Abstract
Fractures are reported to be the second most common findings in child abuse, after skin lesions such as bruises and contusions. This makes careful interpretation of childhood fractures in relation to the provided clinical history important. In this literature review, we address imaging techniques and the prevailing protocols as well as fractures, frequently seen in child abuse, and the differential diagnosis of these fractures. The use of a standardised protocol in radiological imaging is stressed, as adherence to the international guidelines has been consistently poor. As fractures are a relatively common finding in childhood and interpretation is sometimes difficult, involvement of a paediatric radiologist is important if not essential. Adherence to international guidelines necessitates review by experts and is therefore mandatory. As in all clinical differential diagnoses, liaison between paediatricians and paediatric radiologists in order to obtain additional clinical information or even better having joint review of radiological studies will improve diagnostic accuracy. It is fundamental to keep in mind that the diagnosis of child abuse can never be solely based on radiological imaging but always on a combination of clinical, investigative and social findings. The quality and interpretation, preferably by a paediatric radiologist, of radiographs is essential in reaching a correct diagnosis in cases of suspected child abuse.
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Introduction
Fractures are reported to be the second most common findings in child abuse, after skin lesions such as bruises and contusions [39, 47]. Fractures resulting from physical violence can be found throughout the whole skeleton; they are likely to be multiple and can show diverse stadia of consolidation [21, 37, 53, 71]. In the majority of cases, no external physical findings, e.g. bruises or haematomas, are present [42, 66].
In the USA, approximately 10% of children under the age of 5 years visit the emergency department (ED) as a result of non-accidental injuries [22]. In children evaluated in the ED on suspicion of child abuse, over 30% appears to have fresh or healing fractures [23]. In a study on deceased children between the ages of 1 and 15 years (average, 3.9 years) of air force personnel in the USA, it was found that 55% of these children had been seen by a physician as a result of physical trauma in the month prior to their demise [38]. In a retrospective case based analysis of 435 child abuse victims, Carthy and Pierce found that in 51 children (11.7%), the diagnosis of child abuse could have been made at their first presentation at a hospital [9]. Of these 51 children, six (12%) died and ten (20%) survived with handicap.
Fractures in children, besides being a sign of child abuse, are a relatively common finding. In a large retrospective study in 8,642 children, the reported chance to sustain a fracture between birth and the age of 16 was 42% for boys and 27% for girls, i.e. an average 2.1% chance for a child to sustain one fracture per year [35]. These findings are in keeping with a similar study on fractures [71].
The fact that fractures on the one hand are a sign of child abuse but on the other hand are a quite common result of accidental trauma means that it is essential that the interpretation of the type and location of a fracture, seen in the light of the clinical anamnesis, is done by an experienced and trained (paediatric) radiologist [34, 36].
In this paper, we will discuss the radiological work-up in case of suspected child abuse and the main radiological findings indicative of child abuse. We will first address the different imaging techniques and then aspects of fractures (localisation, type, dating and differential diagnosis) that should be evaluated when considering the diagnosis of child abuse. As radiology deals with signs of physical child abuse child abuse should throughout the text be read as physical child abuse.
Imaging techniques
Conventional radiography
Conventional radiography has historically been and, to date, continuous to be the mainstay in radiological imaging of suspected child abuse, both in identifying new cases of possible child abuse, where an incidental finding on a radiograph can be the first sign of child abuse, as well as in the work-up of cases of suspected child abuse. In the latter, a skeletal survey, a systematically performed series of radiographic images that encompasses the entire skeleton, is a routine part of the work-up procedure in children under the age of 2 years [3]. In these cases, the skeletal survey should consist of a complete depiction of each anatomic region on separate radiographs. International guidelines for the skeletal survey have been published by the American College of Radiology (ACR) as well as the Royal College of Radiologists and the Royal College of Paediatrics and Child Health (RCR and RCPCH) (Table 1) [2, 65]. The main difference between these two guidelines is the addition of oblique chest radiographs in the RCR and RCPCH guideline. It has been shown that implementation of oblique chest radiographs increased the sensitivity for the detection of rib fractures by 17% (95%CI 2–36%) and the specificity by 7% (95%CI 2–13%) [24]. According to both protocols, a full skeletal survey consists of at least 20 radiographs. In our tertiary referral centre, where we review skeletal surveys in case of suspected child abuse, we have observed that it is quite common to perform an incomplete skeletal survey [67]. From this study, it was not clear if this is due to unfamiliarity with the international guidelines or fear for radiation dose. Especially when child abuse is part of the differential diagnosis, a thorough work-up is essential. Both making the diagnosis and missing the diagnosis can have enormous consequences for the lives of these children.
