크론병과 궤양성 대장염으로 잘 알려져 있는 염증성 장질환은 재발과 호전을 반복하는 만성적인 염증 및 이에 따른 합병증을 특징으로 하는 원인 불명의 질환이다. 염증성 장질환의 발생 원인은 아직 명확히 알려져 있지 않지만 흡연이나 식이와 같은 환경적 요인, 장내 세균총과 같은 미생물학적 요인, 면역 매개에 의한 조직 손상과 같은 면역학적 요인 그리고 유전학적 요인 등이 복합적으로 발생기전에 관여 할 것이라고 추정한다. 특히 사이토카인과 같은 염증매개물질에 의해 세포매개염증반응의 일련의 과정이 유발 혹은 증폭되거나, 면역 조절 기능의 면화로 장 점막의 국소적 조직 손상을 유발하게 되며 면역 및 염증 반응이 적절하게 감소되지 않고 지속되어 만성 염증에 이르게 된다. 최근 이러한 염증반응에 중요한 역할을 담당하는 사이토카인 유전자에 관심이 몰리고 있다. 사이토카인은 활성화된 면역세포에서 주로 생성되는 당단백으로서 분자량이 8~10 kD 정도이며, 면역 반응시 T세포, B세포, 대식세포 등의 면역세포 상호간에 활성화, 증식 및 분화 등에 관계하여 국소적 조직 손상 및 염증반응을 일으킨다. 반면에 장의 구조와 기능에 있어 중요한 기질인 식이 섬유소에서 유래되는 Butyrate는 친염증성 사이토카인을 감소시키고 항염증성 사이토카인을 증가시킴으로써 장관 면역계에 대한 조절기능을 보이고 있다. 따라서 본 총설에서는 Butyrate의 항염증 효과에 대한 분자적 기작을 면역세포에서 Butyrate가 가지는 사이토카인 조절 능력을 통해 이해하고 Butyrate가 염증성 장질환에 대해 새로운 치료 전략을 제시 해 줄 것으로 기대한다.
크론병과 궤양성 대장염으로 잘 알려져 있는 염증성 장질환은 재발과 호전을 반복하는 만성적인 염증 및 이에 따른 합병증을 특징으로 하는 원인 불명의 질환이다. 염증성 장질환의 발생 원인은 아직 명확히 알려져 있지 않지만 흡연이나 식이와 같은 환경적 요인, 장내 세균총과 같은 미생물학적 요인, 면역 매개에 의한 조직 손상과 같은 면역학적 요인 그리고 유전학적 요인 등이 복합적으로 발생기전에 관여 할 것이라고 추정한다. 특히 사이토카인과 같은 염증매개물질에 의해 세포매개염증반응의 일련의 과정이 유발 혹은 증폭되거나, 면역 조절 기능의 면화로 장 점막의 국소적 조직 손상을 유발하게 되며 면역 및 염증 반응이 적절하게 감소되지 않고 지속되어 만성 염증에 이르게 된다. 최근 이러한 염증반응에 중요한 역할을 담당하는 사이토카인 유전자에 관심이 몰리고 있다. 사이토카인은 활성화된 면역세포에서 주로 생성되는 당단백으로서 분자량이 8~10 kD 정도이며, 면역 반응시 T세포, B세포, 대식세포 등의 면역세포 상호간에 활성화, 증식 및 분화 등에 관계하여 국소적 조직 손상 및 염증반응을 일으킨다. 반면에 장의 구조와 기능에 있어 중요한 기질인 식이 섬유소에서 유래되는 Butyrate는 친염증성 사이토카인을 감소시키고 항염증성 사이토카인을 증가시킴으로써 장관 면역계에 대한 조절기능을 보이고 있다. 따라서 본 총설에서는 Butyrate의 항염증 효과에 대한 분자적 기작을 면역세포에서 Butyrate가 가지는 사이토카인 조절 능력을 통해 이해하고 Butyrate가 염증성 장질환에 대해 새로운 치료 전략을 제시 해 줄 것으로 기대한다.
