ライフサイエンスコーパス: epidemic disease

1 y and mortality, capable of causing periodic epidemic disease.

2 nitude of interventions necessary to control epidemic disease.

3 s animal models have been used to study this epidemic disease.

4 . coli strains associated with severe and/or epidemic disease.

5 s over the role of governments confronted by epidemic disease.

6 mpose a far higher public health burden than epidemic disease.

7 ggests additional adaptation is required for epidemic disease.

8 cholera, Snow extended the inference to all epidemic diseases.

9 g, traffic engineering and the mitigation of epidemic diseases.

10 ertoires, yet crop monocultures are prone to epidemic diseases.

11 left the population more vulnerable to novel epidemic diseases.

12 and outdoor air toxics (n = 21), new or rare epidemic diseases and unexplained syndromes (n = 29), na

13 Yet, a rich, broader scholarship on race and epidemic disease as a "sampling device for social analys

14 mprove the diagnosis of priority endemic and epidemic diseases, as well as strengthen the overall del

15 During seasonal influenza epidemics, disease burden is shouldered predominantly by

16 Epidemic disease can spread during mass gatherings.

17 Pertussis is an epidemic disease caused by Bordetella pertussis and also

18 incidence of naturally occurring endemic or epidemic diseases during hostilities.

19 nt starch (e.g., amylase copy number) and to epidemic diseases evolved as human populations expanded

20 Multiple epidemic diseases have been designated as emerging or re

21 stinal pathogen Vibrio cholerae still causes epidemic disease in areas of the world where there is po

22 Densoviruses cause lethal epidemic disease in invertebrates, including shrimp, coc

23 However, this virus can cause epidemic disease in poultry, and concerns about the pote

24 paramyxoviruses, airborne agents that cause epidemic diseases in animals including humans.

25 , family Bunyaviridae) causes mosquito-borne epidemic diseases in humans and livestock.

26 It has proven possible to eradicate epidemic diseases, often without the availability of vac

27 This requires extensive sampling of epidemic disease over time, alongside the background of

28 es until they too were overfished or died of epidemic diseases related to overcrowding.

29 ce static or deteriorating animal health and epidemic diseases show both regression and expansion.

30 fics, which has fundamental implications for epidemic disease spread and animal sociality.

31 tructed for investigating the dynamics of an epidemic disease such as the COVID-19 pandemic.

32 Shortages of vaccines for epidemic diseases, such as cholera, meningitis, and yell

33 Influenza is an uncontrolled epidemic disease that is vaccine preventable.

34 rmore, our framework can be useful for other epidemic diseases that also feature asymptomatic spreadi

35 dily expanded from its original grounding in epidemic disease to describe a vast array of processes t

36 e been extensively studied in the context of epidemic disease transmission, the role of gatherings in

37 Because rubella is a highly epidemic disease, vigilance will be required to assure c

38 ra outbreak as the basis for his belief that epidemic diseases were transmitted by water, not air.

39 rapid identification of emerging respiratory epidemics, diseases with epidemic potential, their speci