In case of equivocal findings, the use of a repeat skeletal survey, in which case the skull should be excluded as fractures of the skull do not show callus formation, after 14 days, has shown to increase sensitivity and specificity. In a prospective study, additional information regarding skeletal trauma was obtained in 22 of 48 patients [75]. In two cases, the repeat skeletal survey exam influenced the diagnosis, and a definite diagnosis of child abuse could be made. In a retrospective study in 23 children, follow-up exams yielded additional information in 14 children [32].
An issue not specifically addressed in the guidelines is the matter of how to deal with young siblings of abused children. In a study in 795 siblings of abused children, it has been shown that, in 37% of the children, maltreatment was not limited to the abused child but directed to all siblings; in 20% of the children, the abuse was specifically was directed at some but not all siblings [20]. These figures have made us decide that, in our hospital, siblings of abused children under the age of 2 years are routinely assessed for signs of child abuse in line with the international guideline cut-off age for skeletal survey (Fig. 1a).
Bone scintigraphy
In several countries, bone scintigraphy is used in cases of suspected child abuse. A meta-analysis found that although bone scintigraphy had a higher diagnostic yield in more anatomical complex locations, such as the pelvis and feet, it was less sensitive for classic metaphyseal lesions (CML) [11, 19, 26, 48, 62]. The latter has been shown by Mandelstam et al. [40], who, in 20 CMLs detected on conventional radiography, only seven showed increased uptake on the bone scintigraphy.
In the ACR appropriateness criteria, no consensus on the use of bone scintigraphy was reached by the expert panel. In the comments, it is stated: ‘Indicated when a clinical suspicion of abuse remains high and documentation is still necessary’ [57].
A drawback of bone scintigraphy is that not many departments have experience with (this technique in) children; this also means that the experience in reading these studies will be insufficient, thus limiting the applicability. Another relative drawback is the radiation dose involved in this study, which is significantly higher compared to the conventional skeletal survey (3 mSv compared to 0.16 mSv effective dose) [40].
Other imaging techniques
In the past few decades, the radiological arsenal has increased dramatically, and with the widespread availability of computed tomography (CT) and magnetic resonance imaging (MRI), this specialty has evolved significantly.
There is an increasing use of CT in first line trauma triage, where the ‘entry through the gantry’ is becoming more and more a reality [17, 73]. There is ample evidence that CT outperforms conventional radiology in, e.g. the detection of rib fractures [70]. In a retrospective study of 45 paediatric trauma patients, 18 of 45 patients had findings only at CT, including two patients with rib fractures [56]. An additional advantage of CT is the capability of obtaining 3D images, which can give more information (Fig. 2a, b). Given the relatively high radiation dose involved in computed tomography (an abdominal CT scan has a reported effective radiation dose of up to 10 mSv; for comparison, the radiation dose of a single chest radiograph is approximately 0.1 mSv) and the fact that CML will go undetected, its use in child abuse cases will be restricted to those critically ill children who might need (neuro)surgical intervention. CT should not be used as a replacement of conventional radiography; even in cases where CT has been performed during trauma evaluation, a full skeletal survey should be performed.
