스트레스 자극에 대한 심혈관계 및 교감신경계 과활성화 반응은 향후 심혈관계 질환 발생 및 심장 돌연사의 위험을 증가시킨다. 음악 청취는 자율신경계 기능을 향상시켜 안정 시 긴장 이완을 유도하 는 것으로 알려져 있으나 음악이 스트레스 상황에서의 과도한 심혈관 반응을 완화 시킬 수 있는지에 대한 연구는 부족하다. 본 연구는 음악청취가 스트레스 자극에 대한 심혈관 반응성을 완화시켜 줄 수 있을지 검 증하였다. 15명의 건강한 성인(남자 9명, 여성 6명)을 대상으로 무작위 교차 실험 설계로 진행하였다. 음악 처치는 음악을 30분간 청취하였고 통제 처치는 30분간 휴식을 취하였다. 냉압박 검사로 교감신경계를 자극 하였으며, 변인으로 심박수, 상완 및 중심동맥 혈압과 심박변이도(heart rate variability)를 측정하였다. 연 구 결과, 음악 처치와 통제 처치 모두 냉압박 검사 중 심박수와 혈압 반응이 유의하게 증가하였으나(p < .001), 처치와 시기 간 상호작용 효과는 유의하지 않았다. 회복 구간에서 상완동맥 수축기혈압이 음악처치 그룹에서만 유의하게 감소하였다(p = 0.008). 나머지 혈압 변인들도 음악중재 그룹에서 더 완화되는 경향이 나타났으나 통계적으로 유의하지는 않았다. 심박변이도는 음악 처치 전후로 음악 처치 그룹에서만 SDNN(standard deviation of the NN intervals), TP(total power)와 HF(high frequency)값이 유의하게 증 가하였다(p = 0.001, p = 0.002, p = 0.011). 따라서 음악 청취는 스트레스 이후의 회복력을 촉진시킬 가능 성이 있다. 음악 처치의 구체적인 변인들을 고려하여 과도한 심혈관 반응에 대한 보호 효과로서의 음악 청 취에 대한 추가적인 연구가 필요하다.
PURPOSES : In this study, the alkali aggregate reactivity and expansion characteristics of mortar mixed with waste glass (a recycled aggregate) were confirmed to verify the alkali-silica reaction (ASR) stability and review the appropriateness of the alkali aggregate reactivity test method following the replacement of recycled aggregate.
METHODS : The alkali-aggregate reactivity of waste glass aggregates was measured using the chemical and physical methods described in KS F 2545 and ASTM C 1260, respectively. The reactivity was classified by comparing the results. Cement with a high-alkali content was used to simulate an environment that can induce ASR. Non-reactive fine aggregates, waste glass fine aggregates, reactive general aggregates, and Ferronickel slag aggregates were used as control groups.
RESULTS : Waste glass fine aggregates were classified as reactive when applying the chemical method. In the physical method, they were classified as reactive at 100% and latent reactive at 1%, based on the mixing ratio. Additionally, we discovered that the reliability of the chemical method was low since the ASR of the aggregates was classified differently based on the evaluation method, while the results of the chemical and physical test methods were inconsistent.
CONCLUSIONS : To determine the alkali reactivity of recycled aggregates, the complex use of chemical and physical methods and analysis based on the mixing ratio of the reactive aggregates are required. Small amounts of waste glass aggregate replacements affected the ASR. Because ASR reaction products can affect the long-term thermal expansion of the structure, further research is needed to use ASR aggregates in structures.
The reactivity evaluation of copper is performed using ethylenediamine, aminoethanol, and piperidine to apply organic chelators to copper etching. It is revealed that piperidine, which is a ring-type chelator, has the lowest reactivity on copper and copper oxide and ethylenediamine, which is a chain-type chelator, has the highest reactivity via inductively coupled plasma-mass spectroscopy (ICP-MS). Furthermore, it is confirmed that the stable complex of copper-ethylenediamine can be formed during the reaction between copper and ethylenediamine using nuclear magnetic resonance (NMR) and radio-thin layer chromatography. As a final evaluation, the copper reactivity is evaluated by wet etching using each solution. Scanning electron micrographs reveal that the degree of copper reaction in ethylenediamine is stronger than that in any other chelator. This result is in good agreement with the evaluation results obtained by ICP-MS and NMR. It is concluded that ethylenediamine is a prospective etch gas for the dry etching of the copper.
Various semi-cokes were obtained from medium–low-temperature pyrolysis of Shenmu long flame coal. The combustion characteristic index and CO2 gasification reactivity of semi-cokes were measured and analyzed using thermogravimetry analysis. The influence of particle size on CO2 gasification reactivities of these semi-cokes was studied. In addition, the Brunauer–Emmett–Teller surface area (SBET), carbon material structure order and carbon crystalline structure were examined by N2 adsorption, Raman spectroscopy and powder X-ray diffraction. All of these properties were used to evaluate the CO2 gasification reactivity of these semi-cokes. The results show that the gasification reactivity of semi-cokes decreases with an increasing crystallinity and structure order. Surface area of the pores is proportional to the reactivity of the semi-coke; the greater the surface area, the faster the gasification reaction rate.
