Objective Based on the theory of biomechanics, the finite element method was used to study the injury characteristics of different parts of brain hit by fist with different force and to predict the risk of craniocerebral injury, in order to provide reference for actual medical protection and forensic identification. Methods The finite element model of fist was constructed by using DICOM data modeling method and related software, and the effective mass and speed of fist were used to represent the kinetic energy of fist, and combined with human finite element model THUMS 4.02, the characteristics of craniocerebral injury caused by frontal and lateral blows were parametrically simulated. Results The probability of direct death from a blow to the head was low, but as fist power increased, so did the risk of craniocerebral injury. The characteristics of craniocerebral injury were also significantly different with the different fist hitting head locations. When the frontal area was attacked, the maximum equivalent stress of skull was 122.40 MPa, while that of brain tissue was 4.31 kPa. When the temporal area was attacked, the maximum equivalent stress of skull was 71.53 MPa, while that of brain tissue was 7.09 kPa. Conclusion The characteristics and risks of skull fracture and brain tissue injury are different when different parts of the brain are hit by fist. When the frontal area is hit, the risk of skull fracture is significantly higher than when the temporal area is hit. The risk of brain tissue injury is the opposite. The position with the highest probability of skull fracture is generally the place where the skull is directly impacted, and with the conduction of stress waves, it will spread to other parts of the skull, while the position with the highest risk of brain tissue injury is not the place where the brain is directly impacted.
Biomechanical Phenomena ; Craniocerebral Trauma/etiology* ; Finite Element Analysis ; Head ; Humans ; Skull ; Skull Fractures/etiology*

Child ; Edema ; diagnostic imaging ; etiology ; Emphysema ; diagnostic imaging ; etiology ; Ethmoid Bone ; diagnostic imaging ; injuries ; Eyelid Diseases ; diagnostic imaging ; etiology ; Humans ; Male ; Orbit ; diagnostic imaging ; Orbital Diseases ; diagnosis ; diagnostic imaging ; pathology ; Radiography ; Skull ; diagnostic imaging ; pathology ; Skull Fractures ; complications ; diagnostic imaging

OBJECTIVES: To study the correlation between CT imaging features of acceleration and deceleration brain injury and injury degree. METHODS: A total of 299 cases with acceleration and deceleration brain injury were collected and divided into acceleration brain injury group and deceleration brain injury group according to the injury mechanism. Subarachnoid hemorrhage (SAH) and Glasgow coma scale (GCS), combined with skull fracture, epidural hematoma (EDH), subdural hematoma (SDH) and brain contusion on the same and opposite sides of the stress point were selected as the screening indexes. χ² test was used for primary screening, and binary logistic regression analysis was used for secondary screening. The indexes with the strongest correlation in acceleration and deceleration injury mechanism were selected. RESULTS: χ² test showed that skull fracture and EDH on the same side of the stress point; EDH, SDH and brain contusion on the opposite of the stress point; SAH, GCS were correlated with acceleration and deceleration injury (P<0.05). According to binary logistic regression analysis, the odds ratio (OR) of EDH on the same side of the stress point was 2.697, the OR of brain contusion on the opposite of the stress point was 0.043 and the OR of GCS was 0.238, suggesting there was statistically significant (P<0.05). CONCLUSIONS EDH on the same side of the stress point, brain contusion on the opposite of the stress point and GCS can be used as key indicators to distinguish acceleration and deceleration injury mechanism. In addition, skull fracture on the same side of the stress point, EDH and SDH on the opposite of the stress point and SAH were relatively weak indicators in distinguishing acceleration and deceleration injury mechanism.
Brain Contusion ; Brain Injuries/diagnostic imaging* ; Hematoma, Epidural, Cranial ; Hematoma, Subdural/etiology* ; Humans ; Logistic Models ; Skull Fractures/diagnostic imaging* ; Tomography, X-Ray Computed ; Wounds, Nonpenetrating/diagnostic imaging*

OBJECTIVETo study the surgical reconstruction of secondary fracture deformities of the nasal-orbital ethmoid area.