For an increasing number of clinical indications, bone scintigraphy is being replaced by whole body short tau inverse recovery MRI (WB-STIR) [27, 46]. This work has attracted attention to radiologists involved in the field of child abuse. In a study comparing the conventional skeletal survey to WB-STIR in 16 children (age range, 1.5–37 months), a sensitivity of 75% (33/44) for rib fractures and 67% (2/3) for metaphyseal corner fractures was found [15]. In a recent study by Perez-Rossello et al. [52], WB-STIR had a low sensitivity for CML (31%) and rib fractures (57%). Given these findings, the use of WB-STIR should not routinely be performed.
For the completeness of this overview of techniques, the use of ultrasonography and fluorine-18 sodium fluoride positron emission tomography should be mentioned. These techniques, on a case-by-case basis, have been reported but are not validated and should not be used in a routine work-up [14, 41, 49, 58].
Fractures
Differentiating between fractures resulting from accidental trauma or child abuse is, in most cases, only possible with knowledge of the full clinical history and in cooperation with attending clinicians. However, a list of specificity of fractures for child abuse has been published in the renowned textbook ‘Diagnostic imaging of child abuse’ edited by Kleinman (Table 2) [28]. Table 2 should be seen as a guideline, but it is important to remember that no fracture in itself is pathognomonic for child abuse (Fig. 3). In case of a fracture, with a high specificity of abuse, a differential diagnosis should always be considered. It is important that the fracture type matches the clinical history and developmental stage of the child.
Two fractures, most indicative of child abuse, will be discussed in more detail.
Rib fractures
Rib fractures are generally seen as the hallmark of child abuse, especially in cases of inflicted traumatic brain injury. It is not uncommon that rib fractures are found incidentally as may be clinically silent (Fig. 1b) [10, 61]. The most common mechanism seen in case of rib fractures is anterior–posterior compression of the chest [31, 72]. In this situation, excessive leverage of the ribs over the transverse processes can lead to posterior rib fractures.
In a retrospective study, Barsness et al. [4] assessed the positive predictive value (PPV) of rib fractures in relation to child abuse. In total, 316 rib fractures were identified in 62 children; in 51 (82%), the fractures were due to abuse. In children <3 years of age, the PPV of rib fractures for abuse was 95%. Their study also showed that in child abuse cases, multiple rib fractures are more likely to be seen; posterior and lateral rib fractures (78%) were most prevalent, and 29% of the cases were the only skeletal finding.
Although rib fractures have a high specificity for abuse, they have been described in other scenarios. Posterior rib fractures, although rare and only in cases of difficult labour or large babies, have been reported after vaginal delivery [68]. Rib fractures are well described in metabolic bone disease of prematurity or other metabolic disorders and skeletal dysplasias [16, 59]. In these cases, rib fractures are seldom the only abnormal finding; family history, physical examination or the skeletal survey show indications for an underlying disorder or, e.g. vitamin D deficiency.
More controversially is the issue of rib fractures as a result of cardiopulmonary resuscitation (CPR), an issue often addressed by defence lawyers in court. Until recently, rib fractures were not thought to occur as a result of resuscitation [44, 60]. However, with the introduction of two handed infant encircling CPR, in which the hand position resembles the way perpetrators hold their children when they are reportedly shaken, it is becoming a relevant issue [1]. Several cases of anterior–lateral acute rib fractures as a result of resuscitation have been published (Fig. 4) [5, 13, 45, 69]. In all publications, the authors stress the fact that this is an extremely rare finding and that child abuse should be ruled out in all cases. Perhaps, even more important is the fact that even in cases in which rib fractures have been described as a result of CPR, no posterior rib fractures were seen.
Metaphyseal corner fractures
Next to rib fractures, the CML, first described by the paediatric radiologist John Caffey in 1957, is a highly specific finding for abuse [8, 30]. These fractures are also known as corner or bucket handle fractures. CMLs are most often found in the distal femur, proximal and distal tibia/fibula and proximal humerus (Fig. 5a, b) [31]. On imaging, the appearance of CML varies depending on the size of the fragment and the position of the extremity in relation to the X-ray beam [29]. The mechanism of injury for the CML involves a shearing force in manual assaults; the extremities may undergo substantial torsion and traction leading to a CML. Healing of CML is variable. If the CML is associated with significant displacement and periosteal stripping, there may be conspicuous sclerosis and subperiosteal new bone formation. However, most CML heal without radiographic findings.
