V-OG04 Paravertebral Catheter Placement In Minimally Invasive Oesophagectomy

Background Pain control is a vital component of enhanced recovery programmes for patients undergoing an oesophagectomy. Multimodal analgesia using intrathecal diamorphine and local anaesthetic infusion catheters into the paravertebral space and rectus sheath is increasingly utilised. Multimodal analgesia can provide comparable pain relief while potentially reducing side effects associated with thoracic epidurals. This video demonstrates the placement of paravertebral catheters following thoracoscopic oesophagectomy. Methods The video demonstrates the technique for paravertebral catheter placement at the end of the thoracic phase of an oesophagectomy, as practiced at our institution. Results Once the catheter has been placed and flushed, a bolus 15-20mls of 0.25 per cent Levobupivicaine is injected. A 600mls reservoir of Levobupivicaine is attached at the end of the procedure. Conclusions Paravertebral catheters provide a safe and feasible option for pain control following oesophagectomy.

Pediatric Extramedullary Epidural Spinal Teratomas: A Case Report and Review of the Literature

Background. Teratomas in the pediatric population are most commonly found in the sacrococcygeal region. Pediatric intraspinal teratomas, however, are an exceedingly rare central nervous system (CNS) neoplasm. The clinical presentation of these intraspinal neoplasms can vary significantly and thus can be difficult to identify in infants less than one year of age where verbal expression and motor development are still lacking. Case Description. A 7-month-old, previously healthy male presented with a thoracic scoliosis and an asymptomatic right midupper thoracic spinal prominence present since birth. MRI revealed an extensive heterogenous mass in the right epidural space from T5-T6 and the right paravertebral space, resulting in severe spinal stenosis. Outcome. Complete resection of the tumor, including a three-level neurotomy, was achieved by posterior decompression/laminectomy. The final tumor was consistent with a mature teratoma. The surgical resection was performed without any immediate complications. Conclusions. Extramedullary epidural teratomas are exceptionally rare tumors in the pediatric population. Clinical presentation can be ambiguous, particularly in an infant. MRI was useful in suggesting a teratoma as a potential diagnosis and for postoperative surveillance for recurrence. However, histopathological analysis remains the gold standard for definitive diagnosis. Surgical resection is the mainstay of treatment, especially in the setting of cord compression and progressive loss of motor function. Close follow-up is crucial to monitor for progressive spinal deformity or recurrence.

Anatomical basis of fascial plane blocks

Fascial plane blocks (FPBs) are regional anesthesia techniques in which the space (“plane”) between two discrete fascial layers is the target of needle insertion and injection. Analgesia is primarily achieved by local anesthetic spread to nerves traveling within this plane and adjacent tissues. This narrative review discusses key fundamental anatomical concepts relevant to FPBs, with a focus on blocks of the torso. Fascia, in this context, refers to any sheet of connective tissue that encloses or separates muscles and internal organs. The basic composition of fascia is a latticework of collagen fibers filled with a hydrated glycosaminoglycan matrix and infiltrated by adipocytes and fibroblasts; fluid can cross this by diffusion but not bulk flow. The plane between fascial layers is filled with a similar fat-glycosaminoglycan matric and provides gliding and cushioning between structures, as well as a pathway for nerves and vessels. The planes between the various muscle layers of the thorax, abdomen, and paraspinal area close to the thoracic paravertebral space and vertebral canal, are popular targets for ultrasound-guided local anesthetic injection. The pertinent musculofascial anatomy of these regions, together with the nerves involved in somatic and visceral innervation, are summarized. This knowledge will aid not only sonographic identification of landmarks and block performance, but also understanding of the potential pathways and barriers for spread of local anesthetic. It is also critical as the basis for further exploration and refinement of FPBs, with an emphasis on improving their clinical utility, efficacy, and safety.

