Commentary on Bentsen et al.'s study of rib fracture risk after stereotactic body radiotherapy.

Tugcu AO ，Dogru GD ，Dursun CU 《-》

Far Posterior Approach for Rib Fracture Fixation: Surgical Technique and Tips.

The present video article describes the far posterior or paraspinal approach to posterior rib fractures. This approach is utilized to optimize visualization intraoperatively in cases of far-posterior rib fractures. This technique is also muscle-sparing, and muscle-sparing posterolateral, axillary, and anterior approaches have been shown to return up to 95% of periscapular strength by 6 months postoperatively1. Like most fractures, the skin incision depends on the fracture position. The vertical incision is made either just medial to a line equidistant between the palpable spinous processes and medial scapular border or directly centered over the fracture line in this region. The incision and superficial dissection must be extended cranially and caudally, approximately 1 or 2 rib levels past the planned levels of instrumentation, in order to allow muscle elevation and soft-tissue retraction. Superficial dissection reveals the trapezius muscle, with its fibers coursing from inferomedial to superolateral caudal to the scapular spine, and generally coursing transversely above this level. The trapezius is split in line with its fibers (or elevated proximally at the caudal-most surface), and the underlying layer will depend on the location of the incision. The rhomboid minor muscle overlies ribs 1 and 2, the rhomboid major muscle overlies ribs 3 to 7, and the latissimus dorsi overlies the remaining rib levels. To avoid muscle transection, the underlying muscle is also split in line with its fibers. Next, the thoracolumbar fascia is encountered and sharply incised, revealing the erector spinae muscles, which comprise the spinalis thoracis, longissimus thoracis, and iliocostalis thoracis muscles. These muscles and their tendons must be sharply elevated from lateral to midline; electrocautery is useful for this because there is a robust blood supply in this region. Medially, while retracting the paraspinal musculature, visualization with this approach can extend to the head and neck of the rib, and even to the spine. Following deep dissection, the fractures are now visualized. During fracture reduction, it is critical to assess reduction of both the costovertebral joint and the costotransverse joint. With fractures closer to the spine, it is recommended to have at least 2 cm between the rib head and tubercle in order to allow 2 plate holes to be positioned on the neck of the rib; if comminution exists and plating onto the transverse process is needed, several screws are required here for stability as well. For appropriate stability if plating onto the spine is not required, a minimum of 3 locking screws on each side of the fracture are recommended. Contouring of the plates to match the curvature of the rib and to allow for proper apposition may be required with posterior rib fractures. Screws must be placed perpendicular to the rib surface. Following operative stabilization of the rib fractures, a layered closure is performed, and a soft dressing is applied. Nonoperative alternatives include non-opioid and opioid medications as well as corticosteroid injections for pain control. Supportive mechanical ventilation and physiotherapy breathing exercises can also be implemented as needed. Operative alternatives include open reduction and internal fixation utilizing conventional locking plates and screws. Rib fractures are often treated nonoperatively when nondisplaced because of the surrounding soft-tissue support2,3. According to Chest Wall Injury Society guidelines, contraindications to surgical fixation of rib fractures include patients requiring ongoing resuscitation; rib fractures involving ribs 1, 2, 11, or 12, which are relative contraindications; severe traumatic brain injury; and acute myocardial infarction. Patient age of <18 years is also a relative contraindication for the operative treatment of rib fractures. The current literature does not recommend surgical fixation in this age group because these fractures typically heal as the patient ages; however, fracture-dislocations may require the use of instrumentation to prevent displacement. Currently, the U.S. Food and Drug Administration does not approve most plating systems for patients <18 years old4. In certain cases, including those with substantial displacement, persistent respiratory distress, pain, or fracture nonunion, stabilization with open reduction and internal fixation may be appropriate5-7. In cases of flail chest injuries, surgery is often indicated6. Flail chest injuries have been noted in the literature to have an incidence of approximately 150 cases per 100,000 injuries and have been shown to carry a mortality rate of up to 33%8,9. Surgical treatment of rib fractures has been shown to be associated with a