장미 속은 오랜 시간에 걸쳐 잡종화, 배수화 및 육종 등을 통해 약 250개의 종과 30,000여 품종이 존재하는 진화 역사를 가지고 있으며, 다양한 분류체계로 구분되고 있다. 이에, 본 연구 는 장미 속 자원의 다양성을 평가하고 자생식물 해당화의 육종적 활용을 위해 수행되었다. 장미 속 자원의 형태학적 다양성을 확인하기 위해 장미 속 자원 303점에 대해 형태적 특성조사를 실시하고 해당화 및 장미 속 자원 29점을 선발하여 SSR 분석을 실시하였다. 추가적으로, 해당화의 육종적 활용을 위한 자원 6점 을 선발하고 화분 검정을 실시하였다. 본 연구의 결과, 장미 속 자원 303점의 다양성 평가 결과에서 유사한 형태적 특징을 지닌 자원끼리 7개 그룹으로 나뉘었다. 선발된 29개 자원의 형태학적 데이터와 분자학적 데이터를 이용한 군집 분석 결과, 데이터의 유사성을 보인 자원끼리 각각 5개, 4개 그룹으로 구분되었다. 또한, 혼합분석 시에는 3개 그룹으로 확인되었다. 분류 결과를 바탕으로 자생 식물을 이용한 정원장미 육종을 위해 각각 특성이 다른 해당화를 3점 선발하였고 장미 속 자원에 속하는 정원 장미 3점을 선발하여 총 6자원을 선발하였다. 선발된 자원의 화분 검정 결과, 종간 교잡체를 제외한 5가지 자원에서 90% 이상의 정상화분율을 확인하였다. 본 결과는 자생식물 해당화를 재평가 하고 정원 장미 육종 전략 수립에 도움이 될 것으로 기대된다.

In 2018, media reports raised issues related to radon released from building materials used as finishing materials in apartment houses. Accordingly, related ministries recommended not to use materials with a radiation index value exceeding 1. In order to calculate the radioactivity index, not only 226Ra producing radon (222Rn) but also 232Th and 40K radioactivity concentrations are required. To determine the concentration of the radionuclide, 40K is measured by a single gamma ray of 1,460.8 keV. And the 228Ac used to measure 232Th mainly utilizes gamma rays of 911.2 keV. However, 228Ac does not appear as a single peak unlike 40K, and appears as multiple peaks at various energies. Among them, gamma rays are emitted at a intensity of 0.83% at 1,459.2 keV, which is likely to interfere with 40K. Therefore, what is actually measured at 1,460.8 keV is theoretically a compound peak of 40K and 228Ac. Because the probability of emission at 1,459.2 keV (0.83%) is low, a low concentration of 232Th will result in little 40K radioactivity error. However, samples containing a high concentration of 232Th overestimate the 40K radioactive concentration, so correction is required. In this study, the IAEA standard substance (IAEA-RGTh-1) ontaining 232Th of actual high concentration was analyzed, and the results of the analysis without correction of 40K were compared and verified. As the 40K correction method, the 911.2 keV gamma-ray of 228Ac was used as the reference peak to separate the peak of 228Ac (1,459.2 keV) from the 40K (1,460.8 keV) mixed peaks. And, the coefficient value obtained by subtracting the peak of 228Ac (1,459.2 keV) from the 40K (1,460.8 keV) mixed peak was set to a pure peak of 40K and the radioactivity concentration was calculated therefrom. As a result of calculating the IAEA-RGTh-1 reference material without correction, it was confirmed that the 40K value was overestimated by about 38 times. If a measurement beyond the MDA of 40K is generated by 228Ac radioactivity because the 40K correction constant is not applied, there is an error in determining that there is 40K radioactivity. However, even if 40K radioactivity is overestimated due to the high concentration of 232Th, the degree to which this effect contributes to the radioactivity index is very small. However, as an analyst, 40K radioactivity correction should be made for more accurate analysis.

The discovery of antibiotics has helped to save the lives of an uncountable number of people. Antibiotics have been grouped in different classes based on their origin, structure, and mechanism of action. An intrinsic and acquired mechanism of antimicrobial resistance has been identified in many bacterial strains that are of high clinical importance. This has seriously jeopardized the use of antibiotics and has also caused the spread of microbes that are resistant to effective first-choice, or “first-line” drugs. Thus, sensible use of antibiotics and the search for effective alternative measures are of high importance in order to minimize the effect due to existing and emerging antimicrobial resistant microbes.