ライフサイエンスコーパス: digestive system

1 ate normal functions and pathobiology in the digestive system.

2 eep time may also belong to cells within the digestive system.

3 CCK)-A and CCK-B, mediate CCK effects in the digestive system.

4 a life-threatening disorder of the lungs and digestive system.

5 us, such as the smooth-muscle actions of the digestive system.

6 fiber that is not digested in the mammalian digestive system.

7 ses in its capacity as the first part of the digestive system.

8 eptide digestion and absorption in the human digestive system.

9 oesophagus and other narrow orifices in the digestive system.

10 oted Treg accumulation within lesions of the digestive system.

11 ammation, and carcinogenesis of cells of the digestive system.

12 ly transported and metabolized by the larval digestive system.

13 contributing to the form and function of the digestive system.

14 rve cords, photoreceptors, and the posterior digestive system.

15 lular plasticity within adult tissues of the digestive system.

16 uman tumor types, especially in those of the digestive system.

17 and spleen as well as several tissues of the digestive system.

18 in the development of mammalian nervous and digestive systems.

19 of which 12 kg would be absorbed into mussel digestive systems.

20 erves as a common opening to the urinary and digestive systems.

21 skin (31%), prostate (15%), melanoma (13%), digestive system (10%), kidney (4%), thyroid (4%), breas

22 tem (39.1%); trauma (10.2%); diseases of the digestive system (9.7%); pulmonary diseases (9.0%); infe

23 Cancers originating from the digestive system account for 290,000 or ~20% of all new

24 digestive tract, resulting in loss of proper digestive system acidification.

25 cular similarities in the development of the digestive system across species, we hypothesized that th

26 s such as behavioral and neurological AE and digestive system AE.

27 addition to its well established role in the digestive system, also play a role in peripheral vitamin

28 the nervous system, liver, skin, lungs, and digestive system, among others.

29 iew of its relative abundance throughout the digestive system and its apparent regulation by calcium-

30 E1 genes from Caniformia, which has a simple digestive system and lacks microbial digestion typical o

31 MCO1 is located on the basal surfaces of the digestive system and Malpighian tubules.

32 esults broaden the current knowledge of tick digestive system and may lead to the discovery of potent

33 n between developmental specification of the digestive system and one of its most basic functions, re

34 on factor SKN-1 initiates development of the digestive system and other mesendodermal tissues.

35 re likely to have died from disorders of the digestive system and suicide.

36 Herbivores possess diverse microbes in their digestive systems and these microbial symbionts can modi

37 eria, protists, invertebrates, the mammalian digestive system, and other fungi can pose challenges to

38 Additionally, certain tissues (mesoderm, digestive system, and tracheal system) required more tha

39 tGFP line, that expresses GFP throughout the digestive system, and use this tool to analyze the devel

40 nary system anomalies, 83.2% (79.8-86.0) for digestive system anomalies, 97.6% (95.9-98.6) for orofac

41 ncer, associations with other cancers of the digestive system are poorly established.

42 rvival within the hostile environment of the digestive system are the adhesins SabA and BabA; these m

43 y be because immunological, neurological and digestive systems are still developing.

44 cs demonstrates the utility of the planarian digestive system as a model for elucidating the mechanis

45 tworms, which have only one opening to their digestive system, as the sister group to all remaining B

46 ematopoietic cancers and malignancies of the digestive system, brain, breast, and ovary.

47 ion within Teredinidae, the reduction of its digestive system by comparison with other family members

48 physical activity were associated with lower digestive system cancer risk (hazard ratio [HR], 0.74 fo

49 ted the role of physical activity in overall digestive system cancer risk.

50 stones and cholecystectomy may be related to digestive system cancer through inflammation, altered bi

51 mately 2-3 cups/d) had a 21% reduced risk of digestive system cancers combined (HR: 0.79; 95% CI: 0.6

52 tea) was associated with reduced risk of all digestive system cancers combined (HR: 0.86; 95% CI: 0.7

53 of tea consumption with the incidence of all digestive system cancers in Chinese women.

54 After a mean follow-up of 11 y, 1255 digestive system cancers occurred (stomach, esophagus, c

55 k, was inversely associated with the risk of digestive system cancers, particularly digestive tract c

56 exercise was particularly beneficial against digestive system cancers, with the optimal benefit obser

57 24 person-years, we documented 1370 incident digestive system cancers.

58 at common carcinogenic pathways may underlie digestive system cancers.

59 ntake (>/=3 times/wk for >6 mo) with risk of digestive system cancers.