decreased hospital length of stay and mortality rate in patients with major trauma1. Expected outcomes of this procedure include low complication rates, decreased hospital and intensive care unit length of stay, and reduced mechanical ventilation time10,11. However, as with any procedure, there are also risks involved, including iatrogenic lung injury from long screws or an aortic or inferior vena cava injury with aggressive manipulation of displaced fractured fragments, especially on the left side of the body. During open reduction, there is also a risk of injuring the neurovascular bundle. Tanaka et al. demonstrated a significant reduction in the rate of postoperative pneumonia in their operative group (22%) compared with their nonoperative group (90%)12. Schuette et al. demonstrated a 23% rate of postoperative pneumonia, 0% mortality at 1 year, an average of 6.2 days in the intensive care unit, an average total hospital length of stay of 17.3 days, and an average total ventilator time of 4 days in the operative group10. Prins et al. reported a significantly lower incidence of pneumonia in operative (24%) versus nonoperative patients (47.3%; p = 0.033), as well as a significantly lower 30-day mortality rate (0% versus 17.7%; p = 0.018)3. This procedure utilizes a muscle-sparing technique, which has demonstrated successful results in the literature on the use of the posterolateral, axillary, and anterior approaches, returning up to 95% of periscapular strength, compared with the uninjured shoulder, by 6 months postoperatively1. The use of a muscle-sparing technique with the far-posterior approach represents a topic that requires further study in order to compare the results with the successful results previously shown with other approaches. The ipsilateral extremity can be prepared into the field to allow its intraoperative manipulation in order to achieve scapulothoracic motion and improved subscapular access.For costovertebral fracture-dislocations, the vertical incision line is made just medial to a line equidistant between the palpable spinous processes and medial scapular border.Lateral decubitus positioning can be utilized to allow for simultaneous access to fractures that extend more laterally and warrant a posterolateral approach; however, it is generally more difficult to access the fracture sites near the spine with this approach.This muscle-sparing technique is recommended to optimize postoperative periscapular strength, as previously demonstrated with other approaches.Incision and superficial dissection must be extended cranially and caudally approximately 1 or 2 rib levels past the planned levels of instrumentation in order to allow muscle elevation and soft-tissue retraction.To avoid muscle transection during surgical dissection, the underlying muscle is split in line with its fibers.During deep dissection, it can be difficult to delineate underlying muscles because these muscles have fibers that do not run in line with the trapezius, and some, like the rhomboid major, run nearly perpendicular to it.Electrocautery is useful while elevating the erector spinae muscles and tendons, as there is a robust blood supply in this region.The erector spinae muscle complex is relatively tight and adherent to the underlying ribs, which may make it difficult to achieve adequate visualization; therefore, at least 3 rib levels must be elevated to access a rib for reduction and instrumentation.Although internal rotation deformities are more common in this region, any external displacement of a fracture can lead to a muscle injury that can be utilized for access.During fracture reduction, it is critical to assess reduction of both the costovertebral joint and the costotransverse joint.Special attention must be given to contouring the implants because there are not any commercially available precontoured implants for this region at this time, and plating onto the spine remains an off-label use of any currently available implant.For the more challenging fracture patterns, the use of a right-angled power drill and screwdriver is recommended.Generally, the incision is utilized as previously described to provide access as far medial as the transverse process if needed. However, in cases in which this approach does not allow proper visualization with rib fracture-dislocations involving the posterior ribs or spine, a midline spinal incision can be utilized while working in combination with a spine surgeon.With fractures closer to the spine, it is recommended to have at least 2 cm between the rib head and tubercle in order to allow 2 plate holes to be positioned on the neck of the rib.If comminution exists and plating onto the transverse process is needed, several screws are required for stability.When measuring the length of screws to be placed in the transverse process, preoperative CT scans can be utilized. CT = computed tomographyCWIS = Chest Wall Injury SocietyIVC = inferior vena cava.