Inflammatory bowel disease, known as Crohn's disease and ulcerative colitis, is an unexplained disease characterized by chronic inflammation that repeats a cycle of relapse, improvement, and complications. The cause of inflammatory bowel disease is not clearly known, but it is predicted that a compl...
Inflammatory bowel disease, known as Crohn's disease and ulcerative colitis, is an unexplained disease characterized by chronic inflammation that repeats a cycle of relapse, improvement, and complications. The cause of inflammatory bowel disease is not clearly known, but it is predicted that a complex of various factors precipitate its occurrence. In particular, inflammatory mediators, such as cytokine, induce an increase in cell-mediated inflammatory responses. Focal tissue damage then occurs in the intestinal mucosa because of the weakening of the immune-modulating functions of cotton. Immune and inflammatory responses do not decrease appropriately but continue until they lead to chronic inflammation. Current research has focused on the cytokine genes, which have important roles in these inflammatory responses. Cytokine is a glycoprotein that is produced mostly in activated immune cells. It connects the activation, multiplication, and differentiation between immune cells, which causes focal tissue damage and inflammatory response. Moreover, butyrate, which originates in dietary fiber and plays an important role in the structure and function of the intestinal area, shows control functions in the intestinal immune system by decreasing the proinflammatory cytokine and increasing the anti-inflammatory cytokine. Therefore, this research investigated the molecular mechanism of the anti-inflammatory effects of butyrate to comprehend the cytokine controlling abilities of butyrate in the immune cells. Butyrate is expected to have potential in new treatment strategies for inflammatory bowel disease.
Inflammatory bowel disease, known as Crohn's disease and ulcerative colitis, is an unexplained disease characterized by chronic inflammation that repeats a cycle of relapse, improvement, and complications. The cause of inflammatory bowel disease is not clearly known, but it is predicted that a complex of various factors precipitate its occurrence. In particular, inflammatory mediators, such as cytokine, induce an increase in cell-mediated inflammatory responses. Focal tissue damage then occurs in the intestinal mucosa because of the weakening of the immune-modulating functions of cotton. Immune and inflammatory responses do not decrease appropriately but continue until they lead to chronic inflammation. Current research has focused on the cytokine genes, which have important roles in these inflammatory responses. Cytokine is a glycoprotein that is produced mostly in activated immune cells. It connects the activation, multiplication, and differentiation between immune cells, which causes focal tissue damage and inflammatory response. Moreover, butyrate, which originates in dietary fiber and plays an important role in the structure and function of the intestinal area, shows control functions in the intestinal immune system by decreasing the proinflammatory cytokine and increasing the anti-inflammatory cytokine. Therefore, this research investigated the molecular mechanism of the anti-inflammatory effects of butyrate to comprehend the cytokine controlling abilities of butyrate in the immune cells. Butyrate is expected to have potential in new treatment strategies for inflammatory bowel disease.
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제안 방법
Sensitivity analyses were also performed to assess the stability of the results.
Studies included in this meta-analysis had to meet the following criteria: (1) a case-control or cohort design; (2) an evaluation of the associations between XRCC1 Arg399Gln, Arg194Trp, Arg280His polymorphisms and DTC risk; and (3) presentation of sufficient genotype data to estimate the odds ratio (OR) and 95% confidence interval (CI).
이론/모형
When I2 was less than 50%, the studies were considered to have acceptable heterogeneity and the fixed-effects model with the Mantel-Haenszel method was used.
성능/효과
After careful examination, we found that the fixed effects model was used to calculate the result of the ethnicity analysis (Asian) in Arg399Gln polymorphism in Table 2 in their study, however due to the I2>50%, they should apply the random effects model, thus the right result should be [1.56 (0.63-3.86) for the aa vs AA, I2=63.1%; 1.50 (0.64-3.51) for the recessive model, I2=59.2%].
In conclusion, this meta-analysis demonstrated that the XRCC1 Arg194Trp polymorphism might be a risk factor for DTC.
The strength of the associations between DTC and XRCC1 polymorphisms was estimated using ORs with corresponding 95% CIs.
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