Combination of a bronchogenic cyst in the thoracic spinal canal with chronic myelocytic leukemia.

The presented case report describes an incredibly rare instance of an intramedullary bronchial cyst located in the thoracic spinal canal on the dorsal side of the spinal cord, which was observed in a patient with chronic myelogenous leukemia. A 29-year-old man presented with back pain for half a month, along with numbness and pain below the chest and ribs for 1 week. Hypersensitivity was present in the inferior plane of the long xiphoid process in the nervous system. Magnetic resonance imaging (MRI) showed intramedullary cystic lesions in the vertebral body plane of the third to the fourth thoracic vertebra. There was no recurrence during the 6-month postoperative follow-up period. The histopathological findings were consistent with bronchogenic cysts. Cystic lesions were eliminated through the posterior median approach. After the cyst ruptured during surgery, gel liquid was seen, and the majority of the cyst walls were removed. One week after the surgery, the hypersensitivity fully subsided. Six months following surgery, an updated MRI revealed no recurrence. Intramedullary bronchogenic cysts on the dorsal side of the thoracic spine are extremely uncommon. Diagnosis requires histopathological evidence, and it is challenging to diagnose before surgery. Prompt surgical resection is recommended in case of positive diagnosis.

Different patterns of dynamic variations on electrical conductances of acupoints between Qi Vacuity and Qi non-Vacuity after glucose ingestion.

OBJECTIVES: In Traditional Chinese Medicine (TCM), Qi maintains the physiologic function and indicates physiologic energy. Glucose provides energy to humans, thereby playing a role analogous to "nutritive Qi." This study aims to identify the correlations among blood glucose, Qi Vacuity (QV), and the electrical conductances of acupoints. METHODS: Twenty (20) subjects who had ingested a glucose solution after a 10-hour overnight fast were divided into two groups based on QV score. Then their acupoint conductances were measured sequentially using a Ryodoraku instrument during the following 120 minutes. Data were analyzed using generalized estimating equations as a time-series model. RESULTS: Eight (8) subjects were categorized into a Qi Vacuous group for QV score >6, and the other 12 subjects were categorized into a Qi non-Vacuous group for QV score ≤6. During the first 30 minutes, the acupoint conductances decreased on the left Pericardium, left Heart, right Liver, Kidney, and Gallbladder meridians in the Qi Vacuous group, and increased on the right Pericardium meridian and decreased on the right Gallbladder meridian in the Qi non-Vacuous group. From 30 to 60 and 60 to 90 minutes, the acupoint conductances decreased on the Gallbladder, Heart, left Pericardium, left Kidney, right Liver, and right Stomach meridians in the Qi Vacuous group, and increased on the Pericardium, Heart, left Small Intestine, and left Lung meridians in the Qi non-Vacuous group. During the last 30 minutes, more of the acupoint conductances were increased in the Qi non-Vacuous group, whereas only the acupoint conductance on the liver meridian was increased and that on the left gallbladder meridian was decreased in the Qi Vacuous group. CONCLUSIONS: The findings suggest that the energy distribution and transformation in meridian vessels present different patterns in QV and non-QV groups after glucose consumption.

Electrical lumped model for arterial vessel beds.

Numerous electrical analog models of the circulatory system have been proposed. However, conventional models are either too simple, focusing exclusively on heart function, or overly complex, characterizing arteries in excessive detail. The vessel beds, which comprise arteries, capillaries and veins, are well known to be responsible for most of the pressure drop in blood pressure and to dominate the draining of blood flow. Consequently, electrical analog models of the circulatory system should pay more attention to the vessel beds. This investigation divided the arterial system into several aortic segments with vessel beds, and proposed a model that used electrical lumped elements to represent the vessel beds. The model was adopted to simulate blood pressure propagation by considering each vessel bed as an isolated subsystem. The transfer function between the terminals of isolated subsystems was used to identify the electrical components of the lumped elements that characterized the vessel beds. Simulation results reveal that the compliance and impedance of the vessel beds are larger than in previous models that focused on the aorta or arteries. The proposed electrical lumped model could deal with much more information than the simple models due to the lumped element structure. Furthermore, its isolated subsystem approach also makes the proposed model significantly easier to use than the complex models.