ABSTRACT
<b>Introduction</b> : Intravenous rt-PA therapy for acute ischemic stroke patients within 4.5 hours after onset is approved and effective, but is difficult to implement in depopulated areas because of geographical conditions and lack of medical specialists.<br><b>Methods</b> : From February 2013 to February 2014, 75 acute ischemic stroke patients were transferred to our hospital, four (5.3%) of which were subjected to the “drip and ship” method of rt-PA infusion using a telemedicine system for emergency medicine (k-support). We examined the time course after onset and the treatment outcome of these four cases<br><b>Results</b> : Four cases had rt-PA infusion started in the depopulated area. ln one case, recanalization of occluded vessels was demonstrated resulting in improved clinical symptoms. <br><b>Conclusion</b> : The “drip and ship” method of rt-PA infusion using a telemedicine system for emergency medicine (k-support) may be a safe and ideal treatment in depopulated areas.
ABSTRACT
<b>Objectives: </b>Radon (<sup>222</sup>Rn) is a noble gas found in the water of hot spring spas (“onsen”). In Japan, the Hot Springs Law and the Guideline of Analytical Methods of Mineral Springs (revised) classify springs containing 74 Bq/kg of radon as “hot springs” and those with levels exceeding 111 Bq/kg as “medical springs”, also called “radioactive springs”. According to the notification article (the Nature Conservation Bureau of the Ministry of the Environment in Japan), bathing in a radioactive springs may alleviate the effects of gout, arteriosclerosis, and hypertension as well as chronic conditions such as cholecystitis, gallstones, and skin and gynecological diseases. Drinking water from these springs may treat gout, chronic digestive disorders, chronic cholecystitis, gallstones, neuralgia, muscle pain, and arthralgia. To determine exposure doses from radioactive springs, it is important to establish an easy and accurate method of measuring radon concentration in water and humid air in bathing areas.<BR><b>Methods: </b>This study measured the concentration of airborne radon using an activated charcoal detector (PICO-RAD: AccuStar Labs), desiccant (Drierite; 8 mesh of anhydrous calcium sulfate: W.A. Hammond Drierite Company, Ltd.), a liquid scintillation counter (LSC LB-5: Hitachi Aloka Medical, Ltd.), and 2,5-diphenyloxazole(DPO) + 1,4-bis (5-phenyl-2-oxazolyl) benzene(POPOP) toluene solution (Wako Pure Chemical Industries, Ltd.) were used as the liquid scintillator.<BR><b>Results and Conclusions: </b>This study evaluated radon exposure doses due to radioactive spring at a spa in Komono town, Mie prefecture. After water was piped from hot spring storage tanks into bathtubs, only 5.3-18.0% of the radon remained in the water. Two days later, only 0.25% remained, likely due to radioactive decay and increased diffusion into the air from bathing and recirculating filters. Thus, we investigated radon levels in the humid bathroom air around the radioactive hot spring and determined the total radon exposure from spa water and air. The total exposure dose was calculated assuming a two-day stay, during which customers used the bath for some number of hours. Our findings confirm the safety and efficacy of the hot spring facility. This study was supported in part by a grant from the Daido Life Welfare Foundation.
ABSTRACT
<b>Objectives:</b> Radon (<sup>222</sup>Rn) is a noble gas and a component of water in many hot spring spas. The Hot Springs Law and the Guideline of Analytical Methods of Mineral Springs (revised edition) of Japan classify springs containing 74 Bq/kg or more of radon as “hot springs” and those with radon levels exceeding 111 Bq/kg as “medical springs”, also called “radioactive springs”. Komono Town, one of the foremost spa and health resort destinations in Mie Prefecture, is the site of many radioactive springs. For the purpose of regional vitalization of this area through radioactive springs, it is necessary to confirm the safety and effectiveness of their use. To evaluate the exposure dose due to radioactive spring usage, it is important to measure radon concentration in air, especially in high-humidity air such as in bathing rooms.<BR><b>Methods:</b> The concentration of radon in air was analyzed using an activated charcoal detector (PICO-RAD; AccuStar Labs) with a desiccant (Drierite; 8-mesh anhydrous calcium sulfate; W.A. Hammond Drierite Company, Ltd.) and a liquid scintillation counter (LSC LB-5; Hitachi Aloka Medical, Ltd.). A DPO (2,5-diphenyloxazole) + POPOP (1,4-bis- (5-phenyl-2-oxazolyl)-benzene) toluene solution (Wako Pure Chemical Industries, Ltd.) was used as a liquid scintillator. Activated charcoal detectors were set up in and around the radioactive spring facilities. <BR><b>Results and Discussion:</b> In a radioactive spring facility, radon concentration in air in the bathing room and changing room were relatively high at about 50 Bq/m<sup>3</sup>. In the corridor on all floors and at the entrance, these values were approximately 10-30 Bq/m<sup>3</sup>, indicating that radon in hot spring water diffuses into the air and spreads within the facility. Outdoors, radon concentration was 12.5 Bq/m<sup>3</sup> at a campsite near the discharge point of the radioactive spring.<BR> Exposure dose is calculated under the assumption of a two-day stay, during which the visitor will use the bath for several hours. The results obtained show that the exposure dose at the hot spring facility is lower than the exposure dose from daily environmental radiation or medical devices. These conclusions are considered sufficient to confirm the safety of the hot spring facility.
