ライフサイエンスコーパス: collateral damage

1 are at the crux of these toxic effects, or "collateral damage".

2 omiscuous cleavage of nearby RNAs (so-called collateral damage).

3 eter of 6.62 mm but retain the potential for collateral damage.

4 rmful to the host, but can also cause severe collateral damage.

5 infection, which led to economic crises as a collateral damage.

6 chinery to protect against and tolerate this collateral damage.

7 endent apoptosis of individual cells without collateral damage.

8 he efficacy of cancer therapy while limiting collateral damage.

9 f lymphocytes, while minimizing the risk for collateral damage.

10 a thermally confined manner without causing collateral damage.

11 that downregulate hyperinflammation to avoid collateral damage.

12 g structures, thereby minimizing the risk of collateral damage.

13 he penetration force is important to prevent collateral damage.

14 ng cellular functions and protecting against collateral damage.

15 a key role of the immune system, but without collateral damage.

16 ollagen vibrational modes results in minimal collateral damage.

17 human corneoscleral rim tissues, with little collateral damage.

18 ined volumes of soft tissue with very little collateral damage.

19 s, optimizing host protection and minimizing collateral damage(1,2).

20 hs showed similar features, i.e., 2 zones of collateral damage, a zone generally < 10 mm of extensive

21 dormancy, suggesting insignificant levels of collateral damage against host RNA or DNA.

22 sed for transfection, but causes significant collateral damage and a high rate of cell death, especia

23 h danger signals, are needed to protect from collateral damage and are of therapeutic interest.

24 quell overzealous immune signaling to limit collateral damage and enable inflammation resolution.

25 am to prevent excessive inflammation, repair collateral damage, and restore tissue homeostasis, and f

26 of off-target cleavage events and potential collateral damage are still lacking.

27 t a major role of tolerance is in minimizing collateral damage associated with inflammation.

28 y impact on trafficker behavior and the many collateral damages associated with the militarized war o

29 s study was to compare lesion durability and collateral damage between focally delivered unipolar/bip

30 Lysis of bystanders is viewed as acceptable "collateral" damage, but the persistent presence of activ

31 ated immunosuppression protects tissues from collateral damage by antipathogen immune cells.

32 rapid journal turnaround times, may produce collateral damage by incentivizing lower-quality researc

33 that protects normal tissues from excessive collateral damage by overactive immune cells and their p

34 by enabling an antimicrobial defense without collateral damage by the adaptive immune system.

35 lated with target RNA expression levels, and collateral damage can be observed even after reducing Rx

36 e ongoing and new strategies to overcome the collateral damage caused by antibiotics and to limit the

37 oduced by effector Th1 cells helps limit the collateral damage caused by exaggerated inflammation.

38 fibrin deposition protects host tissue from collateral damage caused by the immune system as it comb

39 ning to insert foreign DNA and HDR to repair collateral damage caused by the microprojectiles.

40 mpaction, aggregates blood cells, and causes collateral damage due to leukocyte activation.

41 hus the host can benefit from suppression of collateral damage during parasite infection and from red

42 e to accumulating insights, and it may incur collateral damage (e.g., impairing cognitive processes a

43 ) hepatectomy (eHx) was modified to minimize collateral damage; effects were compared with those of s

44 plications create transmural lesions without collateral damage experimentally and whether they can sa

45 els of SBS2/SBS13 in the small intestine are collateral damage from APOBEC1 fulfilling its physiologi

46 n dogs with sDM and sDMPanc, suggesting that collateral damage from inflammation in the exocrine panc

47 injury in vivo as well as greatly decreased collateral damage from inflammation.

48 deling following I/R injury secondary to the collateral damage from sustained myocardial inflammation

49 that these broad events are a consequence of collateral damage from targeting single loci.

50 rance of pathogenic organisms while limiting collateral damage from the host inflammatory response, k

51 mpts to explain the wavelength-dependence of collateral damage have invoked a wavelength-dependent lo

52 To prevent detrimental collateral damage, IL-1beta release is tightly controlle

53 anding the observed wavelength-dependence of collateral damage in mid-infrared laser ablation.

