No abstract available.
Paralysis* ; Phrenic Nerve*

No abstract available.
Catheters ; Paralysis ; Phrenic Nerve

Various methods of infraclavicular brachial plexus block have been introduced in the past, of which Wilson's coracoid infraclavicular brachial plexus block, a more lateral approach, consequently thought to be easier and safer. While only a few cases of transient ipsilateral phrenic nerve palsy after infraclavicular brachial plexus block have been reported, we describe a rare case of phrenic nerve palsy after Wilson's coracoid infraclavicular brachial plexus block.
Brachial Plexus ; Paralysis ; Phrenic Nerve

No abstract available.
Animals ; Cats* ; Knee Joint* ; Knee* ; Phrenic Nerve*

Pulmonary ligament consists of 2 serosal layer of pleura that connect the lower lobe to the mediastinum.Author analyse and present CT appearance of pulmonary ligament of the 40 normal and abnormal patients on the basisof anatomic knowledge from the cross section of cadaver. Left pulmonary ligament is more frequency visualized thanthe right. The most important CT landmark in localizing pulmonary ligament is the esophagus where the ligamentattaches on its lateral wall. Pitfalls in CT identification of pulmonary ligament are right phrenic nerve andright pericardiacophrenic vessels which emerge from the lateral wall of the IVC and wall of the emphysematousbulla in the region of the pulmonary ligament.
Cadaver ; Esophagus ; Humans ; Ligaments ; Phrenic Nerve ; Pleura

Hiccup is caused by synchronous contractions of the diaphragmatic and intercostal muscles followed by the closure of the glottis. Intractable hiccup is defined as hiccup bouts lasting more than 48 hours or recurring despite various treatments. Recently we have experienced a case of postoperative intractable hiccup. We failed to stop intractable hiccup by pharmacological treatment, but succeeded by unilateral phrenic nerve block.
Glottis ; Hiccup* ; Humans ; Intercostal Muscles ; Nerve Block ; Phrenic Nerve*

Hiccups have more than 100 etiologies. The most common etiology has gastrointestinal origins, related mainly to gastric distention and gastroesophageal reflux disease. Intractable hiccups are rare but may present as a severe symptom of various diseases. Hiccups are mostly treated with non-invasive or pharmacological therapies. If these therapies fail, invasive methods should be used. Here, we present a patient on whom we performed a blockage of the phrenic nerve with the guidance of a nerve stimulator. The patient also had pneumothorax as a complication. Three hours after intervention, a tube thoracostomy was performed. One week later, the patient was cured and discharged from the hospital. In conclusion, a stimulator provides the benefit of localizing the phrenic nerve, which leads to diaphragmatic contractions. Patients with thin necks have more risk of pneumothorax during phrenic nerve location.
Contracts ; Gastroesophageal Reflux ; Hiccup ; Humans ; Neck ; Phrenic Nerve ; Pneumothorax ; Thoracostomy

Phrenic nerve palsy causing hemidiaphragm paralysis is a very uncommon feature of thoracic aortic aneurysm. In one case, a 45-year-old man complained of chronic chest pain, dysphagia, and hoarseness of voice; posteroanterior view chest radiograph revealed lobular enlargement of the superior mediastinum and elevated right hemidiaphragm. Contrast-enhanced computed tomography (CT) of the thorax revealed a giant partially thrombosed aneurysm originating from the ascending aorta and extending into the aortic arch, causing a widening of the aorta-pulmonary window and a compression of the thoracic esophagus. Right hemidiaphragm elevation was explained by the gross mass effect of the aneurysm on the right hilum, causing right phrenic nerve palsy. The patient was to be operated on for surgical correction of the aneurysm, but died before surgery due to spontaneous rupture.
Deglutition Disorders ; Hoarseness ; Aortic Aneurysm, Thoracic ; Paralysis ; Phrenic Nerve

BACKGROUND: Perioperative magnesium sulfate (MgSO4) is used for analgesic, anti-arrhythmic, and obstetric purposes. The effects of MgSO4 on the neuromuscular blockade (NMB) induced by rocuronium, and the sugammadex reversal thereof, have not been clearly quantified. We investigated the effect of various MgSO4 concentrations on the NMB by rocuronium, and sugammadex reversal, in isolated left phrenic nerve hemi-diaphragm (PNHD) preparations from the rat. METHODS: Rat PNHD preparations were randomly allocated to one of four groups varying in terms of MgSO4 concentration (1, 2, 3, and 4 mM, each n = 10, in Krebs solution). The train-of-four (TOF) and twitch height responses were recorded mechanomyographically. The preparations were treated with incrementally increasing doses of rocuronium and each group’s effective concentration (EC)50, EC90, and EC95 of rocuronium were calculated via nonlinear regression. Then, sugammadex was administered in doses equimolar to rocuronium. The recovery index, time to T1 height > 95% of control, and the time to a TOF ratio > 0.9 after sugammadex administration were measured. RESULTS: The EC50, EC90, and EC95 of rocuronium fell significantly as the magnesium level increased. The EC50, EC90, and EC95 of rocuronium did not differ between the 3 and 4 mM groups. The recovery index, time to T1 height > 95% of control, and time to a TOF ratio > 0.9 after sugammadex administration did not differ among the four groups. CONCLUSIONS: Increases in the magnesium concentration in rat PNHD preparations proportionally enhanced the NMB induced by rocuronium but did not affect reversal by equimolar amounts of sugammadex.
Anesthesia ; Animals ; Magnesium Sulfate* ; Magnesium* ; Neuromuscular Blockade ; Phrenic Nerve* ; Rats*

OBJECTIVETo comprehend the anatomic characteristics and correlations between the accessory nerve and the phrenic nerve in the adult corpses.

METHODSThe bilateral accessory nerves, phrenic nerves, and their branches of 20 adult corpses (38 sides) were underwent exposure. The morphologic data of the accessory nerves and the phrenic nerves above clavicle were measured. In addition, the minimal and maximal distances from several points on the accessory nerve to the full length of the phrenic nerve above clavicle were measured. Then, the number of motor nerve fibers on different locations of the nerves utilizing the method of immunohistochemistry were counted and compared.

RESULTThe accessory nerves after sending out the sternocleido-mastoid muscular branches were similar in the morphologic data with the phrenic nerves. Meanwhile, the accessory nerve had a coiled appearance within this geometrical area. The possibly minimal distance between the accessory nerve and phrenic nerve was (3.19 ± 1.23) cm, and the possibly maximal distance between the starting point of accessory nerve and the end of the phrenic nerve above clavicle was (8.71 ± 0.75) cm.

CONCLUSIONSThe accessory nerve and the phrenic nerve are similar in the anatomic evidences and the number of motor nerve fibers. And the length of accessory nerve is sufficiently long to connect with phrenic nerve as needed. It is possible to suture them without strain directly.

Accessory Nerve ; anatomy & histology ; surgery ; Adult ; Female ; Humans ; Male ; Nerve Transfer ; Phrenic Nerve ; anatomy & histology ; surgery