Since no single fracture is pathognomonic for child abuse, there is a case for differential diagnosis for CML. CML have been described as an iatrogenic trauma after delivery and orthopaedic interventions for clubfeet [8, 18, 50]. In addition, metabolic bone diseases, e.g. rickets, and bone dysplasias, especially Schmid-type metaphyseal chondrodysplasia (OMIM no. 156500) and spondylometaphyseal dysplasia corner fracture type (OMIM no. 184255), can have metaphyseal changes similar to the CML.
Dating fractures
Radiological dating of fractures in the context of child protection, whether in a medical or in a forensic setting is possible to a certain extent but it certainly no exact science. Table 3 shows the radiological key findings most consistently agreed upon by radiologists [12, 25, 28, 74].
The issue of fracture dating was addressed in a meta-analysis of 1.556 papers, which were reviewed systematically by a large (and varying) group of specialists [54]. After application of exclusion criteria, only three studies, with combined data on 189 children, could be included. Based on this meta-analysis, the authors concluded that fracture dating in children is not an exact science, but that radiologists should be able to differentiate recent from old fractures.
We, as authors, feel that although estimation of fracture age should be approached with caution, experienced paediatric radiologists should be able to make informed judgments whether or not fractures (excluding skull, spine fractures and some CML) are in a healing phase. Healing can usually be judged as early or mature, and when multiple fractures are present, it is often possible to state if the fractures are of similar or different ages.
Differential diagnosis
As children grow up, they discover the world and accidents leading to fractures are therefore a common finding [43]. As a result of these accidents, long bone shaft fractures are the most common fractures in the emergency department. The older the child, the more likely this fracture is caused by an accidental trauma. In non-ambulatory infants, however, the same fractures are cause for concern. As the saying goes: ‘those who don’t cruise, don’t bruise’ [63].
In case of a paediatric fracture, a differential diagnosis should always be kept in mind, including child abuse. As mentioned in the introduction, about 10% of the paediatric ED visits is a result of child abuse [22]. It is known that this diagnosis is frequently missed by the treating physician due to an incomplete clinical work-up, both with respect to the physical exam as well as the anamnesis [55, 64]. Next to accidental trauma, the treating physician should think of child abuse, disorders related to collagen production, bone mineralisation and other diseases leading to an increased risk in bone fragility (Table 4). As mentioned previously, there are also diseases that may mimic fractures, such as skeletal dysplasias and also more common diseases such as osteomyelitis (Fig. 6) or sickle cell disease. Finally, especially for radiologists with a limited experience in paediatric radiology, normal variants, such as metaphyseal step-off’s, metaphyseal spurs and physiological subperiosteal new bone formation, may present as a diagnostic dilemma (Fig. 7). The interested reader is referred to textbooks for an in-depth discussion on the differential diagnosis of paediatric fractures [6].
Discussion
Imaging child abuse is both clinically and emotionally difficult for those involved; this is one field in which an error in judgement in either way will have a detrimental effect on the overall health of the child and social system in which the child lives. That and the increasing public attention make it, in some countries, more and more difficult to find experts who are willing to be involved in this field.
