RESUMEN
OBJECTIVES: To investigate the amplitude-integrated electroencephalography (aEEG) monitoring results of hospitalized neonates in plateau areas. METHODS: A retrospective analysis was conducted on 5 945 neonates who were admitted to the Department of Neonatology, Kunming Children's Hospital, and received aEEG monitoring from January 2020 to December 2022. According to the aEEG monitoring results, they were divided into a normal aEEG group and an abnormal aEEG group. The incidence rate of aEEG abnormalities was analyzed in neonates with various systemic diseases, as well as the manifestations of aEEG abnormalities and the consistency between aEEG abnormalities and clinical abnormalities. RESULTS: Among the 5 945 neonates, the aEEG abnormality rate was 19.28% (1 146/5 945), with an abnormality rate of 29.58% (906/3 063) in critically ill neonates and 8.33% (240/2 882) in non-critically ill neonates (P<0.05). The children with inherited metabolic diseases showed the highest aEEG abnormality rate of 60.77% (79/130), followed by those with central nervous system disorders [42.22% (76/180)] and preterm infants [35.53% (108/304)]. Compared with the normal aEEG group, the abnormal aEEG group had significantly lower age and gestational age, as well as a significantly lower birth weight of preterm infants (P<0.05). Among the 1 146 neonates with aEEG abnormalities, the main types of aEEG abnormalities were sleep cycle disorders in 597 neonates (52.09%), background activity abnormalities in 294 neonates (25.65%), and epileptiform activity in 255 neonates (22.25%), and there were 902 neonates (78.71%) with abnormal clinical manifestations. The sensitivity and specificity of aEEG monitoring for brain function abnormalities were 33.51% and 92.50%, respectively. CONCLUSIONS: In plateau areas, there is a relatively high rate of aEEG abnormalities among hospitalized neonates, particularly in critically ill neonates and those with smaller gestational ages and younger ages, suggesting a high risk of brain injury. Therefore, routine aEEG monitoring for the hospitalized neonates can help with the early detection of brain function abnormalities, the decision-making in treatment, and the formulation of brain protection strategies.
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Electroencefalografía , Humanos , Recién Nacido , Estudios Retrospectivos , Masculino , Femenino , Hospitalización , Recien Nacido Prematuro , Monitoreo Fisiológico/métodosRESUMEN
OBJECTIVE: To observe the effect of San-Ao Decoction (, SAD) on water metabolism of bronchial asthra model mice. METHODS: Forty-five female BALB/c mice were randomly divided into control, model and SAD groups by a random number table, 15 mice in each group. A composite method with ovalbumin (OVA) sensitization and challenge was developed to establish bronchial asthma model. Mice in the control group were intraperitoneally injected with distilled water without aerosol inhalation challenge. On day 15-22, 0.3 mL SAD was administered via gastric route in SAD group, one time per day, while an equivalent volume of normal saline was used for gastric administration in the control and model groups. Changes in airway resistance in the inspiratory phase (RI-R-Area) were detected using an AniRes2005 system, and 5-h urine output was collected by metabolic cages. Histopathological changes in lung and kidney were observed by hematoxylin-eosin staining. mRNA expressions of aquaporin (AQP) 1 and AQP2 in kidney were detected by reverse transcription-polymerase chain reaction, and the protein expressions of AQP1 and AQP2 in kidney were detected by immunohistochemistry. Enzyme-linked immune sorbent assay was used to detect the OVA-specific endothelium-1 (ET-1), antidiuretic hormone (ADH), atrial natriuretic peptide (ANP), prostaglandin E2 (PGE2), and angiotensin II (Ang II) levels in serum, lung and kidney tissues, respectively. The nitric oxide (NO) contents in serum, lung, and kidney tissues were tested by chemical method, respectively. RESULTS: Compared with the control group, the serum IgE level in model group increased (P<0.01). Following the pathologic changes in lung tissue, no significant change in kidney tissue was observed among 3 groups. Compared with the control group, the mice in the model group showed elevated airway resistance during inhalation phase, higher mRNA and protein expression levels on AQP1 and AQP2 in kidney tissue and higher ET-1 levels in serum, lung and kidney tissues, ADH and ANP in lung and serum, PGE2 in kidney, Ang II in lung and kidney tissues (P<0.05 or P<0.01), but decreased in 5-h urinary output as well as NO and PGE2 contents in serum and lung tissues (P<0.05 or P<0.01). Compared with the model group, the mice in the SAD group showed a weakened airway resistance in inspiratory phase, lower mRNA and protein expressions of AQP1 and AQP2 in kidney tissues, lower levels of ET-1, ADH, ANP in serum as well as ET-1, ANP, Ang II levels in kidney tissues (P<0.05 or P<0.01), whereas 5-h urinary output, NO content in kidney, ADH, ANP and PGE2 levels in lung and Ang II in serum increased (P<0.05 or P<0.01). CONCLUSION: San-Ao Decoction can regulate the urine volume through regulating AQP1 and AQP2 expression, and the expression of these in the kidneys might be regulated by ET-1, NO and Ang II.
