Infant ; Humans ; Atrioventricular Block/therapy* ; Subclavian Vein ; Pacemaker, Artificial ; Endocardium

OBJECTIVE: To evaluate the technical feasibility of intranodal lymphangiography and thoracic duct (TD) access in a canine model.MATERIALS AND METHODS: Five male mongrel dogs were studied. The dog was placed in the supine position, and the most prominent lymph node in the groin was accessed using a 26-gauge spinal needle under ultrasonography (US) guidance. If the cisterna chyli (CC) was not opacified by bilateral lymphangiography, the medial iliac lymph nodes were directly punctured and Lipiodol was injected. After opacification, the CC was directly punctured with a 22-gauge needle. A 0.018-in microguidewire was advanced through the CC and TD. A 4-Fr introducer and dilator were then advanced over the wire. The microguidewire was changed to a 0.035-in guidewire, and this was advanced into the left subclavian vein through the terminal valve of the TD. Retrograde TD access was performed using a snare kit.RESULTS: US-guided lymphangiography (including intranodal injection of Lipiodol [Guerbet]) was successful in all five dogs. However, in three of the five dogs (60%), the medial iliac lymph nodes were not fully opacified due to overt Lipiodol extravasation at the initial injection site. In these dogs, contralateral superficial inguinal intranodal injection was performed. However, two of these three dogs subsequently underwent direct medial iliac lymph node puncture under fluoroscopy guidance to deliver additional Lipiodol into the lymphatic system. Transabdominal CC puncture and cannulation with a 4-Fr introducer was successful in all five dogs. Transvenous retrograde catheterization of the TD (performed using a snare kit) was also successful in all five dogs.CONCLUSION: A canine model may be appropriate for intranodal lymphangiography and TD access. Most lymphatic intervention techniques can be performed in a canine using the same instruments that are employed in a clinical setting.
Animals ; Catheterization ; Catheters ; Dogs ; Ethiodized Oil ; Fluoroscopy ; Groin ; Humans ; Lymph Nodes ; Lymphatic System ; Lymphography ; Male ; Needles ; Punctures ; SNARE Proteins ; Subclavian Vein ; Supine Position ; Thoracic Duct ; Ultrasonography

OBJECTIVE: Aberrant right subclavian artery (ARSA) is a rare anatomical variant of the origin of the right subclavian artery. ARSA is defined as the right subclavian artery originating as the final branch of the aortic arch. The purpose of this study is to determine the prevalence and the anatomy of ARSA evaluated with computed tomography (CT) angiography.METHODS: CT angiography was performed in 3460 patients between March 1, 2014 and November 30, 2015 and the results were analyzed. The origin of the ARSA, course of the vessel, possible inadvertent ARSA puncture site during subclavian vein catheterization, Kommerell diverticula, and associated vascular anomalies were evaluated. We used the literature to review the clinical importance of ARSA.RESULTS: Seventeen in 3460 patients had ARSA. All ARSAs in 17 patients originated from the posterior aspect of the aortic arch and traveled along a retroesophageal course to the right thoracic outlet. All 17 ARSAs were located in the anterior portion from first to fourth thoracic vertebral bodies and were located near the right subclavian vein at the medial third of the clavicle. Only one of 17 patients presented with dysphagia.CONCLUSION: It is important to be aware ARSA before surgical approaches to upper thoracic vertebrae in order to avoid complications and effect proper treatment. In patients with a known ARSA, a right transradial approach for aortography or cerebral angiography should be changed to a left radial artery or transfemoral approach.
Angiography ; Aorta, Thoracic ; Aortography ; Catheterization ; Catheters ; Cerebral Angiography ; Clavicle ; Deglutition Disorders ; Diverticulum ; Humans ; Korea ; Prevalence ; Punctures ; Radial Artery ; Subclavian Artery ; Subclavian Vein ; Thoracic Vertebrae

The primary site for a hemodialysis catheter insertion is the right internal jugular vein (IJV) followed by the left IJV and subclavian vein. In cases when veins of the upper extremities are exhausted, femoral veins are an alternative insertion location. Femoral catheter insertions should only be used for short periods because of the increased risk of infection. There is a percutaneous technique to recanalize occluded central veins for hemodialysis catheter insertion. We experienced success with a cut-down method for permcath through a completely occluded IJV. We, therefore, find surgical recanalization to be better than percutaneous method in terms of cost and safety.
Catheters ; Femoral Vein ; Humans ; Jugular Veins ; Methods ; Renal Dialysis ; Subclavian Vein ; Upper Extremity ; Veins

OBJECTIVE: Central venous catheter (CVC) misplacement can result in incorrect readings of the central venous pressure, vascular erosion, and intravascular thrombosis. Several studies have examined the correlation between the guidewire J-tip direction and misplacement rate. This study examined whether the guidewire J-tip direction (cephalad vs. caudad) affects the misplacement rate in right subclavian venous catheterization. METHODS: This prospective randomized controlled study was conducted between February 2016 and February 2017. The subjects were divided into two groups (cephalad group vs. caudad group) and the misplacement rate was compared according to guidewire J-tip direction in each group. RESULTS: Of 100 patients, the cephalad and caudad groups contained 50 patients each. The age, sex, and operator experience were similar in the two groups. In the cephalad group, misplacement of CVC insertion into the ipsilateral internal jugular vein occurred in two cases. In the caudad group, misplacement of CVC insertion into the contralateral subclavian vein occurred in one case, with loop formation in the brachiocephalic trunk in one case. Guidewire J-tip direction showed no significant correlation with CVC misplacement. CONCLUSION: The guidewire J-tip direction does not influence the rate of misplacement.
Brachiocephalic Trunk ; Catheterization* ; Catheters* ; Central Venous Catheters ; Central Venous Pressure ; Humans ; Jugular Veins ; Prospective Studies ; Reading ; Subclavian Vein ; Thrombosis

