성인과 달리 소아의 경우 인지능력과 의사전달이 정확하지 않아 X선 검사에 있어 심리적 불안감으로 인한 움 직임은 재검사를 증가시키는 요인 중 하나이다. X선 검사라는 거부감을 최소화하고 의료 서비스의 만족도를 향 상하기 위한 방법으로 검사실의 환경을 개선하여 심리적 안정에 도움을 주어 검사과정에서 발생하는 불필요한 재 검사를 비롯한 피폭선량 절감에 긍정적인 방안을 알아보고자 하였다. 실험대상으로는 2017년 5월부터 2017년 8월 까지 본원 일반촬영실에서 만 6개월 이상∼만 36개월 미만의 총 186명의 소아를 대상으로 청각과 시각적 환경변 화를 모두 적용시키지 않는 평소 검사실을 A 군, 시각적 환경변화는 제외시키고 청각적 환경변화만 적용한 검사실을 B 군, 청각적 환경변화는 제외시키고 시각적 환경변화만 적용한 검사실을 C 군, 청각과 시각적 환경변화를 모두 적용한 검사실을 D 군으로 설정하여 연구를 진행하였다. A 군에서는 재검사 건수가 10 건, B 군 7건, C 군 5건, D 군 2건의 결과를 도출할 수 있었다. 특히 A 군과 D 군에서 통계학적 유의수준 p<0.053으로 유의 하다는 결과를 얻을 수 있었다. 결론적으로 청각과 시각적 환경변화가 소아 심리적 안정에 많은 영향을 미쳤으며, 재검사 건수도 감소하여 의료서비스의 질적 향상 보였다.

This study was carried out in order to observe how the bay sediment would be changed with microbial treatments and a chemical oxidant like CaO2. The sediment during the treatments was analyzed in terms of pH, ORP, volatile organics content, COD, AVS, T-N, and T-P. With CaO2 treatment, pH was kept over 9.66 and ORP ranged from +4.70～+46.0, which meant an aerobic state meanwhile with the microbial treatment those were worse. In addition the chemical treatment showed better environmental index values than the microbial one: volatile organics content and COD values in the former were 12.9% and 37.9% while those in the latter were 4.5% and 18.7%, respectively. AVS and T-P were 71.1% and 100% versus 56.5% and 85.8%, respectively. However, the microbial treatment was better for T-N(66% higher). On the other hand, both treatment at a time enhanced all the environmental indices but COD meantime pH and ORP values were lower than with the chemical treatment only. Thus additional input of an oxygen generator like CaO2 could improve the environmental state of a bay sediment where the biological treatment is going on.

The problem of supply and transport of sediment from a mountainous catchment is very important in explaining dynamic geomorphology and the hydrological cycle. The discharge of suspended sediment is determined by a morphological system. Human interference to environment is also an important, not negligible factor in sediment production. Moreover, growing concern in recent years for the problems of nonpoint pollution and for the transport of contaminants through terrestrial and aquatic ecosystem,; has highlighted the role of sediment-associated transport in fluvial systems. This study was conducted in forested and quarried catchments in order to clarify the different discharge process and the mechanism of suspended sediment dynamics for each catchment. As a forested catchment, the Yamaguchi River catchment which drains a 3.12 ㎢ area was chosen. On the other hand, the Futagami River basin, which is formed by three subbasins (1.07, 1.59 and 1.78 ㎢), as a quarried catchment was selected. These catchments are situated to the north and east of Mt. Tsukuba, Ibaraki, Japan. The discharge pattern of suspended sediment from the Futagami River basin is more unstable and irregular than that from forested catchment, the Yamaguchi River catchment. Under the similar rainstorm conditions, suspended sediment concentration from quarried catchment during a rainstorm event increases from 43 to 27,310㎎/l. However, in the case of the forested catchment it changes only from nearly zero to 274 ㎎/l. Generally, the supply source of suspended sediment is classified into two areas, the in-channel and non-channel source areas. As a result of field measurements, in the case of the forested catchment the in-channel (channel bed, channel bank and channel margin) is the main source area of suspended sediment. On the other hand, remarkable sediment source area on the quarried catchmen, is the non-channel that is unvegetated ground.