Radiologists play an important if not vital role in the diagnosis of child abuse. In order to fulfil this role, several criteria must be met; first of all, the paediatric radiologist should be adequately trained in this field. In this light, it is of interest to note that the American Board of Pediatrics in 2005 established certification for child abuse paediatricians; for radiologists, such a certification does not exist [7]. Second, we feel that paediatric radiologists should be seen as equal partners to paediatricians involved in child abuse, similar to the development in radiology in general. Third, if at all possible paediatric radiologists should become involved in their hospital’s child abuse team, although this can be time consuming, their input will (as the first author can tell from personal experience) be highly appreciated. Finally, paediatric radiologists should set the standard in imaging child abuse and adhere to existing guidelines. Although the guidelines of the ACR and RCR and RCPCH are available online for free, adherence to these guidelines has shown to be poor [33, 51, 67]. In interpreting the results from these studies (especially European studies), it is of importance to note that paediatric radiology in general is a small subspecialty in radiology and that not all radiologists have been trained in paediatric radiology. Therefore, involvement of paediatricians in imaging of child abuse might have a positive influence on the adherence to these guidelines. In our country, as is the case in many European countries, most hospitals do not have direct access to a paediatric radiologist. We recommend that in case of suspected child abuse, the skeletal survey should be reviewed by a trained paediatric radiologist or a radiologist with experience in paediatric musculoskeletal imaging before a final conclusion is reported to parents or child protection services.
As in all clinical differential diagnoses, but perhaps even more important in child abuse cases, liaisons with paediatricians in order to obtain additional clinical information or even better having joint review of radiological studies will improve diagnostic accuracy. The diagnosis of child abuse is never solely based on radiological imaging but on a combination of clinical, investigative and social findings.
Abbreviations
- ED:
-
Emergency department
- ACR:
-
American College of Radiology
- RCR:
-
Royal College of Radiologists
- RCPCH:
-
Royal College of Paediatrics and Child Health
- CML:
-
Classic metaphyseal lesions
- CPR:
-
Cardiopulmonary resuscitation
- CT:
-
Computed tomography
- MRI:
-
Magnetic resonance imaging
- OMIM:
-
Online Mendelian Inheritance in Man
References
American College of Radiology (ACR) (1997) Standards for skeletal surveys in children. Resolution 22. American College of Radiology, Reston, pp 51–54
American College of Radiology (ACR) (2006) ACR practice guideline for skeletal surveys in children. American College of Radiology, Reston, 17-6-0008
Barsness KA, Cha ES, Bensard DD, Calkins CM, Partrick DA, Karrer FM, Strain JD (2003) The positive predictive value of rib fractures as an indicator of nonaccidental trauma in children. J Trauma 54:1107–1110
Betz P, Liebhardt E (1994) Rib fractures in children—resuscitation or child abuse? Int J Leg Med 106:215–218
Bilo RAC, Robben SGF, van Rijn RR (2009) Normal variants, congenital and acquired disorders. In: Bilo RAC, Robben SGF, van Rijn RR (eds) Forensic aspects of paediatric fractures; differentiating accidental trauma from child abuse. Springer, Berlin, pp 133–170
Block RW, Palusci VJ (2006) Child abuse pediatrics: a new pediatric subspecialty. J Pediatr 148:711–712