54 of patients with cancer, but it also causes collateral damage in the body that can lead to treatment

55 lation resulted in decreased cellularity and collateral damage in the tissue during viral infection.

56 , when it is drawn into battle, it can cause collateral damage in tissues.

57 in the protection of cells and tissues from collateral damage induced by inflammatory responses.

58 The collateral damage induced on healthy tissues during radi

59 ither destroy foreign DNA directly or elicit collateral damage inducing death of infected cells.

60 cts in the Arab world are much more than the collateral damage inflicted on civilians, infrastructure

61 How the immune response to this collateral damage influences brain maturation and functi

62 Such 'collateral damage' is prohibited by international laws b

63 To avoid collateral damage leading to tissue injury and organ dys

64 Such hepatic collateral damage may be a general consequence of expand

65 conditions, potentially as a means to limit collateral damage of bacterial mutualists.

66 The collateral damage of early-life antibiotic treatment and

67 To mitigate this collateral damage of macrolides and tetracyclines, we sc

68 ute to protection of commensal bacteria from collateral damage of plant glucosinolate-based defense r

69 exerts on an individual's own health via the collateral damage of the drug on bacteria that normally

70 T cells while simultaneously minimizing the collateral damage of their potentially lethal actions an

71 ether IL-10 is also involved in limiting the collateral damage of vigorous T cell responses, has not

72 in the liver, making this a pure example of "collateral damage" of the liver.

73 , the repression of CMT3 prevents epigenetic collateral damage on endogenous genes.

74 rget cancer cells have the ability to reduce collateral damage on normal tissue due to pan-toxic effe

75 are far from perfect and impose significant collateral damage on the fragile endothelial cell (EC),

76 heir therapeutic benefits, antibiotics exert collateral damage on the microbiome and promote antimicr

77 fects harmful to hermaphrodites appear to be collateral damage rather than the goal.

78 o a more complete explanation of the reduced collateral damage resulting from infrared laser irradiat

79 rable safety profile by avoiding much of the collateral damage seen with conventional thermal ablatio

80 d (5) hospital personnel or those considered collateral damage shot, injured, or arrested (5 individu

81 ble to it, the pandemic has caused extensive collateral damage that has led to losses of lives and li

82 x with aspect ratio of 12:1, and without the collateral damage that is observed in unmodulated CW dri

83 tems of several countries in addition to the collateral damage that societies will face in the next y

84 Despite this well-known collateral damage, the activity spectrum of different an

85 r, recent studies have shed new light on the collateral damage they impart on the indigenous host-ass

86 n overly exuberant immune response can cause collateral damage through immune effectors and because o

87 and/or infected cells while also minimizing collateral damage to adjacent noninfected tissues.

88 ssary chemoradiation treatment can result in collateral damage to adjacent vital structures causing a

89 se lesions focally ablated PRs, with minimal collateral damage to cells above and below the plane of

90 t unfolding activity is prevented from doing collateral damage to cellular proteins are not well unde

91 ion of antimicrobial-resistant organisms and collateral damage to commensal microbes.

92 inst MRE colonization, but antibiotics cause collateral damage to commensals and open the way to colo

93 bundance target bacteria without significant collateral damage to complex microbial communities.

94 f the hippocampus (HIPP) or hippocampus plus collateral damage to extrahippocampal structures (HCX) w

95 . cancer cells or parasites) without causing collateral damage to healthy or to host cells is complic

96 catalysis is a promising strategy to reduce collateral damage to healthy tissues and organs.

97 contribute to the inactivation of pathogens, collateral damage to host proteins can also occur and ha

98 is a host response to infection that limits collateral damage to host tissues while having a neutral

99 acterium tuberculosis in vivo but also cause collateral damage to host tissues.

100 sponses counteract infections but also cause collateral damage to hosts.

101 e efficiency of targeted killing and prevent collateral damage to neighboring healthy cells.

102 ion of post-operative quality of life due to collateral damage to neighboring structures.