Ultrasound Guided Thoracic Paravertebral Block as an Analgesic Technique for Tracheoesophageal Fistula repair : A Case Report

Ultrasound has now become an eye of anaesthesiologist and has encouraged for its pervasive use. Its considerable use in the perioperative period for various invasive purposes has added an extra caution to prevent unforeseen complications over blind blocks. The ultrasound-guided thoracic paravertebral block provides excellent perioperative analgesia following thoracic surgery. It can be given as a single shot or a continuous infusion technique placing a catheter. Here the local anesthetic agent is deposited in the paravertebral space from where the spinal nerve emerges which are devoid of coverings and are sensitive to local anesthetics. Even a single-shot block provides analgesia of 4-6 dermatomal levels. The use of local anesthetics using ultrasound not only adds safety measures to minimize procedural complications but also reduces the perioperative requirement of opioids. It also helps in the reduction of postoperative pulmonary complications and early extubation following thoracic surgery. We report a case series where single-shot ultrasound-guided unilateral paravertebral blocks were used as an analgesic technique for the repair of tracheoesophageal fistula in neonates. After delivering anesthesia and confirming the correct placement of the endotracheal tube the neonate was kept on the left lateral position to undergo right thoracotomy and repair of fistula. Scanning at T4 level with a linear probe was done to identify the transverse process, pleura, costotransverse ligament, intercostal muscle, and the paravertebral space where the local anesthetic agent was deposited under aseptic precautions. Tenting of pleura was the endpoint for the completion of the block. The extensive use of various regional anesthetic technique has significantly improved the postoperative outcome of the patients along with adequate perioperative pain management.

Anatomy of the thoracic paravertebral space: 3D micro-CT findings and their clinical implications for nerve blockade

BackgroundA precise anatomical understanding of the thoracic paravertebral space (TPVS) is essential to understanding how an injection outside this space can result in paravertebral spread. Therefore, we aimed to clarify the three-dimensional (3D) structures of the TPVS and adjacent tissues using micro-CT, and investigate the potential routes for nerve blockade in this area.MethodsEleven embalmed cadavers were used in this study. Micro-CT images of the TPVS were acquired after phosphotungstic acid preparation at the mid-thoracic region. The TPVS was examined meticulously based on its 3D topography.ResultsMicro-CT images clearly showed the serial topography of the TPVS and its adjacent spaces. First, the TPVS was a very narrow space with the posterior intercostal vessels very close to the pleura. Second, the superior costotransverse ligament (SCTL) incompletely formed the posterior wall of the TPVS between the internal intercostal membrane and vertebral body. Third, the retro-SCTL space broadly communicated with the TPVS via slits, costotransverse space, intervertebral foramen, and erector spinae compartment. Fourth, the costotransverse space was intersegmentally connected to the adjacent retro-SCTL space.ConclusionsA non-destructive, multi-sectional approach using 3D micro-CT more comprehensively demonstrated the real topography of the intricate TPVS than previous cadaver studies. The posterior boundary and connectivity of the TPVS provides an anatomical rationale for the notion that paravertebral spread can be achieved with an injection outside this space.

A sono-anatomical and cadaveric study of ultrasound-guided retrolaminar block

Aim: Retrolaminar block (RB) is known to confer chest wall analgesia but, its mechanism has not been established. Our primary objective was to determine if the spread of injectate following RB extends to the paravertebral space (PVS). Second-ary objectives were to determine the predefined anatomical areas and nervous tissues contacted by injectate; the effect of volume on spread; and the extent to which experts can predict PVS spread based on examination of US videos of the injection. Material and methods: US-guided RB was performed on cadavers using a single injection technique of 10, 20 or 30 ml dye. Anatomical dissection was performed to identify the extent of spread of injectate to the retrolaminar, intercostal and PVS. Ultrasound recordings of the injection were independently evaluated by experts in US-guided regional anaesthesia. Results: Spread of injectate to the ipsilateral PVS was identified in 6/10 dissected regions (0/1, 1/3 and 5/6 when injectate volumes of 10, 20 and 30ml were administered respectively). The extent of cephalad-caudad spread within the PVS varied from 1 to 3 levels. Expert interpretation of ultrasound images regarding spread to the PVS demonstrated poor correlation with dye staining observed on dissection. Conclusions: Injectate spread following RB demonstrated substantial variability. Inconsistent spread to the ipsilateral PVS may account for clinically occurring incomplete blocks. The likelihood of spread to the ipsilateral PVS was greater when a larger volume was injected. Expert evaluation of the dynamic ultrasound images obtained at injection can-not reliably predict spread to the PVS.