PURPOSES: The object of this study is to select appropriate inorganic materials, and find the best mixing formula to secure fast curing time and enough initial strength, and then to evaluate the durability of the asphalt mixtures according to the degree of addition of the compound manufactured by the determined blending ratio.
METHODS : The breaking time and reactivity between seven kinds of inorganic minerals, and the selected recycled aggregate and emulsified asphalt were compared to determine the best initial curing strength for the mixtures. Then, three inorganic materials were chosen as the materials that provide good breaking time and reactivity, and the best mixing formula for the three materials was determined. The chemical composition of the compound manufactured using the mixing formula was analyzed by energy dispersive x-ray system method. Finally, indirect tensile strength (ITS) test was performed (for two days) at room temperature to determine the proper amount of additives that will provide the best initial strength.
RESULTS: From the results of the reactivity test, the best mixing formula (A:C:G = 60:30:10) for the three selected inorganic materials with short braking time and high reactivity was determined. The four types of cold reclaimed asphalt mixtures for ITS testing were manufactured by adding the inorganic material compounds at 0%, 3%, 5%, and 7%, and the ITS values were measured after two curing days. The ITS values at 5% and 7% were 0.308 MPa and 0.415 MPa, respectively. The results of quality control tests (Marshall stability, porosity, flow value, etc.) at 5% and 7% satisfied the specification criterion for the cold recycled asphalt mixtures.
CONCLUSIONS : The selected inorganic materials (A, C, and G) and the best mixing formula (A:C:G = 60:30:10) accelerated the reaction with emulsified asphalt and shortened the curing time. Depending on the inorganic material used, the breaking time and reactivity can be directly related or unrelated. This is because of the chemical compositions of recycled aggregates, infiltrated foreign matter, and chemical reactions between the inorganic materials and other materials. Therefore, it is important to select the proper materials and the best mixing formula when evaluating the characteristics of the practically used materials such as recycled aggregates, inorganic materials, and emulsified asphalt.
The purpose of this study is to set the method condition of the DPRA in Korea throughout reproducibility study. We conducted intra-lab (triplicate) and inter-lab (three labs of CRI, KTR and CU) validation using 20 chemicals (10 chemicals for the proficiency test listed in the OECD test guideline 442C and an additional 10 more chemicals from reference papers). The data from all three labs met the acceptance criteria. Upon intra-lab validation, two positive chemicals out of 20 total chemicals showed false negative, and one negative chemical showed false positive. In inter-lab validation of three labs, the sensitivity data were 83, 83 and 88% each, and the specificity data was 100, 100 and 88% each. So the accuracy of the three labs was equal to 90%. During these studies, we also checked and improved various limitations that arose. Taken together, the results indicated that the DPRA proposed by OECD test guideline 442C is expected to become a well-established method under Korean GLP applied system.
To understand how reactivity between reinforcing nanoparticles and aqueous solution affects electrodeposited Cu thin films, two types of commercialized cerium oxide (ceria, CeO2) nanoparticles were used with copper sulfate electrolyte to form in-situ nanocomposite films. During this process, we observed variation in colors and pH of the electrolyte depending on the manufacturer. Ceria aqueous solution and nickel sulfate (NiSO4) aqueous solutions were also used for comparison. We checked several parameters which could be key factors contributing to the changes, such as the oxidation number of Cu, chemical impurities of ceria nanoparticles, and so on. Oxidation number was checked by salt formation by chemical reaction between CuSO4 solution and sodium hydroxide (NaOH) solution. We observed that the color changed when H2SO4 was added to the CuSO4 solution. The same effect was obtained when H2SO4 was mixed with ceria solution; the color of ceria solution changed from white to yellow. However, the color of NiSO4 solution did not show any significant changes. We did observe slight changes in the pH of the solutions in this study. We did not obtain firm evidence to explain the changes observed in this study, but changes in the color of the electrolyte might be caused by interaction of Cu ion and the by-product of ceria. The mechanical properties of the films were examined by nanoindentation, and reaction between ceria and electrolyte presumably affect the mechanical properties of electrodeposited copper films. We also examined their crystal structures and optical properties by X-ray diffraction (XRD) and UV-Vis spectroscopy.
