ライフサイエンスコーパス: nutritional deficiency

1 direct (ie, neurotoxicity) or indirect (eg, nutritional deficiency).

2 4200-6300 kJ/d) then to severe (<4200 kJ/d) nutritional deficiency.

3 ction abnormalities, focal direct injury, or nutritional deficiency.

4 onically ill or hospitalized or have a known nutritional deficiency.

5 gh salinity, a stress not directly linked to nutritional deficiency.

6 ns can lead a provider to the diagnosis of a nutritional deficiency.

7 at the cost of occasional protein and other nutritional deficiencies.

8 ith a mild clinical phenotype and infrequent nutritional deficiencies.

9 omised antioxidant defenses as the result of nutritional deficiencies.

10 result in dietary adaptations that may cause nutritional deficiencies.

11 nts with chronic pancreatitis are at risk of nutritional deficiencies.

12 iron deficiency is among the most prevalent nutritional deficiencies.

13 suggested for dietary therapy and to address nutritional deficiencies.

14 from the diet increases the risk of certain nutritional deficiencies.

15 populations that are at risk for developing nutritional deficiencies.

16 an contribute to an increased risk of infant nutritional deficiencies.

17 th problems and the risk of subsequent child nutritional deficiencies.

18 es, fertility, contraception, pregnancy, and nutritional deficiencies.

19 Tuberculosis (TB) often coincides with nutritional deficiencies.

20 d with additional surgical interventions and nutritional deficiencies.

21 st we see increasing evidence of unnecessary nutritional deficiencies.

22 more effective in populations suffering from nutritional deficiencies.

23 with the smallest surgical case volumes were nutritional deficiencies (13), neonatal conditions (204)

24 are to inpatients medically hospitalized for nutritional deficiency, a clinical practice guideline fo

25 Nutritional deficiency, a global problem, remains uncomm

26 Latest estimates indicate that nutritional deficiencies account for 3 million child dea

27 tions in mortality from infectious diseases, nutritional deficiencies and anaemia, diabetes, and card

28 Treatment of nutritional deficiencies and diabetes is an important as

29 ossible explanations for bee decline include nutritional deficiencies and exposures to pesticides and

30 Aging is accompanied by a wide array of nutritional deficiencies and health complications associ

31 ves from evidence showing covariance between nutritional deficiencies and other life stressors.

32 ncomes to understand and address the role of nutritional deficiencies and restricted access to learni

33 atment should be geared toward correction of nutritional deficiencies and study of bone mineral densi

34 ts of therapy, including oral health issues, nutritional deficiencies and the role of physical therap

35 uce metabolic functions that complement host nutritional deficiencies and to induce virulence functio

36 Similarly, nutritional deficiency and certain nutragenomic interact

37 termediate link between fetal and early-life nutritional deficiency and later disease.

38 Third-trimester exposure to severe nutritional deficiency and prenatal exposure to moderate

39 tific information available to demonstrate a nutritional deficiency and/or identify a public health p

40 ation between dietary quality (and potential nutritional deficiencies) and mental health, and for the

41 esistance syndrome, hypertension, associated nutritional deficiencies, and a sedentary lifestyle or a

42 One third of the cases were due to nutritional deficiencies, and one third was due to chron

43 h as modifications of offending medications, nutritional deficiencies, and parvovirus infection.

44 e followed up closely for dietary adherence, nutritional deficiencies, and the development of possibl

45 sible, of any underlying cause, attention to nutritional deficiencies, and the use of antibiotics.

46 ng from the same soil." Fetal and early-life nutritional deficiencies appear to predispose persons to

47 could serve as a modifying factor in thiamin nutritional deficiency as well as when the high affinity

48 The differential diagnoses included nutritional deficiencies, autoimmune disorders, systemic

49 ial proton pump inhibitors (PPIs), including nutritional deficiencies (B12 and magnesium), rebound ac

50 Evidence continues to accumulate that nutritional deficiencies, bacterial, viral and parasitic

51 ree and timing of their prenatal exposure to nutritional deficiency based on their birthdate and birt

52 Infant nutritional deficiencies can influence the development o

53 y goal of this article was to illustrate how nutritional deficiencies can translate into adult or chi

54 There is evidence to support that nutritional deficiency can reduce the body's immune func

55 This article will review the most common nutritional deficiencies causing a periorificial and/or

56 erstanding of the clinical manifestations of nutritional deficiencies comes from old literature; howe

57 Reports of nutritional deficiency continue to surface in developed

58 hronic deficiency of vitamin B12 is the only nutritional deficiency definitively proved to cause opti

59 Throughout the world, the most common nutritional deficiency disorder of infants is iron defic

60 ebral palsy, autism spectrum disorder trait, nutritional deficiency, Down syndrome and Non-specific n

61 therapies to prevent anorexia and concurrent nutritional deficiencies during cancer treatment.

