Brachial plexus injury in the child

Obstetric brachial plexus palsy (OBPP) was first described by the Scottish obstetrician William Smellie in 1779 who described, in a newborn, a case of unilateral arm paralysis which rapidly recovered. He attributed this palsy to compression of the axillary nerve against the humerus, probably wrongly in light of subsequent knowledge. The main risk factor for OBPP is high birth weight (>4000 g) and intrapartum shoulder dystocia causing traction on the brachial plexus. It has been demonstrated in cadaveric models that traction on the arm with the neck laterally flexed in the opposite direction causes rupture or avulsion of the brachial plexus. Upper roots are more likely to rupture due to strong ligamentous attachment to the spine whereas the lower roots are more likely to be avulsed. For unknown reasons, however, in the rare circumstance of small babies born breech, upper root avulsion is common. Other risk factors for OBPP include a previous child affected, prolonged labour, instrumented delivery, and multiparity, although each of these may be a surrogate for large birth weight.

FUNCTIONAL OUTCOME OF FRACTURE TALUS: TREATED WITH DIFFERENT MODALITIES

Talus is a peculiar bone as almost 78% of its total bony surface is intra-articular. It transmits the entire body weight and has hardly any musculo-tendinous attachments [1]. Hence its injuries especially fractures and fracture dislocations, though not common, have posed a great deal of problems to orthopaedic surgeons in the form of open wound, skin necrosis from bony pressure, imperfect reduction and avascular necrosis [2-4]. As more than two third of the talus is intraarticular, very limited surface area is available to provide adequate vascular perforations. Blood vessels enter the talus via capsular and ligamentous attachment. Therefore, it is vulnerable to complication such as osteonecrosis after fracture and dislocation of talus [5].

An ovarian torsion in a 2-year-old girl: a case report

Background Abdominal pain is one of the most common complaints by patients in the emergency department. Diarrhea, constipation, and urinary tract infection are the commonest etiologies among these patients, but there are surgical emergencies, such as appendicitis and volvulus of the intestine, which are less common. Torsion of the ovary is rarer than all of the above conditions. Ovarian torsion occurs following the twisting of the ovary on its ligamentous attachment, possibly with a cyst, leading to the impediment of blood flow. Prompt diagnosis with a high clinical suspicion is essential to salvage the ovaries and to prevent complications, including death. Case presentation Here, we present a case of ovarian torsion in a 2-year-old Sri Lankan girl who presented with nonspecific abdominal symptoms after being symptomatically treated twice by her general practitioners for 3 days. Following biochemical and radiological investigations, she was diagnosed with a twisted necrotic ovarian torsion and underwent laparoscopic right-sided oophorectomy. Conclusions Finding the etiology of a child with abdominal pain is challenging, especially because of the limited history, examination findings, the difficulty in carrying out radiological investigations, and the poor specificity of the results compared with adults. This is a case presentation and a brief discussion about the dilemmas and difficulties in the diagnosis and treatment of ovarian torsion in young children.

Thoracic and lumbar intraforaminal ligaments

Object The author conducted a study to investigate the anatomy of the intraforaminal ligaments of the thoracic and lumbar nerve roots and describe their anatomical relationships and functional properties. This anatomical study performed on the intervertebral foramina, intraforaminal ligaments, transforaminal ligaments, and nerve roots of the thoracic and lumbar spine was performed in human cadavers. Methods The foraminal anatomy was studied in 11 whole cadavers (5 females, 6 males) previously prepared with formaldehyde, whose ages at the time of death ranged from 16 to 71 years. The thoracic and lumbar spinal columns were separated from the cervical and sacral segments en bloc using an electric band saw. The paraspinal muscles and their attachments were removed by sharp and meticulous dissection, and the thoracic and lumbar intervertebral foramina were examined under a surgical microscope. The intervertebral foraminal ligaments and nerve roots were exposed. The foraminal contents were identified and studied in detail. The intraforaminal ligaments were stained using H & E to determine ligamentous fiber. Results Intraforaminal ligaments connect the periosteum and transforaminal ligaments to the nerve root sleeves and vessels within the fatty areolar tissue. Histologically, the ligamentous attachment of the nerve roots within the foramina consists of adipose and connective tissue. Conclusions The nerve roots are surrounded by intraforaminal ligaments, which may act in conjunction with the dura and periosteum to protect the nerve roots mechanically.