ABSTRACT
Objectives: Radon (222Rn) is a noble gas and a component of water in many hot spring spas. The Hot Springs Law and the Guideline of Analytical Methods of Mineral Springs (revised edition) of Japan classify springs containing 74 Bq/kg or more of radon as “hot springs” and those with radon levels exceeding 111 Bq/kg as “medical springs”, also called “radioactive springs”. Komono Town, one of the foremost spa and health resort destinations in Mie Prefecture, is the site of many radioactive springs. For the purpose of regional vitalization of this area through radioactive springs, it is necessary to confirm the safety and effectiveness of their use. To evaluate the exposure dose due to radioactive spring usage, it is important to measure radon concentration in air, especially in high-humidity air such as in bathing rooms. Methods: The concentration of radon in air was analyzed using an activated charcoal detector (PICO-RAD; AccuStar Labs) with a desiccant (Drierite; 8-mesh anhydrous calcium sulfate; W.A. Hammond Drierite Company, Ltd.) and a liquid scintillation counter (LSC LB-5; Hitachi Aloka Medical, Ltd.). A DPO (2,5-diphenyloxazole) + POPOP (1,4-bis- (5-phenyl-2-oxazolyl)-benzene) toluene solution (Wako Pure Chemical Industries, Ltd.) was used as a liquid scintillator. Activated charcoal detectors were set up in and around the radioactive spring facilities. Results and Discussion: In a radioactive spring facility, radon concentration in air in the bathing room and changing room were relatively high at about 50 Bq/m3. In the corridor on all floors and at the entrance, these values were approximately 10-30 Bq/m3, indicating that radon in hot spring water diffuses into the air and spreads within the facility. Outdoors, radon concentration was 12.5 Bq/m3 at a campsite near the discharge point of the radioactive spring. Exposure dose is calculated under the assumption of a two-day stay, during which the visitor will use the bath for several hours. The results obtained show that the exposure dose at the hot spring facility is lower than the exposure dose from daily environmental radiation or medical devices. These conclusions are considered sufficient to confirm the safety of the hot spring facility.
ABSTRACT
Objectives: Radon (222Rn) is a noble gas found in the water of hot spring spas (“onsen”). In Japan, the Hot Springs Law and the Guideline of Analytical Methods of Mineral Springs (revised) classify springs containing 74 Bq/kg of radon as “hot springs” and those with levels exceeding 111 Bq/kg as “medical springs”, also called “radioactive springs”. According to the notification article (the Nature Conservation Bureau of the Ministry of the Environment in Japan), bathing in a radioactive springs may alleviate the effects of gout, arteriosclerosis, and hypertension as well as chronic conditions such as cholecystitis, gallstones, and skin and gynecological diseases. Drinking water from these springs may treat gout, chronic digestive disorders, chronic cholecystitis, gallstones, neuralgia, muscle pain, and arthralgia. To determine exposure doses from radioactive springs, it is important to establish an easy and accurate method of measuring radon concentration in water and humid air in bathing areas. Methods: This study measured the concentration of airborne radon using an activated charcoal detector (PICO-RAD: AccuStar Labs), desiccant (Drierite; 8 mesh of anhydrous calcium sulfate: W.A. Hammond Drierite Company, Ltd.), a liquid scintillation counter (LSC LB-5: Hitachi Aloka Medical, Ltd.), and 2,5-diphenyloxazole(DPO) + 1,4-bis (5-phenyl-2-oxazolyl) benzene(POPOP) toluene solution (Wako Pure Chemical Industries, Ltd.) were used as the liquid scintillator. Results and Conclusions: This study evaluated radon exposure doses due to radioactive spring at a spa in Komono town, Mie prefecture. After water was piped from hot spring storage tanks into bathtubs, only 5.3-18.0% of the radon remained in the water. Two days later, only 0.25% remained, likely due to radioactive decay and increased diffusion into the air from bathing and recirculating filters. Thus, we investigated radon levels in the humid bathroom air around the radioactive hot spring and determined the total radon exposure from spa water and air. The total exposure dose was calculated assuming a two-day stay, during which customers used the bath for some number of hours. Our findings confirm the safety and efficacy of the hot spring facility. This study was supported in part by a grant from the Daido Life Welfare Foundation.