60 a protective role for tea in the etiology of digestive system cancers; however, results from prospect

61 Urinary tract infection and digestive system complications were also common readmiss

62 ome compositional variations reveal that the digestive system consists of multiple, longitudinally he

63 The mucosal lining of the respiratory and digestive systems contains the largest and most complex

64 Despite descriptions of the ctenophore digestive system dating to Agassiz [16] that identify tw

65 ssible explanations for the craniofacial and digestive system defects observed in humans with mutatio

66 Digestive system development is orchestrated by combinat

67 Together, these data define aspects of digestive system development necessary for the character

68 modifications, we used a dynamic artificial digestive system (DIDGI(R)) that mimics the physicochemi

69 hol problems were associated with death from digestive-system disease, drug misuse with mental and be

70 e radial nerve cords, circumoral nerve ring, digestive system (e.g., cardiac stomach) and body wall-a

71 Incident cancer of the digestive system encompassing the digestive tract (mouth

72 During organogenesis of the C. elegans digestive system, epithelial cells within a cyst-like pr

73 f which showed predominant expression in the digestive system (FABP1, FABP2, FABP6, FABP10, RBP1, and

74 otential to harvest energy directly from the digestive system for powering a future wireless endoscop

75 cting the dynamic processes of the mammalian digestive system for this hydrophobic organic contaminan

76 vely little is known about how the zebrafish digestive system forms.

77 that neurotrophins play a broad role in the digestive system from development through adult life, pe

78 have brilliant GFP fluorescence: the entire digestive system from tongue to anus; the male and femal

79 the prostate, lung (nonsmall cell), breast, digestive system, gynecological, urinary system, or head

80 logous gene family (a major component of the digestive system in D. pulex ) could explain why fitness

81 rved gene involved in the development of the digestive system in many animals, has an important role

82 participate in the building of a functional digestive system in metazoans, and genetic conditions in

83 de-offs between the cost and capacity of the digestive system in response to resource pulses: rare, e

84 doderm generate a highly ordered, multiorgan digestive system in vertebrate animals.

85 an-specific functions of SPs and KLFs in the digestive system including the oral cavity, esophagus, s

86 xpression in tissues other than those of the digestive system, including muscle and the central nervo

87 Bacteria play many important roles in animal digestive systems, including the provision of enzymes cr

88 Some data suggest digestive system involvement.

89 s account for the finding that the zebrafish digestive system is assembled from individual organ anla

90 bout how cells in the brain and possibly the digestive system keep time.

91 Despite the essential functions of the digestive system, much remains to be learned about the c

92 Here we investigated stem-cell death in the digestive system of adult Drosophila melanogaster.

93 Although the development of the digestive system of humans and vertebrate model organism

94 ails in the laboratory, probably because the digestive system of infected snails is compromised by C.

95 f ~65 kDa, present in the body periphery and digestive system of infective larvae (L3), as demonstrat

96 e in vivo levels of serotonin release in the digestive system of intact zebrafish embryos during earl

97 ns was dissolved from ingested Cu NPs in the digestive system of isopods.

98 udy we report that analysis of ESTs from the digestive system of Limnoria quadripunctata reveals a tr

99 rhythms play a major role in regulating the digestive systems of many organisms.

100 e assessment of load:capacity ratios for the digestive systems of predators in the wild, compiling 63

101 assiz [16] that identify two openings of the digestive system opposite of the mouth-called "excretory

102 r lymphohematopoietic cancers, melanoma, and digestive system, prostate, kidney, and brain cancers.

103 esophagus, like other luminal organs of the digestive system, provides a potential environment for b

104 Vertebrate and invertebrate digestive systems show extensive similarities in their d

105 ented soymilk storage and after the in vitro digestive system simulation (DSS).

106 s increased significantly after the in vitro digestive system simulation of the product.

107 ovel microbial communities within the oyster digestive system, the functions of the oyster microbiome

108 ur results demonstrated that exposure of the digestive system to H5N1 influenza viruses could initiat

109 getic trade-offs by rapidly modulating their digestive system to track variation in foraging opportun

110 n radial nerve cords, circumoral nerve ring, digestive system, tube feet and innervation of interossi

111 es of the respiratory (including asthma) and digestive systems (VA), and diverse symptom diagnoses (V

112 erlying UFP-mediated lipid metabolism in the digestive system with clinical relevance to gut homeosta

113 assic examples of circadian variation in the digestive system, with an emphasis on rhythms in cell pr

114 internal organs of early arthropods only the digestive system withstands fossilization is challenged

115 ood uptake after injury, degeneration of the digestive system would often occur indicating limited en