ライフサイエンスコーパス: medical imaging

1 ethods used in humans provides comprehensive medical imaging.

2 otechnology, drug discovery, and potentially medical imaging.

3 r in actual NIR contrast-enhanced diagnostic medical imaging.

4 relates tissue neuropathological analysis to medical imaging.

5 f multiple myeloma is frequently observed in medical imaging.

6 ces, optical computing, and in vivo infrared medical imaging.

7 uctive materials, sensors, drug delivery and medical imaging.

8 ically improve soft tissue contrast in X-ray medical imaging.

9 e with or even below those currently used in medical imaging.

10 science, pharmaceuticals, agrochemicals, and medical imaging.

11 nces that can be visualized noninvasively by medical imaging.

12 ith potential applications in biological and medical imaging.

13 ng to applications from energy harvesting to medical imaging.

14 rstones to enhancing the radiation safety of medical imaging.

15 sonance (EPR), fluorescence spectroscopy and medical imaging.

16 h to drug screening and discovery as well as medical imaging.

17 nd cumulative annual radiation exposure from medical imaging.

18 e high exposure to ionizing radiation due to medical imaging.

19 anced interest in exposure to radiation from medical imaging.

20 in vivo dynamics of gliomas visualized with medical imaging.

21 ical sciences, it also plays a vital role in medical imaging.

22 nizing radiation potentially associated with medical imaging (2).

23 sting topic in structural health monitoring, medical imaging, aerospace and nuclear instrumentation.

24 entities for site-specific drug delivery and medical imaging after parenteral administration.

25 c media, resulting in anxiety and fear about medical imaging among patients and parents.

26 In microarray analysis, medical imaging analysis and functional magnetic resonan

27 ensitivity that is otherwise challenging for medical imaging and blood biomarkers to achieve.

28 integrates interdisciplinary expertise from medical imaging and engineering.

29 ests applications of hyperpolarized 15N2O in medical imaging and for flow and diffusion studies.

30 cular imaging modality more centrally within medical imaging and for the integration of nuclear medic

31 The medical imaging and image processing techniques, ranging

32 ing data sharing policies, and standardizing medical imaging and in vitro diagnostics.

33 Possible applications include medical imaging and material evaluation.

34 approach appears particularly beneficial for medical imaging and nondestructive testing.

35 niques are rapidly emerging in the fields of medical imaging and targeted drug delivery.

36 olar energy conversion, fuel-cell catalysis, medical imaging and therapy, and electronics.

37 unctional nanomaterials with applications in medical imaging and therapy.

38 s such as particle detection, dosimetry, and medical imaging and therapy.

39 Medical imaging and viewing software were used to compar

40 n varied applications such as drug delivery, medical imaging, and advanced materials, as well as in f

41 drivers of costs: end-of-life care patterns, medical imaging, and drugs.

42 ated to nonproliferation, homeland security, medical imaging, and gamma-ray telescopes.

43 As drug delivery, therapy, and medical imaging are becoming increasingly cell-specific,

44 predict human performance are of interest in medical imaging as substitutes in psychophysical studies

45 n over the impact of radiation exposure from medical imaging, as well as on the cost of diagnostic me

46 t category "radiology, nuclear medicine, and medical imaging" at the Institute of Science Information

47 imaging has great potential in the field of medical imaging because it offers several major advantag

48 ly related to Definity (Bristol-Myers Squibb Medical Imaging, Billerica, Massachusetts) administratio

49 ntrast agents Definity (Bristol-Myers Squibb Medical Imaging, Billerica, Massachusetts) and Optison (

50 ved intravenous contrast (Definity, Lantheus Medical Imaging, Billerica, Massachusetts).

