ライフサイエンスコーパス: colitis-associated cancer

1 stinal inflammation and delayed the onset of colitis-associated cancer.

2 and its absence promotes the development of colitis-associated cancer.

3 al epithelial cells (IEC) during colitis and colitis-associated cancer.

4 factor for colorectal cancer, also known as colitis-associated cancer.

5 imed to establish the miRNAs associated with colitis-associated cancer.

6 e (AOM) and dextran sulfate sodium to induce colitis-associated cancer.

7 lates certain proapoptotic RNAs to attenuate colitis-associated cancer.

8 ride (LPS), is over-expressed in humans with colitis-associated cancer.

9 on that may predispose to the development of colitis-associated cancer.

10 ntly upregulated in cohorts of patients with colitis-associated cancer.

11 strongly associated with the development of colitis-associated cancer.

12 olonic mucosa and tumors in a mouse model of colitis-associated cancer.

13 nduced colitis, and severe susceptibility to colitis-associated cancer.

14 ablished a key function for PHB in mediating colitis-associated cancer.

15 mmatory intestinal diseases, such as IBD and colitis-associated cancer.

16 seful therapeutic target in the treatment of colitis-associated cancer.

17 for tr-NK-1R in malignant transformation in colitis-associated cancer.

18 hogenesis of inflammatory bowel diseases and colitis-associated cancer.

19 ell hypothesis has not yet been validated in colitis-associated cancer.

20 es of dextran sodium sulfate (DSS) to induce colitis-associated cancer.

21 ease treatment and define novel mediators of colitis-associated cancer.

22 be useful in the prevention or treatment of colitis-associated cancer.

23 ing through TLR4 may lower the threshold for colitis-associated cancer.

24 nt of intestinal inflammation, infection and colitis-associated cancer.

25 ute colitis, type 2 intestinal infection and colitis-associated cancer.

26 was analyzed in acute colitis, infection and colitis-associated cancer.

27 rget against inflammatory diseases including colitis-associated cancer.

28 20 (CCL20), and increased susceptibility to colitis-associated cancer.

29 lead to new strategies to identify and treat colitis-associated cancers.

30 myeloid cells contributes to development of colitis-associated cancer and Apc(Min)-dependent intesti

31 These mice were bred with Apc(Min/+) mice; colitis-associated cancer and colitis were induced by ad

32 capacity of the test to distinguish between colitis-associated cancer and different ulcerative colit

33 hes to manipulate IDO1 activity in mice with colitis-associated cancer and human colon cancer cell li

34 dence for their roles in the pathogenesis of colitis-associated cancer and sporadic colorectal cancer

35 important insights into the pathogenesis of colitis-associated cancer and suggest that epidermal gro

36 nd germline alterations in 174 patients with colitis-associated cancers and sequenced 29 synchronous

37 of colorectal cancer gave rise to the term "colitis-associated cancer" and the concept that inflamma

38 arthritis, inflammatory intestinal disease, colitis-associated cancer, and lipopolysaccharide (LPS,

39 lammatory signature' genes characteristic of colitis-associated cancer are also upregulated in colore

40 d to exacerbated intestinal inflammation and colitis-associated cancer, but also helped protect again

41 linked to pre-existing inflammation known as colitis-associated cancer, but most develops in patients

42 Here we established a novel mouse model of colitis-associated cancer by genetically inactivating si

43 vation appears to promote the development of colitis-associated cancer by mechanisms including enhanc

44 r findings suggest that PHB protects against colitis-associated cancer by modulating p53- and STAT3-m

45 e intestine, where it helps protects against colitis-associated cancer by regulating HMOX-1 expressio

46 K1) links chronic intestinal inflammation to colitis-associated cancer (CAC) and both are exacerbated

47 myeloid AC protects from tumor incidence in colitis-associated cancer (CAC) and inhibits the expansi

48 Using an autochthonous model of colitis-associated cancer (CAC) and sporadic cancer, we

49 modulates inflammatory signals and promotes colitis-associated cancer (CAC) in mice.

50 Colitis-associated cancer (CAC) is a complication of inf

51 Colitis-associated cancer (CAC) is a major complication

52 creased tumor development in an experimental colitis-associated cancer (CAC) model.

53 fic IKKbeta is involved in the initiation of colitis-associated cancer (CAC), as in its absence mice

54 ling pathway are associated with colitis and colitis-associated cancer (CAC), but how IL-33 modulates

55 trast, MyD88-deficient mice are sensitive to colitis-associated cancer (CAC), since selected cytokine

56 Using a well-established model of colitis-associated cancer (CAC), we found that mice gene

57 evels render IBD patients susceptible to the colitis-associated cancer (CAC).

58 nd proliferation of tumor cells in mice with colitis-associated cancer (CAC).

59 Here, we investigated the role of SPL in colitis-associated cancer (CAC).

60 microenvironment plays a significant role in colitis-associated cancer (CAC).

61 intestinal inflammation (i.e., colitis) and colitis-associated cancer (CAC).

62 ease increases the risks of colon cancer and colitis-associated cancer (CAC).

63 f intestinal homeostasis, leading to IBD and colitis-associated cancer (CAC).

64 xymethane (AOM)/dextran sodium sulfate (DSS) colitis-associated cancer (CAC).

65 rses crypt architectural changes and reduces colitis-associated cancer (CAC).

66 e networks drive intestinal inflammation and colitis-associated cancer (CAC).

67 atory bowel disease (IBD) are susceptible to colitis-associated cancer (CAC).

68 PURPOSE OF REVIEW: Human colitis-associated cancers (CAC) represent a heterogeneo

69 miR-375 was significantly upregulated in the colitis-associated cancer cohort (p=0.0061) compared wit

70 response in sepsis, intestinal colitis, and colitis-associated cancer development through NLRP3-infl

71 mmation and contributes to the prevention of colitis-associated cancer during chronic inflammation th

72 Molecular mechanisms specific to colitis-associated cancers have been poorly characterize

73 antly attenuated intestinal inflammation and colitis-associated cancer in dextran sodium sulfate mode

74 mation increases the risk for development of colitis-associated cancer in IBD patients.

75 ce significantly inhibits the progression of colitis-associated cancer in the AOM/DSS model.

76 Conversely, in a mouse model of colitis-associated cancer, in which mice are exposed to

77 in colon cancer, however, the implication in colitis-associated cancer is unknown.

78 In contrast, in a colitis-associated cancer model combining azoxymethane a

79 SAMe or MTA treatment in the colitis-associated cancer model lowered total beta-caten

80 Using a colitis-associated cancer model, we show that although d

81 idence of tumors compared with controls in a colitis-associated cancer model.

82 of dysplasia and adenocarcinomas in a murine colitis-associated cancer model.

83 sis, we used Nlrp1b(-/-) mice in colitis and colitis-associated cancer models.

84 s (ulcerative colitis, n=37; dysplasia, n=2; colitis-associated cancer, n=6).

85 ions, an early and highly recurrent event in colitis-associated cancers, occur in half of dysplasia,

86 expression was lost in carcinoma tissues of colitis-associated cancer patients, whereas p65 expressi

87 MCC levels in IEC increase in colitis and colitis-associated cancer patients.

88 critical role for ITF2 in the repression of colitis-associated cancer progression and ITF2 would be

89 ression of beta-catenin target genes in CUC, colitis-associated cancer, tubular adenomas, and sporadi

90 lear translocation of p65 and thus increased colitis-associated cancer tumorigenesis, which was media

91 dministration of dextran sodium sulfate, and colitis-associated cancer was induced by administration

92 Using two mouse models of colitis-associated cancer, we found that epidermal growt