Ultrasound assessment of acute appendicitis in paediatric patients: methodology and pictorial overview of findings seen
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Acute appendicitis is a common surgical emergency in the paediatric population. Computed tomography (CT) has been shown to have high accuracy and low operator dependence in the diagnosis of appendicitis. However, with increased concerns regarding CT usage in children, ultrasound (US) is the imaging modality of choice in patients where appendicitis is suspected. This review describes and illustrates the step-wise graded-compression technique for the visualisation of the appendix, the normal and pathological appearances of the appendix, as well as the imaging characteristics of the common differentials.
• A step-wise technique improves the chances of visualisation of the appendix.
• There are often several causes for the non-visualisation of the appendix in children.
• A pathological appendix has characteristic US signs, with several secondary features also identified.
• There are multiple common differentials to consider in the paediatric patient.
KeywordsPaediatric Ultrasonography Appendix Appendicitis Ileitis
In the paediatric population, acute appendicitis is a common condition that requires emergency abdominal surgery [1, 2]. It usually occurs in older children (ages 10–20) and is rare in children less than 2 years, but can occur at any age . As the incidence of acute abdominal pain is common in children, differentiating acute appendicitis from non-surgical self-limiting illnesses is important.
Ultrasound (US) is often the diagnostic modality of choice in the diagnosis of appendicitis [4, 5, 6]. It lacks ionising radiation, allows dynamic visualisation of the abdominal organs and is of lower cost compared with computed tomography (CT). Many studies indicate a high sensitivity and specificity for US in the diagnosis of appendicitis. An 85–100 % sensitivity and 89–98 % specificity for US accuracy in appendicitis diagnosis have been documented [5, 7, 8, 9, 10, 11, 12]. These studies tend to be reported by radiologists skilled in performing/interpreting paediatric sonography. However, some studies show lower rates due to the user-dependent nature of US [13, 14].
CT, on the other hand, has been shown to have a consistently high sensitivity and specificity in the diagnosis of appendicitis with reduced operator dependence [15, 16]. However, there is an increasing trend away from CT in the paediatric population because of the risk of radiation-induced cancer. Several risk models and studies have predicted higher risks for cancer in children exposed to CT compared with adults [17, 18, 19].
It is therefore important to know how to perform an adequate study using graded compression US, a well-established technique that maximises the chance of identifying the appendix .
Clinical features of appendicitis include right lower quadrant pain, pain migration, nausea or vomiting, anorexia, rebound tenderness, pyrexia and elevated white cell count . However, not all children with appendicitis present with such classical symptoms and this can prolong the diagnosis . Any delay in the surgical management can lead to complications as appendicitis usually does not resolve spontaneously . Potential complications include perforation, peritonitis, abscess formation and death. Because of atypical presentations and the risk of potential complications, imaging is often requested. In children, this imaging technique is usually US.
US allows the radiologist to clinically assess the patient, asking the child where they are sore, as well as other symptoms that have occurred. It is the imaging method of choice in the evaluation of suspected acute appendicitis due to the lack of non-ionising radiation and dynamic ability. A graded-compression US technique is performed using a high-resolution linear transducer. Graded-compression is the application of pressure through the transducer in order to displace and compress underlying bowel loops, thus allowing the visualisation of the appendix. A competent study should include the visualisation of the psoas muscle and iliac vessels.
Setting the scene: contact with the patient and parents
When meeting the paediatric patient for the first time, the patient should be asked where the point of maximum tenderness is located. The examination is explained to the patient. The patient is usually accompanied by a parent or guardian. In optimal conditions, the patient is fasted and has a full bladder to help in the exclusion of any ovarian or other pelvic pathology.
General abdominal US
US examinations of the liver, biliary tree, pancreas, both kidneys and spleen are performed with a 3.5–6 MHz curvilinear probe prior to graded US of the right iliac fossa and pelvis. This allows exclusion of any other possible cause for the acute abdominal pain. Free fluid is also looked for throughout the abdomen, as well as any echogenic omentum, large mass or collection, or pleural effusions at the lung bases. In girls, the assessment of the gynaecological structures, particularly the right ovary, should be performed at this stage.