Caffey J (1957) Some traumatic lesions in growing bones other than fractures and dislocations: clinical and radiological features: The Mackenzie Davidson Memorial Lecture. Br J Radiol 30:225–238
Carty H, Pierce A (2002) Non-accidental injury: a retrospective analysis of a large cohort. Eur Radiol 12:2919–2925
Chapman S (1990) Radiological aspects of non-accidental injury. J R Soc Med 83:67–71
Conway JJ, Collins M, Tanz RR (1993) The role of bone scintigraphy in detecting child abuse. Semin Nucl Med 23:321–333
Cumming W (1979) Fractures of the hands and feet in child abuse: imaging and pathologic features. J Can Assoc Radiol 30:33
Dolinak D (2007) Rib fractures in infants due to cardiopulmonary resuscitation efforts. Am J Forensic Med Pathol 28:107–110
Drubach LA, Sapp MV, Laffin S, Kleinman PK (2008) Fluorine-18 NaF PET imaging of child abuse. Pediatr Radiol 38:776–779
Evangelista P, Barron C, Goldberg A, Jenny C, Tung G (2006) MRI STIR for the evaluation of nonaccidental trauma in children. In: Pediatric Academic Societies’ Abstract Archive 2000–2006, 2912.433
Feldman KW, Brewer DK (1984) Child abuse, cardiopulmonary resuscitation, and rib fractures. Pediatrics 73:339–342
Fung Kon Jin PH, Dijkgraaf MG, Alons CL et al (2011) Improving CT scan capabilities with a new trauma workflow concept: simulation of hospital logistics using different CT scanner scenarios. Eur J Radiol. doi:10.1016/j.ejrad.2009.11.026
Grayev AM, Boal DK, Wallach DM, Segal LS (2001) Metaphyseal fractures mimicking abuse during treatment for clubfoot. Pediatr Radiol 31:559–563
Haase GM, Ortiz VN, Sfanakis GN (1980) The value of radionuclide bone scanning in the early recognition of deliberate child abuse. J Trauma 20:873–875
Hamilton-Giachritsis CE, Browne KD (2005) A retrospective study of risk to siblings in abusing families. J Fam Psychol 19:619–624
Hobbs CJ, Hanks HGI, Wynne JM (1993) Child abuse and neglect—a clinician’s handbook. Churchill Livingstone, London
Holten JC, Friedman SB (1968) Child abuse: early case finding in the emergency department. Pediatrics 42:128–138
Hyden PW, Gallagher TA (1992) Child abuse intervention in the emergency room. Pediatr Clin North Am 39:1053–1081
Ingram JD, Connell J, Hay TC, Strain JD, Mackenzie T (2000) Oblique radiographs of the chest in nonaccidental trauma. Emerg Radiol 7:42–46
International Liaison Committee on Resuscitation (2006) The International Liaison Committee on Resuscitation (ILCOR) consensus on science with treatment recommendations for pediatric and neonatal patients: pediatric basic and advanced life support. Pediatrics 117:e955–e977
Islam O, Soboleski D, Symons S, Davidson LK, Ashworth MA, Babyn P (2000) Development and duration of radiographic signs of bone healing in children. AJR Am J Roentgenol 175:75–78
Jaudes PK (1984) Comparison of radiography and radionuclide bone scanning in the detection of child abuse. Pediatrics 73:166–168
Kellenberger CJ, Epelman M, Miller SF, Babyn PS (2004) Fast STIR whole-body MR imaging in children. Radiographics 24:1317–1330
Kleinman PK (1998) Diagnostic imaging of child abuse. Mosby, St. Louis
Kleinman PK (2008) Problems in the diagnosis of metaphyseal fractures. Pediatr Radiol 38:S388–S394
Kleinman PL, Kleinman PK, Savageau JA (2004) Suspected infant abuse: radiographic skeletal survey practices in pediatric health care facilities. Radiology 233:477–485
Kleinman PK, Marks SC Jr (1995) Relationship of the subperiostal bone collar to metaphyseal lesions in abused infants. J Bone Joint Surg Am 77A:1471–1476
Kleinman PK, Marks SC Jr, Nimkin K, Rayder SM, Kessler SC (1996) Rib fractures in 31 abused infants: postmortem radiologic-histopathologic study. Radiology 200:807–810
Kleinman PK, Nimkin K, Spevak MR, Rayder SM, Madansky DL, Shelton YA, Patterson MM (1996) Follow-up skeletal surveys in suspected child abuse. AJR Am J Roentgenol 167:893–896