ABSTRACT
We previously reported that in patients with Alzheimer’s disease (AD), the number of baths that patients report taking at their first evaluation at a memory clinic was significantly decreased in comparison to before the onset of dementia. Based on this research, we thought further longitudinal evaluation was needed regarding the relationship between the number of baths, cognitive impairment and depression state after AD progression. In the present study, we reevaluate the number of baths; cognitive function tests (Hasegawa’s Dementia Scale-Revised [HDS-R], Mini Mental State Examination [MMSE] and Wechsler Adult Intelligence Scale-Revised [WAIS-R]); and the depression assessment (Zung Self-rating Depression Scale [SDS]) 1 year after first evaluation.<BR> At the first evaluation, the average number of baths taken by 65 AD patients (16 male, 49 female; range: 64-90 years, average: 79.5±5.6 years), was 5.6±1.6 bathsweek. At the reevaluation, this number had decreased to 4.9±1.9 bathsweek. In the WAIS-R, a significant positive correlation was found between the score change in number of baths and the change in performance intelligence quotient (PIQ) and total intelligence quotient (TIQ). However, no significant correlation was found between the score change in number of baths and the change in HDS-R, MMSE, or verbal intelligence quotient in WAIS-R or SDS.<BR> We further evaluated the present series by dividing the study population into two subtypes: a group of patients in which the number of baths decreased 1 year after the first evaluation, and a group in which there was no change. There were no significant differences in background factors (e.g. average age at first evaluation) between the groups. Although, no significant difference was observed between the groups in number of baths before dementia onset (both were 6.7 timesweek), a significant difference was found at the first evaluation (5.3 bathsweek vs 5.9 bathsweek, respectively). No significant differences were observed between the groups in cognitive function test or depression assessment at the first evaluation. However, on reevaluation the group with the decreased number of baths showed significantly lower PIQ and TIQ scores in WAIS-R and a significantly higher SDS score.<BR> The results of the present study suggested that number of baths decreased along with the progression of AD and the greatest participating factor was the practical dysfunction reflected by the PIQ score in WAIS-R. Furthermore, we considered the existence of two subtypes: patients in whom the number of baths decreases with AD progression and those in whom there is no change.
ABSTRACT
We previously reported that in patients with Alzheimer’s disease (AD), the number of baths that patients report taking at their first evaluation at a memory clinic was significantly decreased in comparison to before the onset of dementia. Based on this research, we thought further longitudinal evaluation was needed regarding the relationship between the number of baths, cognitive impairment and depression state after AD progression. In the present study, we reevaluate the number of baths; cognitive function tests (Hasegawa’s Dementia Scale-Revised [HDS-R], Mini Mental State Examination [MMSE] and Wechsler Adult Intelligence Scale-Revised [WAIS-R]); and the depression assessment (Zung Self-rating Depression Scale [SDS]) 1 year after first evaluation. At the first evaluation, the average number of baths taken by 65 AD patients (16 male, 49 female; range: 64-90 years, average: 79.5±5.6 years), was 5.6±1.6 bathsweek. At the reevaluation, this number had decreased to 4.9±1.9 bathsweek. In the WAIS-R, a significant positive correlation was found between the score change in number of baths and the change in performance intelligence quotient (PIQ) and total intelligence quotient (TIQ). However, no significant correlation was found between the score change in number of baths and the change in HDS-R, MMSE, or verbal intelligence quotient in WAIS-R or SDS. We further evaluated the present series by dividing the study population into two subtypes: a group of patients in which the number of baths decreased 1 year after the first evaluation, and a group in which there was no change. There were no significant differences in background factors (e.g. average age at first evaluation) between the groups. Although, no significant difference was observed between the groups in number of baths before dementia onset (both were 6.7 timesweek), a significant difference was found at the first evaluation (5.3 bathsweek vs 5.9 bathsweek, respectively). No significant differences were observed between the groups in cognitive function test or depression assessment at the first evaluation. However, on reevaluation the group with the decreased number of baths showed significantly lower PIQ and TIQ scores in WAIS-R and a significantly higher SDS score. The results of the present study suggested that number of baths decreased along with the progression of AD and the greatest participating factor was the practical dysfunction reflected by the PIQ score in WAIS-R. Furthermore, we considered the existence of two subtypes: patients in whom the number of baths decreases with AD progression and those in whom there is no change.