OBJECTIVE: To assess whether ultrasonographic examination compared to chest radiography (CXR) is effective for evaluating complications after central venous catheterization. METHODS: We performed a prospective observational study. Immediately after central venous catheter insertion, we asked the radiologic department to perform a portable CXR scan. A junior and senior medical resident each performed ultrasonographic evaluation of the position of the catheter tip and complications such as pneumothorax and pleural effusion (hemothorax). We estimated the time required for ultrasound (US) and CXR. RESULTS: Compared to CXR, US could equivalently identify the catheter tip in the internal jugular or subclavian veins (P=1.000). Compared with CXR, US examinations conducted by junior residents could equivalently evaluate pneumothorax (P=1.000), while US examinations conducted by senior residents could also equivalently evaluate pneumothorax (P=0.557) and pleural effusion (P=0.337). The required time for US was shorter than that for CXR (P < 0.001). CONCLUSION: Compared to CXR, US could equivalently and more quickly identify complications such as pneumothorax or pleural effusion.
Catheterization, Central Venous* ; Catheters* ; Central Venous Catheters* ; Diagnostic Imaging ; Observational Study ; Pleural Effusion ; Pneumothorax ; Prospective Studies ; Radiography ; Subclavian Vein ; Thorax ; Ultrasonography*

Baseline ¹⁸F-FDG PET was performed in a 74-year-old patient with relapsing upper mediastinum lymphoma. Left subclavian thrombosis was suspected on prior contrast-enhanced CT. Dynamic PET imaging was achieved during 3 min after IV injection of ¹⁸F-FDG to the left arm in order to further assess left subclavian vein permeability. The 20-s dynamic frame at 1 min after injection confirmed the absence of flow in the left subclavian vein and evidenced the derivation of ¹⁸F-FDG through left axillary, then superficial, then right internal mammary collaterals to the superior vena cava, hence confirming the subclavian thrombosis.
Aged ; Arm ; Humans ; Lymphoma ; Mediastinum ; Permeability ; Subclavian Vein ; Thrombosis ; Tomography, X-Ray Computed ; Vena Cava, Superior ; Venous Thrombosis

Angiography ; Arteriovenous Shunt, Surgical ; Brachiocephalic Veins ; diagnostic imaging ; Collateral Circulation ; Constriction, Pathologic ; diagnostic imaging ; Female ; Humans ; Jugular Veins ; diagnostic imaging ; Kidney Failure, Chronic ; therapy ; Male ; Middle Aged ; Phlebography ; Renal Dialysis ; methods ; Subclavian Vein ; diagnostic imaging ; Vascular Access Devices

Lead insertion for cardiac implantable electronic devices requires venous access into the right side of the heart. The access route commonly used is from the axillary vein, through the subclavian vein and the superior vena cava. However, in patients with congenital heart malformations or those with vascular stenosis, and/or those who have undergone previous cardiac surgery, the passage of leads might be difficult, and the implantation procedure would show restricted scope. In such cases, insertion of leads through the hepatic vein is known to be a safe procedure. We report 2 cases of patients with limited vascular access who underwent lead implantation using the transhepatic approach—1 patient who underwent placement of an implantable cardioverter defibrillator and the other who underwent placement of a permanent pacemaker.
Axillary Vein ; Constriction, Pathologic ; Defibrillators ; Defibrillators, Implantable ; Heart ; Hepatic Veins ; Humans ; Subclavian Vein ; Thoracic Surgery ; Vena Cava, Superior

BACKGROUND: The current indications of cardiac implantable electronic devices (CIEDs) have expanded to include young patients with serious cardiac risk factors, but CIED placement has the disadvantage of involving unsightly scarring and bulging of the chest wall. A collaborative team of cardiologists and plastic surgeons developed a technique for the subpectoral placement of CIEDs in young female patients via a transaxillary approach. METHODS: From July 2012 to December 2015, subpectoral CIED placement via an axillary incision was performed in 10 young female patients, with a mean age of 25.9 years and mean body mass index of 20.1 kg/m². In the supine position, with the patient's shoulder abducted, an approximately 5-cm linear incision was made along one of the deepest axillary creases. The submuscular plane was identified at the lateral border of the pectoralis major, and the dissection continued over the clavipectoral fascia until the subpectoral pocket could securely receive a pulse generator. Slight upward dissection also exposed an entrance to the subclavian vein, allowing the cardiology team to gain access to the vein. One patient with dilated cardiomyopathy underwent augmentation mammoplasty and CIED insertion simultaneously. RESULTS: One case of late-onset device infection occurred. All patients were highly satisfied with the results and reported that they would recommend the procedure to others. CONCLUSIONS: With superior aesthetic outcomes compared to conventional methods, the subpectoral placement of CIEDs via a transaxillary approach is an effective, single-incision method to hide operative scarring and minimize bulging of the device, and is particularly beneficial for young female or lean patients.
Body Mass Index ; Cardiac Resynchronization Therapy ; Cardiology ; Cardiomyopathy, Dilated ; Cicatrix ; Defibrillators, Implantable ; Fascia ; Female* ; Humans ; Mammaplasty ; Methods ; Pacemaker, Artificial ; Plastics ; Risk Factors ; Shoulder ; Subclavian Vein ; Supine Position ; Surgeons ; Thoracic Wall ; Veins