62 Men exposed prenatally to severe maternal nutritional deficiency during the first and/or second tr

63 to explore the mechanisms by which prenatal nutritional deficiency enhances risk for schizophrenia i

64 This syndrome of poverty, nutritional deficiency, fishery dependence, and extrinsi

65 By overcoming this nutritional deficiency, H. subflexa larvae achieve numer

66 weight loss and 58 (72%) showed some type of nutritional deficiency; health-care consumption (hospita

67 ntrol comorbidity, environmental insult, and nutritional deficiency, however, confound the ability to

68 Nutritional deficiencies in adolescence can lead to loss

69 cture and function may result, in part, from nutritional deficiencies in culture media.

70 This review will focus on nutritional deficiencies in obese and postbariatric surg

71 We characterized dietary intake and nutritional deficiencies in patients with diabetic and i

72 Nutritional deficiencies in postbariatric patients alrea

73 lth problem should refocus attention on this nutritional deficiency in Angola and other areas of Afri

74 tial for optimal innate immune function, and nutritional deficiency in either metal leads to increase

75 Iron deficiency (ID) is the most common nutritional deficiency in the world and remains relative

76 Iron deficiency is the most common nutritional deficiency in the world; zinc deficiency is

77 , and although acute interstitial nephritis, nutritional deficiencies (including B12 and hypomagnesem

78 parts of the nonindustrialized world, where nutritional deficiencies, including micronutrients, rema

79 ons target most of the population to prevent nutritional deficiencies, inclusion of genomic criteria

80 a variety of causes, but it may also involve nutritional deficiencies, increased RBC destruction, or

81 Because of the nutritional deficiencies inherent in LC-HP diets and the

82 e pathogens or the effects of pesticides and nutritional deficiencies is the lack of controlled in vi

83 y treatment may prevent the development of a nutritional deficiency is not known.

84 Nutritional deficiency is prevalent in developing countr

85 tries and developing countries, where severe nutritional deficiency is widespread and often exacerbat

86 y; and examination for signs and symptoms of nutritional deficiencies, malignancy, and other autoimmu

87 rature has focused on the relationship among nutritional deficiency, malnutrition and poverty, recent

88 e less able to actively cope with stressors, nutritional deficiencies may accentuate the negative imp

89 st that outbreaks of disease attributed to a nutritional deficiency may actually result from infectio

90 Prenatal nutritional deficiency may play a role in the origin of

91 Many more nutritional deficiencies occurred in the gastric bypass

92 tic criteria (at least two of the following: nutritional deficiency, ocular signs, cerebellar signs,

93 Nutritional deficiency of zinc is widespread throughout

94 tcomes is to first understand the effects of nutritional deficiencies on the mammalian system includi

95 e north and south were subjected to moderate nutritional deficiency only.

96 steine levels, such as those associated with nutritional deficiencies or genetic polymorphisms in the

97 is often one of the first organs affected in nutritional deficiency, providing a key to the diagnosis

98 wth outcomes, health outcomes resulting from nutritional deficiencies, quality of life, mortality, an

99 he alimentary system results in digestive or nutritional deficiencies requiring intervention.

100 a, globe damage due to trauma, infection and nutritional deficiency, retinal disorders, and other con

101 h retinoid receptor null mutants and classic nutritional deficiency studies have demonstrated that re

102 understanding the genetic basis of inherited nutritional deficiencies such as acrodermatitis enteropa

103 s a heterotrophic lifestyle with conspicuous nutritional deficiencies, suggesting the need for metabo

104 Older adults are at greater risk for nutritional deficiencies than are younger adults due to

105 The gastric bypass group experienced more nutritional deficiency than the lifestyle-medical manage

106 bacteria adapt to environmental stresses and nutritional deficiencies through the synthesis and hydro

107 disease, ranging from 131 412 procedures for nutritional deficiencies to 45.8 million procedures for

108 ue suggests numerous diagnoses, ranging from nutritional deficiencies to a myelodysplastic syndrome.

109 liar with the clinical signs and symptoms of nutritional deficiencies to facilitate diagnosis.

110 yndromes to chronic kidney disease, and from nutritional deficiencies to inflammatory processes inclu

111 guidance has changed from the prevention of nutritional deficiencies to the prevention of chronic di

112 e findings of an earlier study that prenatal nutritional deficiency was a determinant of schizophreni

113 ved diabetes control, but adverse events and nutritional deficiencies were more frequent.

114 deficiency and prenatal exposure to moderate nutritional deficiency were not associated with risk for

115 ective CFTR in the intestinal tract leads to nutritional deficiency which in turn contributes to comp

116 and effective, but carries with it long-term nutritional deficiencies, which need to be assessed and

117 ron deficiency is also among the most common nutritional deficiencies worldwide.

118 ts are continuously challenged with combined nutritional deficiencies, yet very little is known about