versão On-line ISSN 1027-202X
S. Afr. J. radiol. (Online) vol.18 no.1 Cape Town Out. 2014
Joel H. Bortz
LSG Imaging, Los Angeles, United States of America
A 68-year-old obese man underwent computed tomographic colonography (CTC) scanning to investigate worsening constipation and lower abdominal discomfort on his left side. Optical colonoscopy was contraindicated because of his comorbidities. A preliminary CTC diagnosis of incarcerated Spigelian hernia was made, based on lateral deviation of the sigmoid colon to the left as well as extrinsic impressions on it, and the central location of the small bowel. Spigelian hernia is a rare form of anterior abdominal wall hernia. CTC can play a role in its diagnosis.
Computed tomography (CT) has been shown to produce the most accurate imaging in the diagnosis of Spigelian hernia. In this case report, CT colonography (CTC) demonstrated additional findings, making the diagnosis more readily achievable.
A 68-year-old obese man was referred for CTC scanning by a gastroenterologist. His primary clinical history was worsening constipation and lower abdominal discomfort on his left side. Optical colonoscopy was contraindicated because of his comorbidities of hypertension, ischaemic heart disease, diabetes and chronic obstructive airways disease. A low-dose CTC technique, CO2 insufflation and a 16-slice General Electric multidetector CT (MDCT) scanner were used for the study. As the patient was obese, a standard two-view supine and prone study could not be performed; therefore right and left decubitus views were done instead. Filling the colon with three litres of CO2 took approximately seven minutes, compared with the average time of three minutes. The CTC study showed an incarcerated Spigelian hernia (SH), without evidence of obstruction. The colon map views showed three important findings: (1) the sigmoid colon was markedly displaced to the left; (2) the small bowel was in a central position (Figure 1a); and (3) in addition, the air-contrast colon map demonstrated two external impressions on the sigmoid colon at the point where it enters and exits the muscular defect (Figure 1b). Slight narrowing of both the afferent and efferent loops of the sigmoid was noted on 3D fly-through imaging (Figure 2).
A 2D image below the umbilicus confirmed a defect through both the internal oblique and the transversus muscles. The sigmoid colon was contained in a hernia. An axial view demonstrated a thin rim of the external oblique muscle laterally, indicating an interstitial or interparietal geographic location of the hernia (Figure 3). Coronal and sagittal 2D images clearly demonstrated the SH (Figure 4 and Figure 5).
In view of the patient's comorbidities, surgical intervention was not an option at this stage. He was fully briefed by the gastroenterologist in this regard and made aware of the risk of obstruction or strangulation. He was informed that, should this occur, surgical intervention would be required.
Spigelian hernia is also known as spontaneous anterior abdominal hernia. It is a rare acquired hernia occurring in less than 2% of all abdominal hernias, with just over 1000 reported cases in the literature.1Congenital cases of SH have been reported in children.2SH is often undetected clinically as the symptoms and physical findings are subtle or inconclusive, particularly in obese adult patients. SH is prone to complications, such as incarceration, small or large bowel obstruction and strangulation, because the hernia defect is usually narrow (2 cm - 3 cm).1-3
Diagnosis is, however, primarily made by CT.1, 4, 5 In the present case report, a CTC was performed for investigation of abdominal discomfort and worsening constipation. A diagnosis of SH was made based on the lateral deviation of the sigmoid colon as well as the two extrinsic defects on its wall (Figure 1a and Figure 1b). The diagnosis was confirmed by the 2D study which showed an interparietal SH containing sigmoid colon and a clear hernial defect in both the internal oblique and transversus muscles (Figure 4 and Figure 5). CTC is a minimally invasive, fast, safe and accurate screening examination for colorectal cancer. It is also suitable as a diagnostic study for patients with gastrointestinal symptoms. Furthermore, it allows evaluation of extracolonic structures in the abdomen and pelvis.