Kremer C, Racette S, Marton D, Sauvageau A (2008) Radiographs interpretation by forensic pathologists: a word of warning. Am J Forensic Med Pathol 29:295–296
Landin LA (1983) Fracture patterns in children. Analysis of 8, 682 fractures with special reference to incidence, etiology and secular changes in a Swedish urban population 1950–1979. Acta Orthop Scand Suppl 202:1–109
Leung RS, Nwachuckwu C, Pervaiz A, Wallace C, Landes C, Offiah AC (2009) Are UK radiologists satisfied with the training and support received in suspected child abuse? Clin Radiol 64:690–698
Leventhal JM, Thomas SA, Rosenfield NS, Markowitz RI (1993) Fractures in young children. Distinguishing child abuse from unintentional injuries. Am J Dis Child 147:87–92
Lucas DR, Wezner KC, Milner JS, McCanne TR, Harris IN, Monroe-Posey C, Nelson JP (2002) Victim, perpetrator, family, and incident characteristics of infant and child homicide in the United States Air Force. Child Abuse Neglect 26:167–186
Maguire S, Mann MK, Sibert J, Kemp A (2005) Are there patterns of bruising in childhood which are diagnostic or suggestive of abuse? A systematic review. Arch Dis Child 90:182–186
Mandelstam SA, Cook D, Fitzgerald M, Ditchfield MR (2003) Complementary use of radiological skeletal survey and bone scintigraphy in detection of bony injuries in suspected child abuse. Arch Dis Child 88:387–390
Markowitz RI, Hubbard AM, Harty MP, Bellah RD, Kessler A, Meyer JS (1993) Sonography of the knee in normal and abused infants. Pediatr Radiol 23:264–267
Mathew MO, Ramamohan N, Benet GC (1998) Importance of bruising associated with paediatric fractures: prospective observational study. BMJ 317:1117–1118
Mathison DJ, Agrawal D (2010) An update on the epidemiology of pediatric fractures. Pediatr Emerg Care 26:594–603
Matshes EW, Lew EO (2010) Do resuscitation-related injuries kill infants and children? Am J Forensic Med Pathol 31:178–185
Matshes EW, Lew EO (2010) Two-handed cardiopulmonary resuscitation can cause rib fractures in infants. Am J Forensic Med Pathol (31):303–307
Mazumdar A, Siegel MJ, Narra V, Luchtman-Jones L (2002) Whole body fast inversion recovery MR imaging of small cell neoplasms in pediatric patients: a pilot study. AJR Am J Roentgenol 179:1261–1266
McMahon P, Grossman W, Gaffney M, Stanitski C (1995) Soft-tissue injury as an indication of child abuse. J Bone Joint Surg Am 77:1179–1183
Merten DF, Radlowski MA, Leonidas JC (1983) The abused child: a radiological reappraisal. Radiology 146:377–381
Nimkin K, Kleinman PK, Teeger S, Spevak MR (1995) Distal humeral physeal injuries in child abuse: MR imaging and ultrasonography findings. Pediatr Radiol 25:562–565
O'Connell A, Donoghue VB (2007) Can classic metaphyseal lesions follow uncomplicated caesarean section? Pediatr Radiol 37:488–491
Offiah AC, Hall CM (2003) Observational study of skeletal surveys in suspected non-accidental injury. Clin Radiol 58:702–705
Perez-Rossello JM, Connolly SA, Newton AW, Zou KH, Kleinman PK (2010) Whole-body MRI in suspected infant abuse. AJR Am J Roentgenol 195:744–750
Pierce MC, Bertocci GE (2006) Fractures resulting from inflicted trauma: assessing injury and history compatibility. Clin Pediatr Emerg Med 7:143–148
Prosser I, Maguire S, Harrison SK, Mann M, Sibert JR, Kemp AM (2005) How old is this fracture? Radiologic dating of fractures in children: a systematic review. AJR Am J Roentgenol 184:1282–1286
Ravichandiran N, Schuh S, Bejuk M, Al-Harthy N, Shouldice M, Au H, Boutis K (2010) Delayed identification of pediatric abuse-related fractures. Pediatrics 125:60–66
Renton J, Kincaid S, Ehrlich PF (2003) Should helical CT scanning of the thoracic cavity replace the conventional chest x-ray as a primary assessment tool in pediatric trauma? An efficacy and cost analysis. J Pediatr Surg 38:793–797