동맥경화 상태에서는 혈관이 수축물질에 예민하게 반응 함으로써 혈압의 급격한 변화에 대한 회복능력이 저하한다. 한편 뽕나무 잎에는 고지방식의 섭취로 인해 발생하는 동맥경화증의 발달을 감소시킬 가능성이 있는 여러 물질이 있다고 추정된다. 뽕나무 잎을 백서에 투여하면 고지 방식에 의해 유발된 혈관이 예민해지는 현상을 감소시킬 수 있는지 시험하기 위하여 고지방식 및 뽕나무잎을 8주 간 투여하고 혈관수축 물질에 대한 혈압의 반응성을 시험 하였다. 순환기반사에 따른 혈압반응 감수성차이를 최소화 할 목적으로 동물의 중추신경계를 파괴(pithing)하고 시험 하였다. 고콜레스테롤을 함유한 식이를 공급한 백서에서 교감신경계 전기자극이나 norepinephrine, phenylephrine, angiotensin II 및 vasopressin 등의 투여로 유발된 혈압상승반응이 증강되었으며, 사료에 뽕잎을 2% 또는 10% 첨 가하면 정상적인 혈압상승반응을 보여주었다. 교감신경계를 파괴하지 않은 채 마취만 한 백서에서는 고콜레스테롤에 의한 반응증강이나 뽕잎에 의한 변화를 관찰할 수 없었다. 이 결과로 부터 뽕잎이 동맥경화에서 나타나는 혈관반응성 변화를 방지하는 데 유용한 것으로 판단할 수 있을 것이다.
Free-radical copolymerization of glycidyl methacrylate(GMA) and N-phthalimidoethyl acrylate(NPEA) were carried out at 60℃ in dimethylformamide(DMF) solution in the presence of benzoylperoxide(BPO) at low conversion. The polymers were characterized by IR and 1H-NMR. The compositions of the copolymer was analyzed by ultra violet(UV/Vis) spectrophotometry. The reactivity ratios of the monomer was determined by the application of Fineman-Ross(FR) and Kelen-Tudos(KT) methods. The monomer reactivity ratios of the system and Alfrey-Price's resonance effect(Q) and polar effect(e) value for NIEA were determined as follow. The reactivity ratios of the monomer obtained from FR and KT are found to be r1=0.87, r2=0.98 and r1=0.88, r2=0.99 respectively. The Q and e values of poly(GMA-co-NPEM) calculated from r1 and r2 was Q= 1.31, e=0.75 respectively.
PURPOSES: The purpose of this study is to compare the alkali-silica reactivity for mortar bar and concrete prism specimens using crushed aggregates of 5 types in Korea. And the alkali-silica reactivity for those aggregates are measured by chemical test method. METHODS: The alkali-silica reactivity for those aggregates was measured by chemical test method of KS F 2545, mortar-bar test of KS F 2546, accelerated mortar-bar test method of ASTM C 1260 and concrete prism test method of ASTM C 1293, relatively. RESULTS: The alkali-silica reactivity for those aggregates was verified by chemical test of KS F 2546 and accelerated mortar-bar test of ASTM C 1260. However, it was not by mortar-bar test of KS F 2546 and concrete prism test of ASTM C 1293. CONCLUSIONS: The above results showed that relationship among the four test methods were very low. The results from 3 types of test methods using cement-aggregate combinations appeared to be different. Because the environmental conditions of test methods for measuring the alkali-silica reactivity such as equivalent alkali content(external source), humidity, temperature, and times were different though the aggregates were same. Moreover, alkali-silica reactivity showed the biggest impact when alkalis were supplied form outside and exposed to environmental conditions. The accelerated mortar-bar test method seems to be most appropriate test method for concrete structures exposed to alkali environment.
본 연구에서는 정서 유발 프로토콜을 이용하여 유발된 다섯 가지 정서(기쁨, 슬픔, 분노, 스트레스와 무료함)에 따른 아동의 심혈관계 반응의 차이를 밝히고자 하였다. 아동에게 음악, 색채, 심상을 유발하는 이야기, 인형으로 구성된 복합자극을 제시하는 동안 이들의 심혈관계 반응을 측정하고, 자극에 대한 적합성(유발된 정서의 유형)과 효과성(유발된 정서의 강도)을 정서평가척도 상에 평정하도록 하였다. 분석에 사용된 심혈관계 생리반응 변수는 심박수, 호흡주기 관련 심박률 변화, 심박률 분산, 심박률 분산의 고주파수 성분, 저주파수 성분과 혈류량이었다. 연구 결과, 스트레스 유발하는 자극을 제외한 네 가지 정서 유발 자극은 아동에게 각 정서(기쁨, 슬픔, 분노와 무료함)를 적절하고 효과적으로 유발시킨 것으로 나타났다. 또한 호흡주기 관련 심박률 변화를 제외한 모든 심혈관계 지표에서 정서에 따른 유의한 차이가 나타났다. 정서에 따라 특징적인 심혈관계 반응이 나타났으며, 이는 심혈관계 반응을 이용하여 아동정서를 구분하는 것이 가능함을 의미한다.
Li reacts with N2 at room temperature. In order to activate Li, the mechanical milling of Li with stable metal oxide, namely, Al2O3 and MgO, using a high energy vibrating ball mill was performed. In the case of Li-MgO system, it reacts with N2, but hardly reacts with O2. The reaction with N2 generally produces Li3N, while for some vigorous reactions the Mg3N2 is produced as the major phases. In the case of Li-Al2O3 system, reactivities with both N2 and O2 are high. The difference is explained in terms of the reaction mechanism and the Li state.