103 ate tissue with negligible heat transfer and collateral damage to neighboring tissue.

104 and often severe side effects as a result of collateral damage to normal cells.

105 is specifically in cancer cells with minimal collateral damage to normal cells.

106 or removal of damaged neurons, but can cause collateral damage to normal neurons located close to def

107 nciple, yet it is accompanied by significant collateral damage to normal tissue and unwanted side eff

108 ruction of pathogens may result in excessive collateral damage to normal tissues, and the failure to

109 ted to infect only myeloma cells to minimize collateral damage to normal tissues: viral binding to it

110 effective chemotherapy treatments with less collateral damage to ocular tissues and may allow reduce

111 an promote genome evolution while minimizing collateral damage to overall chromosome architecture and

112 ced peripheral neuropathy (CIPN) arises from collateral damage to peripheral afferent sensory neurons

113 ontrolled oxidant bursts could cause serious collateral damage to phagocytes or other host tissues, p

114 djunctive neuroprotective therapy may reduce collateral damage to photoreceptors and improve visual o

115 ole target of FALI and provide evidence that collateral damage to proximal proteins occurs following

116 lled death of cells that occurs with minimal collateral damage to surrounding cells or tissue during

117 while effective against cancer, often causes collateral damage to surrounding healthy tissues, leadin

118 o acts non-autonomously to limit ROS-induced collateral damage to surrounding tissues.

119 wed for unprecedented precision with minimal collateral damage to surrounding tissues.

120 ness of the A1 pulley release and detect any collateral damage to the A2 pulley, interdigital nerves,

121 es were dissected by laser axotomy, avoiding collateral damage to the adjacent dendrite and the forma

122 while minimizing their potential to inflict collateral damage to the adjacent lung tissue and indica

123 Causing collateral damage to the B-cell genome during CSR and SH

124 therapies in some cases, but issues such as collateral damage to the commensal microbiota and consis

125 s is 43.1% lower, highlighting a decrease in collateral damage to the environment.

126 as a general treatment, potentially causing collateral damage to the gut microbiome of the patient.

127 viral persistence and survival with minimal collateral damage to the healthy host.

128 o tune the immune response, thereby limiting collateral damage to the host and the risk for sepsis.

129 mune system controls inflammation and limits collateral damage to the host during acute bacterial inf

130 in order to optimize responses and to avoid collateral damage to the host, immune responses must be

131 ective antimicrobial protection with minimal collateral damage to the host.

132 , to prevent excessive inflammation to limit collateral damage to the host.

133 d downregulates Th1 responses that may cause collateral damage to the host.

134 as the eradication of pathogens with minimal collateral damage to the host.

135 nt antimicrobials, however, exert tremendous collateral damage to the human microbiome through overus

136 ive papers emerged this past year concerning collateral damage to the liver in extrahepatic infection

137 lance of initiating immunity without causing collateral damage to the lungs because of an exaggerated

138 lusively within the tumors, and there was no collateral damage to the neighboring hepatic parenchyma.

139 ffects pathologic vessels, it can also cause collateral damage to the overlying retina.

140 to target a specific pathogen can also cause collateral damage to the patient's resident microbial po

141 ding histology sections exhibit only minimal collateral damage to the surrounding tissue and the dept

142 s and can treat microvessels without causing collateral damage to the surrounding tissue.

143 Collateral damage to the vagal nerve and the upper gastr

144 In contrast, mice with collateral damage to the ventromedial hypothalamus and p

145 easy-to-implement techniques without causing collateral damage to true memories.

146 these nasty invaders while also constraining collateral damage to vital tissue.

147 Finally, no sign of collateral damage was observed in any of the groups.

148 However, collateral damage was observed with both catheters in 17

149 e empiric therapy against toxicity risks and collateral damage when selecting antibiotic therapy for

150 this beneficial activity comes at a cost of collateral damage when the immune system overreacts to i

151 Our data suggest that T6SS toxins may avoid collateral damage within a complex ecosystem by recogniz