메탄가스는 주요 온실가스 중 하나로 반추동물의 장내발효를 통해 발생하며, 이러한 경로의 메탄가스는 대한민국 축산부문 총 온실가스 발생량의 40% 이상을 차지한다. 이런 이유로 많은 연구자들은 반추동물에서 발생하는 메탄생성량을 줄이기 위한 시도를 계속해 왔다. 본 연구는 반추동물의 메탄발생량을 측정하기 위해 호흡대사챔버를 개발하고 호흡대사챔버의 정확성을 검증하기 위해 실시하였다. 호흡대사챔버는 25.4 m3 크기로 스테인리 스 플레이트로 내부를 완전히 밀폐하였다. 직경 Φ100의 공기 유입관과 배출관을 설치하였고, 공기 배출관에 에어모터를 설치하여 내부공기를 제거함과 동시에 유입관을 통해 배출된 만큼의 공기가 외부에서 유입되도록 하였다. 챔버 내 메탄가스 회수기능을 검증하기 위해 메탄표준가스 5L를 각 챔버에 주입하여 균일하게 확산시킨 후, 챔버 내부의 공기를 900 L/min의 속도로 제거하였다. 제거된 공기의 메탄가스 농도를 연속적으로 측정하여 주입된 메탄가스와 비교함으로써 회수율을 평가하였다. 챔버 내 표준가스는 평균 100분에 완전히 제거되었으며, 메탄가스의 회수율은 평균 109 ± 6.7%로 측정되었다. 호흡대사챔버의 실제 이용성을 평가하기 위해, 평균체중 581.9 ± 33.8 kg 의 한우 거세우 4두에게 비육후기 배합사료 9 kg과 볏짚 1 kg을 급여하며 메탄발생량을 측정하였다. 한우의 장내발효에 의한 메탄발생량은 평균 236.4 ± 105.44 L/day로 측정되었다. 본 연구에서 개발·검증한 호흡대사챔버는 국내 한우의 장내발효 메탄가스발생량 측정 시험에 적용 가능할 것이다.

It has been now believed and documented that high producing animals can be exploited even best if the heat period expressed in them could be synchronized. Recently, the development in the field of animal science and the introduction of newer technology such as assisted reproductive technology (ART) has immensely rationalized the importance of certain techniques by improvising them in order to benefit the production part from animals. Assisted reproductive technologies have not only benefitted a lot by increasing the production but also by addressing several problems of reproduction failure in farm animals. These technologies have also assisted in improving them and in accelerating genetic improvement among animal population. Techniques such as improved follicular efficiencies, ovum pick up, in vitro embryo production, embryo and semen sexing, somatic cell nuclear transfer and production of transgenic and cloned embryos have been now taken up as cost effective shape in accelerating genetic improvement in animal population and all such technologies have been overviewed and highlighted in this review.

This study was conducted to evaluate natural plant extracts for methane gas reduction in ruminants. Rumen fluid was collected from cannulated Hanwoo cow (450±30 kg) consuming 400 g/kg concentrate and 600 g/kg timothy. The 15 ml of mixture comparing McDougall’s buffer and rumen fluid in the ratio 2 to 1, was dispensed anaerobically into 50 ml serum bottles. Rumen fluid contents were collected and in vitro fermentation prepared control (timothy, 300 mg), ginseng, balloon flower, yucca plant, camellia, tea plant and ogapi extracts were added at the level of 5% against 300 mg of timothy as a substrate (v/w) and incubated for 3, 6, 9, 12, 24, 48, and 72 h. In vitro pH values range 6.55~7.41, this range include rumen titration. The dry matter digestibility was not differ between all treatments and control. Total gas emission was significantly higher (p<0.05) in ginseng and balloon flower treatments on 24 h than in control. Carbon dioxide emission was not differ all treatments on 9 h than in control and significantly higher (p<0.05) yucca plant, camellia and tea plant treatments on 12 h than control. Methane emission was not differ all treatments on 6 h than in control. The rumen microbial growth rate was significantly higher (p<0.05) in ginseng, balloon flower on 12 h and significantly higher (p<0.05) in ginseng, yucca plant, tea plant and ogapi treatments on 24 h than in control. Total VFA was significantly higher (p<0.05) in tea plant and ogapi treatments on 12 h than in control and significantly higher (p<0.05) in ginseng, balloon flower treatments on 48 h than in control. Acetic acid was significantly lower (p<0.05) in ginseng and balloon flower treatments on 24 h than in control. Propionic acid was significantly higher (p<0.05) in ginseng and balloon flower treatments on 48 h than in control. As a results, sixth natural plant extracts had no significant effect dry matter digestibility and negative on rumen fermentation, but not effect methane reduction.