ABSTRACT
The present study aimed to investigate how nutritional status affected iron status, and how this knowledge might be used to prevent anemia in rhythmic gymnasts prior to a competition. We divided twenty-one subjects according to their iron status in just prior to competition into either an iron-deficiency group (n=12) and a non-iron-deficiency group (n=9), the latter of which represented the normal group. Iron-deficiency group was defined as a hemoglobin concentration below 12g/dl, a ferritin level below 12ng/ml and/or a transferrin saturation ratio under 16%. Physical, hematological, and nutritional assessments were made using a semi-quantitative food frequency questionnaire, once at 2 months before a competition, and once more just prior to the competition (‘pre-competition’).1) The iron-deficiency group had significantly lower body weight, body mass index and body fat at pre-competition compared to 2 months before the competition.2) Compared to the normal group, the iron-deficiency group had significantly lower serum iron and haptoglobin concentrations at the pre-competition.3) Intakes of energy, protein, iron, and vitamin C at the pre-competition were 1965±340kcal, 68.0±14.0g, 11.2±3.2mg, and 76±30mg in the normal group, and 1620±456kcal, 53.8±18.0g, 11.6±4.1mg, and 75±29mg in the iron-deficiency group, respectively. There was no significant difference in intakes of energy, protein, iron, and vitamin C between the groups, respectively.4) Pre-competition protein intakes per body weight (BW) were 1.46±0.33g and 1.08±0.31g in the normal group and the iron-deficiency group, respectively. Those levels were significantly lower in the iron-deficiency group than those in the normal group.5) Pre-competition protein energy ratio (13.9±1.6%) and animal protein ratio (56.0±6.7%) of the normal group were significantly higher than those measured 2 months before the competition. Conversely, those ratios remained constant for 2 months in the iron-deficiency group.6) Changes in the protein energy ratio and/or the animal protein ratio between the pre-competition and the 2 months before were significantly correlated with the pre-competition Hb levels.We conclude that the pre-competition iron status is closely associated with protein intakes in female collegiate rhythmic gymnasts.
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The purpose of the present study is to investigate protein metabolism during rapid weight reduction. Six male boxing players put on a restricted diet of their own accord for two weeks. Body weight changes were observed and a biochemical analysis was made of their urine and blood. The initial body weight of 66.1±3.0kg (mean±SE) decreased to 63.6±3.2 kg after two weeks (P<0.01) . The changes in lean body mass (LBM) by weight reduction were not significant, but the LBM tended to decrease after two weeks. The mean caloric intake was 2, 791±728 kcal before the study and 1, 643±548 kcal after two weeks. The reduction of carbohydrate consumption is much more than that of fat and protein consumption. The 3-Me/Cr in urine increased significantly after two weeks (348.1 ± 37.0 μol/g to 508.1 f 45.6 μmol/g, P<0.01) and the increase of Urea-N/Cr in urine (8.4±0.5mg/mg creatinine to 13.7±1.3mg/mg creatinine, P<0.01) was also significant after two weeks. Urine volume decreased significantly after two weeks (P<0.01) . There was no significant difference in the blood components during the weight reduction period. These results might suggest that rapid weight reduction and massive decrease of carbohydrate intake accelerate protein catabolism.