In Korea, groundwater is main water source in livestock farms. Most dairy and cattle farms have constructed their own wells for human drinking and livestock farming. However, these private residential wells have not been controlled by government and also there was scant study about livestock drinking water quality. Therefore this study was to monitor of the livestock farms' groundwater quality in Korea. Water samples were collected at 123 dairy and cattle farms and were analysed forty six substances with quality standard for drinking water approved by the Minister of Environment. Seventy eight (63.4%) of 123 samples failed to drinking water stand a test. The most frequent contaminants were nitrate-nitrogen and microbial. 22.8% (n = 28) of samples showed nitrate-N concentration of higher than 10 mg/L meant that can't be used drinking water for human and the Nitrate-N concentration analysed in the range of 0.2 to 61.2 mg/L. All of 78 failed to drinking samples had microbial problems, especially 5.7% (n = 7) of samples indicated water could be contaminated by feces. Other contaminants detected were zinc and evaporation residue. Especially detected zinc concentration (32 mg/L) was about ten times higher than standard of zinc (3 mg/L). Regression analysis indicated that groundwater pH did not influence to nitrate-N concentration but the hardness and chloride could affect to nitrate-N concentration in the groundwater. Most livestock farms were adjacent to crop farmland in Korea. This could cause contamination of groundwater with nitrate-N and pesticide that could accumulate livestock product. Moreover Heavy metal such as zinc and copper could be released from a corrosive plated water pipe in livestock farm. Put together, Korea livestock system is indoor, not pasture-based, hence livestock could be exposed to potential contaminated water consistently. Therefore on the basis of these data, appropriate livestock drinking water quality standards should be prepared to keep livestock healthy and their product safe. Further, livestock drinking water quality should be monitored continuously in suitable livestock drinking water standards.
Animals ; Cattle ; Copper ; Drinking ; Drinking Water ; Feces ; Groundwater ; Hardness ; Humans ; Hydrogen-Ion Concentration ; Korea ; Livestock ; Organothiophosphorus Compounds ; Water ; Zinc

Interest in the correction of jaw deformities has increased due to the development of techniques and instruments of jaw operation. The accurate position of the mandibular foramen and lingula is important for the prevention of the complications and successful inferior alveolar nerve block. This study was conducted on 104 dried mandibles (65 males, 39 females) from Korean cadaver. The positions of the mandibular foramen and lingula were measured on the coronoid notch, occlusal plane, mandibular notch, gonion, koronoid and kondylion. The structures of the mandibular foramen and lingula were determined and the thickness of ramus and the angle of mandible were measured. Independent t-tests and paired t-tests were performed to determine the statistically significant difference. The results as follows; The line between coronoid notch and posterior border of ramus was located on the same level with the tip of lingula in 42.2% of the cases, and in between the mandibular foramen and the tip of lingula in 33.8% of the cases. The occlusal plane was located on the level between the mandibular foramen and the tip of lingula in 47.7% of cases, and on the same level with the tip of lingula in 35.6% of the cases. The line between lower end of the mandibular notch to inferior border of the mandible, in parallel to the posterior border of the mandibles, met the tip of lingula in 55.8% of the cases. The mandibular foramen was located posteriorly to the midpoint on the anteroposterior (AP) width of the ramus. It was located at 57.3% of AP width from the coronoid notch and 56.5% from the occlusal plane. The mandibular foramen and the tip of lingula were located superiorly to the midpoint on the vertical height of the ramus, on the 48.5% and 35.7% of vertical distance from the coronoid notch, respectively. The mandibular foramen was located at 40% of the length on the line from the gonion to the koronion. The results of this study will provide important morphometric information to prevent the complications in mandibular surgery and also provide the basis for the development of the new techniques.
Cadaver ; Congenital Abnormalities ; Dental Occlusion ; Humans ; Jaw ; Male ; Mandible ; Mandibular Nerve