Distribution of injectates in the thoracic paravertebral space of the dog and cat: A cadaveric study

Background: Thoracic paravertebral block (TPVB) entails injecting a local anesthetic inside the thoracic paravertebral space (TPVS). Loss of resistance to air injection (air-LOR) was the first technique described in humans to locate the TPVS. To date, no study has investigated the spread of any substance after injection into the TPVS using the air-LOR technique nor has described the cranial and caudal limits of the space. Aim: To identify the boundaries of the TPVS, to determine whether the air-LOR technique is reliable for the identification of the TPVS and to examine the relationship between the volume of injectate and its spread. Methods: After a preliminary phase, the thorax of five cat and five dog cadavers was accessed and eviscerated. After TPVS probing, the polyurethane foam was injected, and the cranial and caudal borders were recorded after its maximum spread. Different volumes of a mixture of new methylene blue and ioversol were injected in the TPVS after its localization with a Tuohy needle and air-LOR technique in fourteen dog and six cat cadavers. Lateral radiographs of the vertebral column were used to document needle positioning, spread pattern and extension. The thorax of these subjects was then accessed and eviscerated to observe and record the spread of the mixture. Results: Injecting a dye into the TPVS, localized by an air-LOR technique, resulted in multi-segmental and often bilateral subpleural staining of paravertebral, intercostal, and dorsal mediastinal structures in dog and cat cadavers. The lateral radiographs most often showed a mixed cloud-like and linear spread pattern, which could be a predictor of the longitudinal spread of the dye. The foam injected into the TPVS at the cranial and the caudal level revealed anatomical communication with the cervical, axillar, and lumbar paravertebral regions. Conclusion: TPVS localization by air-LOR technique and injection results in a longitudinal multi-segmental spread in dog and cat cadavers. The communication of the TPVS with the axillary and lumbar regions could be of clinical interest for the brachial plexus and the lumbar intercostal nerve blocks in a clinical setting.

Hyperthermia in a pediatric patient with neuroblastoma during anesthesia: a case report

Background Neuroblastoma is the most common malignant extracranial solid tumor in pediatrics patients. Intraoperative hyperthermia is extremely rare in patients with neuroblastoma and can cause a series of complications. Here, we represent a case of neuroblastoma accompanied by hyperthermia during anesthesia, and propose a rational explanation and management options. Case presentation The patient had gait disturbance and sitting-related pain without fever. Magnetic resonance imaging revealed a soft tissue mass located in the right posterior mediastinum, paravertebral space and canalis vertebralis. Serum tumor marker screening showed that the patient had increased epinephrine, norepinephrine and neuron specific enolase levels, with an increased 24 hour urine vanillylmandelic acid level. Intraspinal tumor resection was conducted. The temperature of the patient rapidly arose to 40.1 °C over 10 minutes when waiting for tracheal extubation. The arterial gas analysis results indicated malignant hyperthermia was less likely, and dantrolene was not administered. Physical cooling methods were used, and the temperature dropped to 38.6 ℃. The trachea was successfully extubated. Histological results confirmed the diagnosis of neuroblastoma. Conclusions Hyperthermia during anesthesia is a serious adverse event. Catecholamines secreted from neuroblatoma cells can lead to hypermetabolism and hyperthermia. Surgeons and anesthesiologists should be aware of the possibility of hyperthermia in patients with neuroblastoma.