Graded compression US
- Step 1:
Displacing small bowel loops out of the way
Normal bowel loops are displaced by gentle compression of the anterior abdominal wall using the US probe. These loops should be easily compressed and displaced away. The displacement of the bowel structures should allow the visualisation of the iliac vessels in the right iliac fossa as well as the psoas muscle. Two-plane scanning is performed (longitudinal and transverse).
- Step 2:
Visualisation of the ascending colon and caecumThe ascending colon is visualised as a non-peristalsing structure containing gas and fluid in the right side of the abdomen. The probe is then moved inferiorly toward the caecum, using repeated compression and release to express gas and fluid from the bowel (Fig. 1a, b). The right psoas muscle should also be visualised (Fig. 2). The adjacent terminal ileum should be identified as a compressible structure that is undergoing peristalsis.
- Step 3:
Identification of the appendixOnce the caecum has been seen, the appendix should be visualised arising from it, separate to the terminal ileum (Fig. 3). The appendix should be followed along its whole length. A normal appendix should measure 6 mm or less in diameter from outside wall to outside wall. It should have a thin wall (less than 3 mm), be empty or gas/faecal-filled and compressible, and there should be no evidence of hypervascularisation [23, 24, 25, 26].
- Step 4:
Assessment for features of acute appendicitisAn abnormal appendix can have any of the following characteristics which should be actively considered:
Secondary features can be observed around the inflamed appendix; these should be actively sought:
Compressibility: in acute appendicitis, the appendix is non-compressible . One caveat here is perforation when the appendix can become compressible.
Target sign appearance: this is caused by a fluid-filled centre (hypoechoic centre), surrounded by a hyperechoic ring (mucosa/submucosa) which is surrounded by a hypoechic muscularis layer giving a target sign on axial imaging (Fig. 7a, b) [15, 28].
Thickening and hyperechogenicity of the overlying peritoneum (Fig. 13).
Dilated hyperactive small bowel from secondary small bowel obstruction (Fig. 14).
It is not uncommon that the appendix cannot be identified. There are varying rates quoted in the literature for the appendix being seen, between 24.4 % and 69.3 % [6, 13, 23]. In this situation, it is important to actively assess for the secondary features often seen which may help direct further management. Repeating the examination after a few hours has been shown to significantly increase the sensitivity of US .
Causes of inadequate visualisation of the appendix and possible solutions
There are a few common causes for the non-visualisation of the appendix.
Patient symptoms: pain and abdominal guarding
Pain can often limit the extent of compression of the abdominal wall, thus limiting the ability to displace the overlying bowel loops. Pain relief prior to the examination can help. Examining the rest of the abdomen first with a curvilinear probe prior to the graded compression of the right iliac fossa can help relax the patient. Gentle compression should be used initially to gauge the patient’s symptoms.
The position of the appendix can also lead to difficulty in its visualisation. A retrocaecal appendix can occur in 20.1–65 % of patients [34, 35] and will be difficult to visualise on US [6, 24, 30]. The appendix may be also anatomically abnormally positioned, such as abnormalities of situs, when the caecum is mobile or subhepatic, or in cases of congenital malrotation [36, 37, 38]. Rarely, it may also be located away from the right iliac fossa due to very long length. The average appendix measures between 8 and 10 cm in length, but can measure more than 20 cm [39, 40]. The use of the lower frequency 3.5 MHz curvilinear probe may reveal free fluid or omental reaction away from the right iliac fossa, giving a clue about an anatomically abnormal appendix location.
State of the pathological process
Appendiceal obstruction leading to appendicitis can occur anywhere along the appendix [15, 24]. Therefore, if only a small part of the appendix is involved, the inflammation may be limited to the tip . Incomplete visualisation of the whole length of the appendix due to position can lead to a false-negative result if only the tip of the appendix is involved.