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Asma , Animales , Acuaporina 2 , Asma/tratamiento farmacológico , Modelos Animales de Enfermedad , Medicamentos Herbarios Chinos , Femenino , Pulmón , Ratones , Ratones Endogámicos BALB CRESUMEN
OBJECTIVE: To calculate the imbalance degree (IBD) of left-right meridian (IBD-LRM), IBD of exterior-interior meridian (IBD-EIM) and IBD of hand-foot meridians (IBD-HFM) of impedance in extracellular fluid of cells in twelve meridians of healthy subjects, so as to provide foundation for meridian diagnosis. METHODS: A total of 31 healthy volunteers were enrolled and bioelectrical impedance spectroscopy (BIS) was applied. The constant current (from 1 to 100 kHz, 200 µA) was connected into the bilateral twelve meridians through two excitation electrodes with a distance of 10 cm. Two measuring electrodes, with an interval of 5 cm, were set in between the two excitation electrodes to collect the voltage amplitude and phase. The Cole-Cole curve fitting was used to calculate the impedance of extracellular fluid of cells in the twelve meridians; the IBD-LRM, IBD-EIM and IBD-HFM as well as their absolute values were calculated. RESULTS: The impedance of extracellular fluid in the left side was higher than that in right side in the large intestine meridian, the small intestine meridian and the bladder meridian (P<0.05, P<0.01). The mean value of IBD-LRM of extracellular fluid was (4.0±1.4) %; the mean value of absolute value of IBD-LRM was (15.0±1.1) %; the maximum absolute value of IBD-LRM was the bladder meridian. The mean value of IBD-EIM was (3.3±1.0) %; the mean value of absolute value of IBD-EIM was (17.9±1.6) %; the maximum absolute value of IBD-EIM was the bladder meridian and the kidney meridian. The impedance of extracellular fluid of hand jueyin meridian, hand taiyin meridian and hand shaoyin meridian were lower than those of foot meridians. The mean value of IBD-HFM was (-2.6±1.1) %; the mean value of absolute value of IBD-HFM was (19.7±1.7) %; the maximum absolute value of IBD-HFM was shaoyang meridian; the imbalance of yin meridians was greater than yang meridians. There were significant differences in impedance of extracellular fluid between left and right and between hands and feet (P<0.05, P<0.01). CONCLUSION: The extracellular fluid of left-right meridians of healthy subjects is different, but the absolute value of IBD is low; the mean value of exterior meridian and interior meridian is very close, and the absolute value of IBD is medium; the impedance of the foot meridians are greater than the hand meridians, and the absolute value of IBD is relatively high.
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Meridianos , Puntos de Acupuntura , Impedancia Eléctrica , Líquido Extracelular , Voluntarios Sanos , HumanosRESUMEN
OBJECTIVE: To compare differences of extracellular fluid impedance (Re) and intracellular fluid impedance (Ri) between the Stomach(ST) Meridian or Gallbladder(GB) Meridian and their neighboring non-meridian sites of the left lower leg at the same level, so as to explore the distribution characteristics of body fluid in the meridian. METHODS: Sixteen healthy volunteers were enrolled in the present study. The Re and Ri were detected by using Ag/AgCl electrodes and a digital lock-in amplifier. The measuring electrodes (at an interval of about 3 cm) were separately fixed to the skin sites covering the running courses of the ST Meridian (in the lateral interspace of the anterior tibial muscle)and the GB Meridian (in the interspace of the anterior edge of the fibula), and the excitation electrodes (at an interval of about 9 cm) respectively fixed to the skin sites covering the anterior tibial muscle and the interspace between the anterior tibial muscle and the tibia (about 2 cm and 5 cm lateral to the ST and GB meridians, and about 3ï¼4 cm and 6ï¼8 cm lateral to the ST and GB meridians, respectively). A 100 µA constant current with frequencies from 1 kHz to 100 kHz delivered via an excitation electrode was applied to the site (control spots of the ST Meridian), and signals of the voltage amplitude and phase difference of the tissues fed to the lock-in amplifier via the measuring electrode were collected, followed by measuring those of the GB Meridian and control sites. The circumference of the lower leg around the two excitation and measuring electrodes was measured. Then the cole-cole curve fitting was performed to calculate the Ri and Re, as well as the intracellular fluid resistivity (ρi) and extracellular fluid resistivity (ρe) of the ST and GB meridians, the related muscles and interspace lateral to ST or GB (ST/GB) meridians at the same level. RESULTS: The Ri and Re (Ω) values of the ST, GB, the muscle lateral to ST/GB and the interspace lateral to ST/GB were 19.1±1.3 and 28.3±1.4, 15.8±1.9 and 25.7±2.0, 19.6±1.3 and 31.3±1.6, and 19.4±1.2 and 32.4±1.6, respectively. The Re values were significantly lower at the ST and GB meridians than at the muscle lateral to and the interspace lateral to both meridians (P<0.05). The ρi and ρe values (Ωâ¢cm) of the ST, GB, the muscle lateral to and the interspace lateral to ST/GB were 658.9±78.5 and 953.8±75.3, 528.0±90.1 and 833.9±101.7, 669.9±71.8 and 1 059.8±86.0, 655.9±64.8 and 1 099.3±93.3, respectively. The ρi and ρe values were significantly lower at the GB Meridian Than at the other three locntions, and the ρe value of ST Meridian was significantly lower than those of the muscle lateral to and the interspace lateral to ST/GB meridians (P<0.01)ï¼. CONCLUSION: The Ri, Re, ρi and ρe values of the ST and GB meridians are significantly lower than those of their neighboring tissues at the same levels of the lower leg, suggesting a more extracellular fluid in the meridian running course and providing evidence for our speculation that the meridian is a hydraulic resistance channel.
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Meridianos , Puntos de Acupuntura , Vesícula Biliar , Voluntarios Sanos , Humanos , Líquido Intracelular , EstómagoRESUMEN
Qi, blood and the meridians are fundamental concepts in Chinese medicine (CM), which are components of the human body and maintain physiological function. Pathological changes of qi, blood and meridians may lead to discomfort and disease. Treatment with acupuncture or herbal medicine aims to regulate qi and blood so as to recover normal function of the meridians. This paper explores the nature of qi as well as compares and correlates them with the structures of the human body. We propose a conceptualization of qi as being similar to the interstitial fluid, and the meridians as being similar to interstitial space of low hydraulic resistance in the body. Hence, qi running in the meridians can be understood as interstitial fluid flowing via interstitial space of low hydraulic resistance.
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Líquido Extracelular/fisiología , Espacio Extracelular/fisiología , Meridianos , Qi , Agua , Puntos de Acupuntura , Tejido Conectivo/fisiología , HumanosRESUMEN
OBJECTIVE: To lay a foundation for meridian diagnosis by measuring the blood perfusion (BP) on yuan-source points of twelve meridians and calculating the normal range of imbalance degree (IBD) of left and right meridian (IBD-LRM), IBD of exterior-interior meridian (IBD-EIM) and IBD of hand-foot of the same name meridians (IBD-HFM) in healthy subjects. METHODS: BP at yuan-source points of twelve meridians was measured on 31 healthy volunteers by a Laser Doppler Line Scanner (LDLS). BP distribution and IBD-LRM, IBD-EIM, IBD-HFM were calculated. RESULTS: (1) Of the twelve meridians, BP was almost equal between the left and right of the same meridian. The mean value of IBD-LRM was (0.8±7.0)%. The absolute value of IBD-LRM ranged from (13.2±12.0)% to (22.9±15.6)%, with the mean value of (16.2±4.1)%, the IBD of gallbladder meridian of foot-shaoyang was the highest. (2) Of the six pairs of exterior-interior meridians, five pairs manifested as the interior (yin) meridians being larger than the exterior (yang) meridians in BP. The mean value of IBD-EIM was (-11.4±10.4)%. The absolute value of IBD-EIM ranged from (16.6±12.1)% to (36.6±15.6)%,with the mean value of (25.2±8.0)%, the IBD between pericardium meridian of hand-jueyin and triple energizer meridian of hand-shaoyang was the highest. (3)All of the hand-foot of the same name meridians were found hand meridians being larger than foot in BP. The mean value of IBD-HFM was (38.8±18.2)%.The absolute value of IBD-HFM ranged from (34.4±20.9)% to (59.6±12.0)%, with the mean value of (43.8±13.3)%, and IBD between heart meridian of hand-shaoyin and kidney meridian of foot-shaoyin was the highest. (4) The order of IBD absolute value in BP was the same as transcutaneous CO2 emission (TCE) measured before, and their IBD-LRM absolute values were close to each other. However, the absolute values of IBD-EIM and IBD-HFM existed some differences. CONCLUSIONS: The IBD-LRM of the twelve yuan-source points in BP of healthy subjects is small and in a balance state, but IBD-EIM and IBD-HFM are relatively high.