METHODSTypical bicoronal and subciliary incisions or the adjacent scar incision were employed to expose the fractured area. The flattened nasal bone was narrowed by curved osteotomy along the medial orbital rims and trimed with a bur. 2-3 pieces of cranial outer table were used to reconstruct the nasal framework, which were fixed to the frontal bone with mini-plates. After the medial orbital wall and orbital floor were exposed, the herniated orbital contents were released and reduced to the orbital cavity. The fractured orbital walls were repaired precisely with autogenous cranial outer table or Medpor. The medial canthal tendons were anchored superior-posteriorly to the lacrimal fossa with transnasal wires.

RESULTSFrom December 1996 to December 2001, 34 cases of severe nasal-orbital ethmoid fracture deformities were repaired with this technique. Of them, 12 cases had combined orbital-zygomatic fracture, 4 cases had fontal sinus fracture, 1 case had Le Fort II and 1 case had Le Fort III fracture. All the patients recovered well and their facial appearance improved greatly.

CONCLUSIONSThe key points for surgical reconstruction of the periorbital post-fracture deformities are narrowing the flattened nasal root by curved osteotomy, the nasal framework reconstruction with autogenous bone graft, the orbital wall repair to correct enophthalmos, and most importantly, the medial canthal tendon reduction and canthal plasty.

Adolescent ; Bone Transplantation ; methods ; Cicatrix ; surgery ; Enophthalmos ; surgery ; Ethmoid Bone ; injuries ; Humans ; Nasal Bone ; injuries ; Nose Deformities, Acquired ; surgery ; Orbit ; surgery ; Orbital Fractures ; surgery ; Osteotomy ; methods ; Paranasal Sinuses ; injuries ; surgery ; Polyethylenes ; Reconstructive Surgical Procedures ; Skull Fractures ; etiology ; surgery ; Tendons ; surgery

OBJECTIVEThe treatment of frontobasilar fractures is a demanding aspect of craniofacial fracture management. A sequel of inadequate or improper fracture management presents cosmetic and functional problems which are very difficult to correct. The aim of this manuscript was to examine a group of growing patients treated for frontobasilar fractures and provide clinicians a possible therapeutic option for the treatment of these challenging fractures.

METHODSIn this investigation, 12 patients under the age of 16 years treated for severe injuries to the frontobasilar region were included. Their records were reviewed to evaluate the clinical diagnosis, preoperative findings, hospital course, postoperative results, and long-term follow-up. Preoperative and postoperative CT scans were performed in all children treated. Postoperative complications were reviewed in detail. Surgical procedures were evaluated for type and location of fixation. All complications and treatments were recorded.

RESULTSThree of the patients presented with a cerebrospinal fluid (CSF) leak and required pericranial flaps. Only 3 patients underwent removal of plates and screws due to palpability in 1 patient, loose hardware in 1 patient, and limited disturbance on growth in the rest patient. Seven patients underwent open reduction and internal fixation with resorbable plates, 4 patients with titanium plates, and 1 patient with a combination. Follow-up ranged from 6 months to 5 years. No patients with a preoperative CSF leak developed any recurrence of the leak.

CONCLUSIONAccording to basic craniofacial principles, reducing and stabilizing the fractures should reconstruct the anterior cranial base. However, the treatment of paediatric maxillofacial trauma requires the evaluation of several factors. The facial skeleton of a child is constantly evolving and its growth depends on the balance of basal bone and soft tissues.

Adolescent ; Child ; Device Removal ; Female ; Fracture Fixation, Internal ; methods ; Frontal Bone ; diagnostic imaging ; injuries ; Humans ; Internal Fixators ; Male ; Postoperative Complications ; diagnostic imaging ; Skull Fractures ; diagnostic imaging ; etiology ; surgery ; Tomography, X-Ray Computed ; Treatment Outcome