All UAE procedures were carried out in the angio suite with a digital subtraction angiography (DSA) system. Except this is of great importance to exclude present vascular abnormalities. The goal of UAE is partial or complete occlusion of both uterine arteries branches which led to adenomyosis focus with polyvinyl alcohol (PVA). Microspheres or gelatin-coated tris-acryl polymer microspheres and after the embolization of the above-mentioned vessels may produce effective infraction of adenomyosis focus associated due to moderate or severe pain. It is very important to sparing of cervical and vaginal branches, vasoconstriction avoidance, catheter 4-F retraction in the internal iliac artery, after the microcatheter placement.

Caution for anatomic variances:

atypical origin of uterine arteries, ovarian/uterine tube arteries deriving from uterine arteries, multiple arteries branching instead of one artery, absence of uterine arteries, origin from ovarian arteries or round ligament arteries, avoidance of embolization of the ascending branches to the ovary and descending branches to the cervix and the vagina.

After the selective catheterization of the uterine artery visualization with contras, if major ovary branch is visualized micro catheter is moved superelectively inside the ovary branch and the embolization of the supply to the ovary is done first with microspheres or big embolospheres with a diameter 900 μm. Technical difficulties include severe cannulating of arteries due to anatomic variations, arterial spasm, recently use of gonadotropin releasing hormone agonist, uterine perfusion from collateral ovarian vasculature. During the procedure, analgesic treatment (paracetamol and morphine) is administered wherever it is necessary.