Slovis TL, Smith W, Kushner DC, Babcock DS, Cohen HL, Gelfand MJ, Hernandez RJ, McAlister WH, Parker BR, Royal S, Strain JD, Strife JL, Kanda MB, Myer E, Decter RM, Moreland MS, Eggli D (2000) Imaging the child with suspected physical abuse. American College of Radiology. ACR Appropriateness Criteria. Radiology 215(Suppl: 805–9):805–809
Smeets AJ, Robben SG, Meradji M (1990) Sonographically detected costo-chondral dislocation in an abused child. A new sonographic sign to the radiological spectrum of child abuse. Pediatr Radiol 20:566–567
Smurthwaite D, Wright N, Russell S et al (2009) How common are rib fractures in extremely low birth weight preterm infants? Arch Dis Child Fetal Neonatal Ed 99:F138–F139
Spevak MR, Kleinman PK, Belanger PL, Richmond JM (1994) Cardiopulmonary resuscitation and rib fractures in infants. A postmortem radiologic–pathologic study. JAMA 272:617–618
Stover B (2007) Diagnostic imaging in child abuse. Radiologe 47:1037–1048
Sty JR, Starshak RJ (1983) The role of bone scintigraphy in the evaluation of suspected child abuse. Radiology 146:369–375
Sugar NF, Taylor JA, Feldman KW (1999) Bruises in infants and toddlers: those who don't cruise rarely bruise. Puget Sound Pediatric Research Network. Arch Pediatr Adolesc Med 153:399–403
Taitz J, Moran K, O'Meara M (2004) Long bone fractures in children under 3 years of age: is abuse being missed in emergency department presentations? J Paediatr Child Health 40:170–174
The Royal College of Radiologists and the Royal College of Paediatrics and Child Health (2008) Standards for radiological investigations of suspected non-accidental injury. RCR and RCPCH, London
Valvano T, Binns H, Flaherty E et al (2006) The reliability of bruising in predicting which fractures are caused by child abuse. In: Pediatric Academic Societies’ Abstract Archive 2000–2006, 3140.5
van Rijn RR, Bilo RA, Robben SG (2009) Birth-related mid-posterior rib fractures in neonates: a report of three cases (and a possible fourth case) and a review of the literature. Pediatr Radiol 39:30–34
van Rijn RR, Kieviet N, Hoekstra R et al (2009) Radiology in suspected non accidental injury: theory and practice in The Netherlands. Eur J Radiol 71:147–151
Weber MA, Risdon RA, Offiah AC, Malone M, Sebire NJ (2009) Rib fractures identified at post-mortem examination in sudden unexpected deaths in infancy (SUDI). Forensic Sci Int 189:75–81
Wootton-Gorges SL, Stein-Wexler R, Walton JW, Rosas AJ, Coulter KP, Rogers KK (2008) Comparison of computed tomography and chest radiography in the detection of rib fractures in abused infants. Child Abuse Negl 32:659–663
Worlock P, Stower M, Barbor P (1986) Patterns of fractures in accidental and non-accidental injury in children: a comparative study. BMJ 293:100–102
Worn MJ, Jones MD (2007) Rib fractures in infancy: establishing the mechanisms of cause from the injuries—a literature review. Med Sci Law 47:200–212
Wurmb TE, Frühwald P, Hopfner W, Keil T, Kredel M, Brederlau J, Roewer N, Kuhnigk H (2009) Whole-body multislice computed tomography as the first line diagnostic tool in patients with multiple injuries: the focus on time. J Trauma 66:658–665
Yeo LI, Reed MH (1994) Staging of healing of femoral fractures in children. Can Assoc Radiol J 45:16–19
Zimmerman S, Makoroff K, Care M, Thomas A, Shapiro R (2005) Utility of follow-up skeletal surveys in suspected child physical abuse evaluations. Child Abuse Negl 29:1075–1083
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van Rijn, R.R., Sieswerda-Hoogendoorn, T. Educational paper. Eur J Pediatr 171, 215–224 (2012). https://doi.org/10.1007/s00431-011-1499-1
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DOI: https://doi.org/10.1007/s00431-011-1499-1