Ultrasound is often the first line of imaging used to investigate SH.1, 2, 5Although operator dependent, it can be used to make a diagnosis of SH in a large proportion of patients. In addition, a Valsalva manoeuvre can be used in supine and erect sonography to determine the presence of SH.3
There is a slightly higher incidence of SH in women than in men; in adults, it usually occurs during the fourth and seventh decades.1, 2, 6It may occur on either side of the body, or occasionally bilaterally.1There are several known predisposing factors: obesity, chronic obstructive airways disease, previous surgery or laparoscopy, peritoneal dialysis, multiple pregnancies, and rapid weight loss, for example.2, 6, 7
Clinical presentation varies, depending on the content of the hernial sac. In obese individuals, detection of SH may be particularly difficult as the hernia may not be palpable on clinical examination. Some patients may complain of pain, but no lump is palpable.6Omentum and/or segments of the small bowel or colon are usually present in the sac. In the present case, the colon map showed small bowel in a central location; it was not included in the hernia sac (Figure 1a). Other structures, such as the stomach, Meckel's diverticulum, the appendix, and testicular and endometrial tissue, have been found in SH.2, 8
It is important to know the anatomy of the abdominal musculature when diagnosing SH. There are three flat and two vertical muscles of the anterior abdominal wall (Figure 6a and Figure 6b). The flat group consists of the external and internal oblique muscles and the transversus abdominis muscles. The vertical group comprises the rectus abdominis and pyramidalis.
The external oblique muscle arises from the lower eight ribs; it is the largest and most superficial muscle of the antero-lateral abdominal wall. The muscle fibres pass infero-medially. The aponeurosis of the upper part of the muscle splits to cover the anterior and posterior portions of the rectus abdominis. Inferiorly, the superior margin of the external oblique aponeurosis thickens and folds back on it to form the inguinal ligament.9
The internal oblique is the middle of the flat muscle group. It is a thin muscular sheet that fans out antero-medially. Its fibres become aponeurotic and split to envelop the anterior and posterior margins of the rectus in its upper two-thirds of the abdomen. In the lower third, the aponeurosis does not split; it passes as a whole in front of the rectus to reach the linear alba (Figure 6a).9
The transversus abdominis muscle is the innermost of the three flat muscles, with a transversomedial orientation. Superior to the arcuate line, the aponeurosis of the tranversus abdominis muscle splits to form part of both the anterior and posterior rectus sheath. Inferiorly to the arcuate line, the aponeurosis of the transversus abdominis muscle passes anteriorly to form part of the anterior rectus sheath layer. This arrangement allows for a potential area of weakness posteriorly.
The rectus abdominis is a vertical muscle that is wrapped anteriorly and posteriorly by the aponeurosis of the three flat muscles. The lower third has no posterior cover. The pyramidalis is absent in approximately 25% of individuals. It is a small, insignificant muscle situated in relation to the inferior margin of the rectus.
The Spigelian (semilunar) line represents the vertical fibrous band formed by the union of the rectus sheath with the fascia of the three flat muscles of the anterior abdominal wall. In the upper two-thirds of the abdomen, the aponeurosis splits at the lateral margin of the rectus into a posterior layer, which passes behind the rectus muscle, and an anterior layer which passes in front of the rectus. The level at which this occurs is known as the arcuate line (Figure 6a), the semicircular line or the line of Douglas. The deep layer of the abdominal wall is only weakly reinforced by separated fascial bands. The Spigelian aponeurosis is the portion of the transversus abdominis that is bordered by the semilunar (Spigelian) line laterally and the lateral borders of the rectus muscle medially (Figure 6a). SH protrudes through this aponeurosis; most are found in a transverse band lying between 0 cm and 6 cm cranially to a line running between both the anterior and superior iliac spines.8This band is referred to as the 'Spigelian hernia belt' where the Spigelian fascia is widest (Figure 6a).6
A diagnosis of SH, based on plain-film radiographs, upper and lower gastrointestinal studies, and follow-through studies, is not readily made in the absence of an intestinal obstruction.7There has been reported use of magnetic resonance imaging (MRI) for investigation of SH.10CT, however, is the main imaging modality. As is evident in the present case report, CTC can play an important part in the diagnosis of SH. The main advantage of CTC is that the entire large bowel and all extracolonic components can be visualised. The complementary role of 2D and 3D imaging in the diagnosis of SH is well demonstrated in this case report.
Clinton Bopp is thanked for drawing the line diagram of the abdominal musculature.
The author declares that he had no financial or personal relationship(s) that might have inappropriately influenced him in writing this report.
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Apartment 141, Playa Vista
United States of America
Received: 19 June 2014
Accepted: 27 July 2014
Published: 04 Dec. 2014