In an advanced stage of appendicitis, the appendix can be engulfed within an inflammatory mass and identification of the appendix itself may be impossible. This situation is also identified at surgery .
This is a rare cause of acute abdominal pain in children. It is a benign self-limiting process that should be managed conservatively. It is more common in boys and in those who are obese [49, 50]. Symptoms are often acute or subacute in nature and often right-sided. The patient is often apyrexic and does not have symptoms of diarrhoea, vomiting or anorexia . On US, there is evidence of an ovoid soft-tissue hyperechoic mass located between the anterior abdominal wall and the colon, which is non-compressible and painful . If the normal appendix is not visualised, this soft-tissue mass can be mistaken for acute appendicitis.
Caused by failure of the omphalomesenteric-vitelline duct to regress, a Meckel’s diverticulum is found in 1–4 % of the population . The US appearances of an inflamed Meckel’s diverticulum may mimic acute appendicitis . On US examination, it may appear as a non-compressible, blind-ending, hypoechoic structure in the right-iliac fossa . It may also appear as a cyst-like mass with a thick, irregular internal wall with an external hypoechoic rim (corresponding to the muscle layer) and an internal hyperechoic line corresponding to the submucosal and mucosal layers . Doppler US can reveal hypervascularisation .
Indeterminate challenging cases
If the diagnosis remains unclear there are many further options. As described already, repeating the US has been shown to increase the diagnostic accuracy in patients with suspected appendicitis . While CT seems to be the next choice in the difficult patient in many centres worldwide, it is increasingly difficult to justify due to the concerns over the effects of ionising radiation [17, 18, 19]. Magnetic resonance imaging (MRI) is beginning to be used in the evaluation of the paediatric patient with suspected appendicitis. Several recent studies have shown a sensitivity and specificity comparable to CT, with sensitivities between 97.6 % and 100 %, and specificities between 96 % and 99 % [59, 60, 61]. The use of MRI thus avoids the concerning effects of ionising radiation. While scoring systems such as the Alvarado score are available to stratify the risk of the presenting patient, they have been shown to be inadequate in the prediction of appendicitis on their own [62, 63]. However, when combined with US, such scores have been shown to be useful in indeterminate cases .
US examination of a paediatric patient where appendicitis is suspected includes examination of the abdominal organs with a curvilinear probe, followed by graded compression of the right colon and appendix using a linear-array probe. This should be performed in a systematic way to maximise the chance of identifying the appendix and the features that would suggest appendicitis.
Conflicts of interest
- 18.Krille L, Zeeb H, Jahnen A, Mildenberger P, Seidenbusch M, Schneider K, Weisser G, Hammer G, Scholz P, Blettner M (2012) Computed tomographies and cancer risk in children: a literature overview of CT practices, risk estimations and an epidemiologic cohort study proposal. Radiat Environ Biophys 51:103–111PubMedCrossRefGoogle Scholar
- 19.Mathews JD, Forsythe AV, Brady Z, Butler MW, Goergen SK, Byrnes GB, Giles GG, Wallace AB, Anderson PR, Guiver TA, McGale P, Cain TM, Dowty JG, Bickerstaffe AC, Darby SC (2013) Cancer risk in 680 000 people exposed to computed tomography scans in childhood or adolescence: data linkage study of 11 million Australians. BMJ 346:f2360PubMedPubMedCentralCrossRefGoogle Scholar
- 48.Ebel KD, Blickman H, Willich E, Richter E (1998) Differential diagnosis in pediatric radiology. Thieme, New York, pp 250–251Google Scholar
- 53.Levine D, Brown DL, Andreotti RF, Benacerraf B, Benson CB, Brewster WR, Coleman B, DePriest P, Doubilet PM, Goldstein SR, Hamper UM, Hecht JL, Horrow M, Hur HC, Marnach M, Patel MD, Platt LD, Puscheck E, Smith-Bindman R (2010) Management of asymptomatic ovarian and other adnexal cysts imaged at US: Society of Radiologists in Ultrasound consensus conference statement. Radiology 256:943–954PubMedCrossRefGoogle Scholar
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