ライフサイエンスコーパス: bacterial spore

1 the dormancy, robustness, and germination of bacterial spores.

2 n order of magnitude greater inactivation of bacterial spores.

3 rs to characterize the germination of single bacterial spores.

4 e compromised the long-term stability of the bacterial spores.

5 binary complex is best for the detection of bacterial spores.

6 nd gold particles and Clostridium sporogenes bacterial spores.

7 dipicolinic acid (DPA), a major component of bacterial spores.

8 c acid (DPA), which is a marker molecule for bacterial spores.

9 o-germinant and is also a germinant for most bacterial spores.

10 se materials are readily differentiated from bacterial spores.

11 ionizing compounds directly in bacteria and bacterial spores.

12 designed synthetic polymers with engineered bacterial spores.

13 ole-cell biosensing systems that is based on bacterial spores, a dormant form of life.

14 rovide an interpretation of the mechanics of bacterial spores and can help in developing synthetic ma

15 e in exposure media was in the size range of bacterial spores and crystal toxins.

16 Bacterial spores are dormant cells that are encased in a

17 Dormant bacterial spores are encased in a thick protein shell, t

18 Dormant bacterial spores are extraordinarily resistant to enviro

19 Bacterial spores are extremely resistant to environmenta

20 Bacterial spores are problematic in agriculture, the foo

21 Bacterial spores are protected from the environment by a

22 Bacterial spores are remarkable in their resistance to c

23 Bacterial spores are resistant to a wide range of chemic

24 Bacterial spores are surrounded by a morphologically com

25 Bacterial spores are surrounded by a multilayered protei

26 Bacterial spores are the most resistant form of life kno

27 Airborne contaminants, e.g., bacterial spores, are usually analyzed by time-consuming

28 nt of all the mass peaks in the spectra from bacterial spores, as presented in this work, establishes

29 by detecting the evanescent scattering from bacterial spores at the sensor surface.

30 Here, we develop and detect an artificial bacterial spore--B. globigii (BG) Bugbead-a particle mim

31 enhanced in the presence of a gram-positive bacterial spore, Bacillus globigii (Bg), which serves as

32 iously demonstrated the capability to detect bacterial spores based on the Raman spectrum of the char

33 e dielectrophoresis to manipulate individual bacterial spores between the electrodes.

34 Optimal detection of bacterial spores by PCR requires that the spores be disr

35 The outermost proteinaceous layer of bacterial spores, called the coat, is critical for spore

36 Bacterial spores can remain dormant for decades yet rapi

37 A recent study explains how bacterial spores capture and protect phage DNA, which re

38 The bacterial spore cortex is critical for spore stability a

39 y and demonstrate significant improvement in bacterial spore detection.

40 omer produced in vivo upon UV irradiation of bacterial spore DNA.

41 Dormant bacterial spores do not take up and bind nucleic acid dy

42 to capture Bacillus subtilis var. niger (BG) bacterial spores driven to the surface.

43 Bacterial spores (endospores), such as those of the path

44 y study evaluated the safety and efficacy of bacterial spores for preventing recurrent CDI.

45 form, which suggests a common mechanism with bacterial spores for protecting DNA in the most adverse

46 Starvation triggers bacterial spore formation, a committed differentiation p

47 to an unconventional production process of a bacterial spore-forming anaerobic challenge agent is an

48 However, several aspects of the exit of bacterial spores from dormancy, i.e., the germination of

49 Dormant bacterial spores germinate to become vegetative cells up

50 Bacterial spores have outstanding properties from the ma

51 Bacterial spore heat resistance is primarily dependent u

52 ation was employed to enhance sensitivity of bacterial spore immunoassay detection, specifically, enz

53 state of the science in the inactivation of bacterial spores in a decontamination scenario, further

54 Bacterial spores in a metabolically dormant state can su

55 y of sterilization by iHP was assessed using bacterial spores in biological indicator assemblies.

56 d with optical trapping to probe and analyze bacterial spores in solution.

57 n and hydrophobicity, constrain dispersal of bacterial spores in the environment.

58 The unusual UV resistance of bacterial spores is a result of the unique photochemistr

59 The dormant state of bacterial spores is generally thought to be devoid of bi

60 tolesion in the DNA of UV-irradiated dormant bacterial spores is the thymine dimer 5-thyminyl-5,6-dih

61 ntigen-like molecules, and furthermore, that bacterial spores modulate host immunity.

62 ound for 3 min gave a detection limit for BG bacterial spores of 1 x 10(3) spores/mL.

63 Bacterial spores of various Bacillus species are imperme

64 icated microfluidic devices for detection of bacterial spores on the basis of enhancement of the emis

65 o detect and discriminate between individual bacterial spores on the basis of their electrical respon

66 n principle be formed upon UV irradiation of bacterial spores, only the 5R configuration is possible

67 and subtilin in its ability to inhibit both bacterial spore outgrowth and vegetative growth.

68 Bacterial spores owe their incredible resistance capacit

69 on in mammalian hosts includes inhalation of bacterial spores, phagocytosis of spores in the nasal mu

70 agnetostrictive sensors for the detection of bacterial spores, proteins, and classical swine fever.

71 Bacterial spores remain dormant and highly resistant to

72 Bacterial spores resist antibiotics and sterilization an

73 ytical method to detect residual agar from a bacterial spore sample as an indication of culturing on

74 solubilization of agar polysaccharide from a bacterial spore sample, enzymatic digestion, followed by

75 Sonication of bacterial spores to obtain measurements of released nucl

76 us microbiota and commonly fail to eradicate bacterial spores, two key factors that allow recurrence

77 hundred to 19 050 can be desorbed from whole bacterial spores using infrared laser desorption and no

78 classes of pathogens (virus, protein toxins, bacterial spores, vegetative cells).

79 The detection of bacterial spores via dipicolinate-triggered lanthanide l

80 n addition, detection of Bacillus atrophaeus bacterial spores was improved by the use of Tb(DO2A)(+),

81 Single bacterial spores were analyzed by using nonlinear Raman

82 ective TB antigens onto the surface of inert bacterial spores, which are then delivered to the respir

83 om culture on agar plates in the presence of bacterial spores with a limit of detection of approximat

84 reagentless detection and identification of bacterial spores with no false positives from a complex

85 picolinic acid (DPA), a major constituent of bacterial spores, with greater affinity and demonstrate