Manes TJ ，DeGenova DT ，Taylor BC ，Patel JN ... -  《-》

Response to commentary on "Cumulative rib fracture risk after stereotactic body radiotherapy in patients with localized non-small cell lung cancer" by Tugcu et al.

Kirkelund Bentsen K ，Brink C ，Bjørn Nielsen T ，Bank Lynggaard R ，Just Vinholt P ，Schytte T ，Hansen O ，Starup Jeppesen S ... -  《-》

Rib fracture characteristics increasing the risk of hemothorax: a multicenter study.

The precise assessment of hemothorax risk resulting from a rib fracture is not feasible. CT images, patient characteristics, and clinical experience are utilized in daily practice to assess risk intuitively. This study aimed to identify specific markers on CT images that can predict the risk of hemothorax. The study was retrospectively conducted between May 2021 and December 2023 at three different centers. Patients diagnosed with hemothorax at the initial assessment or during follow-up were identified among those being followed for rib fractures. An investigation was carried out to examine the relationship between the number of rib fractures, displacement status, and the location of the fracture on the rib arch with the risk of hemothorax. Of the 273 patients included in the study, 201 (73.6%) were male. The mean age was 53.9 ± 17.27 (19-93) years. Lateral (p = 0.029) and posterior (p < 0.001) location of the fracture and displacement of at least one fracture (p = 0.003) were associated with an increased risk. There was a significant correlation between the number of rib fractures and the risk of hemothorax (p < 0.001). The optimal cut-off for the number of rib fractures associated with a high risk of hemothorax was determined to be 4. Anatomical characteristics of a rib fracture can be useful to assess the risk of hemothorax practically in patients with thoracic trauma especially in emergency rooms. Patients with four or more rib fractures, at least one displaced rib fracture, and lateral and posterior rib fractures should be followed more carefully for hemothorax.

Aydın S ，Kahraman Aydın S ，Gülmez B ，Güneş SG ，Kavurmacı Ö ，Dadaş ÖF ... -  《Scientific Reports》

Short-term follow-up of single-port thoracoscopic rib fracture reduction and internal fixation for the treatment of multiple rib fractures.

The objective of this study was to evaluate the short-term outcomes of single-port thoracoscopic rib fracture reduction and internal fixation for the treatment of multiple rib fractures. This study included 149 patients with multiple rib fractures admitted to the Second People's Hospital Affiliated with Fujian University of Chinese Medicine between June 2021 and April 2024. The patients were divided into two groups based on the surgical method. The study group, consisting of 84 cases, underwent rib fracture reduction using a single-port thoracoscopy and internal fixation with a memory alloy reverse rib embrace device. The control group, consisting of 65 cases, underwent traditional open surgery for rib fracture internal fixation. Perioperative and follow-up data were collected and analyzed to assess incision length, total operation time, intraoperative blood loss, number of memory alloy embrasures placed, placement success rate, drainage tube placement time, time to mobilization, total hospitalization duration, total cost, preoperative and postoperative pain levels, postoperative complications, and rib CT results three months postoperatively. There was no statistically significant difference in general conditions between the study group and the control group. All 149 patients successfully completed the surgery, with 3 to 10 intrathoracic memory alloy embrace devices placed in each patient, achieving a 100% success rate. Compared to the control group, the study group showed significant improvements in incision length (3.5 ± 0.6 vs. 6.5±1.6 cm), intraoperative blood loss (92.5 ± 15.1 vs. 113 ± 18.2 ml), drainage tube placement time (75.4 ± 13.1 vs. 90.6 ± 15.4 h), mobilization time (2.9 ± 1.1 vs. 3.3 ± 1.3 days), and hospital stay (10.8 ± 2.7 vs. 12 ± 3.5 days), with differences being statistically significant (P < 0.05). In terms of preoperative Visual Analogue Scale (VAS) pain scores, the study group had a significantly lower score on the first postoperative day compared to the control group (3.9 ± 1.1 vs. 4.5 ± 1.4, P < 0.05). A follow-up CT and 3D reconstruction at 3 months post-surgery showed that all patients had securely fixed plates, with the study group demonstrating a higher rate of excellent fracture healing (94% vs. 83.1%), which was statistically significant (P < 0.05). The use of a memory alloy reverse rib embrasure device for intrathoracic rib fracture fixation via single-port thoracoscopic surgery is safe and reliable. This method demonstrates a high success rate of internal fixation, excellent clinical fracture healing, and advantages such as minimal trauma, rapid recovery, and the simultaneous treatment of other intrathoracic conditions. It significantly reduces postoperative pain and enhances the quality of life.

Lin ZW ，Long JT ，Lin WK 《-》