51 copic lesions are frequently detected during medical imaging, but it is unclear how they form or prog

52 As a noninvasive technique, medical imaging can be performed at low risk and inconve

53 Observations: Medical imaging can provide a comprehensive macroscopic

54 Medical imaging can visualize characteristics of human c

55 rgery, radiation oncology, medical oncology, medical imaging, clinical pathology and lab medicine, so

56 Accordingly, the medical imaging community must ensure that the benefits

57 mulations, including drug delivery vehicles, medical imaging contrast agents, and integral membrane p

58 In most cases, the development of a medical imaging device was opportunistic; many scientist

59 logical and materials research, and portable medical imaging devices, and would substantially reduce

60 We suggest that the FDA Medical Imaging Division convene a panel of cardiologist

61 Medical imaging does not provide diagnosis of EVD, but p

62 for many biomedical applications, including medical imaging, drug delivery, and antimicrobial coatin

63 ubiquity of DNA sequencing and the advent of medical imaging, electronic health records, and "omics"

64 Several radionuclides used in medical imaging emit Auger electrons, which, depending o

65 Patients who undergo frequent medical imaging examinations can accumulate doses that a

66 In some cases, medical imaging examinations may be delayed or deferred

67 Radiomics extracts and mines large number of medical imaging features quantifying tumor phenotypic ch

68 nal oncology, as research and development in medical imaging focuses on interventional needs, it is l

69 nd porous media, with applications including medical imaging, food characterization and oil-well logg

70 In this review, the current status of medical imaging for intervention in oncology will be des

71 gned to coordinate metal ions or chelates to medical imaging has allowed for significant breakthrough

72 Traditionally, medical imaging has defined anatomy, but increasingly ne

73 Medical imaging has enormous potential for early disease

74 PURPOSE OF REVIEW: Radiation exposure due to medical imaging has grown exponentially over the past tw

75 zation in imaging: the low-dose radiation of medical imaging has no documented pathway to harm, where

76 Over the past decade, medical imaging has played an increasingly valuable role

77 Medical imaging has seen substantial and rapid technical

78 in developmental biology, neuroscience, and medical imaging have brought us closer than ever to unde

79 Advances in cancer biology and medical imaging have led to a number of cancer screening

80 nificant implications related to the role of medical imaging in didactic and research.

81 espite numerous applications in oncology and medical imaging in general, there is no consensus regard

82 ntional needs, it is likely that the role of medical imaging in intervention will become even more in

83 Medical imaging in interventional oncology is used diffe

84 s disease entity; and to address the role of medical imaging in this patient population.

85 ntrast agent (Definity, Bristol-Myers Squibb Medical Imaging Inc., North Billerica, Massachusetts) wa

86 t agents (35% Definity, Bristol Myers Squibb Medical Imaging Inc., North Billerica, Massachusetts; 65

87 The use of ionizing radiation in medical imaging, including CT, provides valuable diagnos

88 Excessive use of medical imaging increases health care costs and exposure

89 es, private payers, government agencies, the medical imaging industry, and experts in quality measure

90 Medical imaging is crucial for diagnosis, phenotyping, a

91 Medical imaging is entering the new millennium with a so

92 Medical imaging is essential to screening, early diagnos

93 Medical imaging is routine in the diagnosis and staging

94 uantification of the tumor phenotype through medical imaging, is a promising development for precisio

95 esented in the top 100 cited articles in the medical imaging literature.

96 Hence, we are pioneering a new medical imaging method, called Magnetic Particle Imaging

97 ge electromechanical coupling for ultrasound medical imaging, microfluidic control, mechanical sensin

98 itous challenge, crucial in radio astronomy, medical imaging, navigation, and classical and quantum c

99 oad interest to researchers in the fields of Medical Imaging, Neuroscience, Physiology, and Psycholog

100 The growth in medical imaging over the past 2 decades has yielded unar

101 Despite the advances made in medical imaging over the past 3 decades and the central

102 Medical imaging plays a fundamental role in oncology and

103 In general, medical imaging plays five key roles in image-guided the

104 ial characterization, biological sensing and medical imaging, practical development of these applicat

105 ncy with which patients underwent diagnostic medical imaging procedures during episodes of care was c

106 ncy with which patients underwent diagnostic medical imaging procedures during episodes of outpatient

107 York, New York, that evaluated all preceding medical imaging procedures involving ionizing radiation

108 hs per year in the U.S. population caused by medical imaging procedures that use ionizing radiation.

109 The yearly rate of medical imaging radiation exposure may seem small at app

110 ge and key questions in regard to sources of medical imaging radiation exposure, radiation risk estim

111 Application of these methods to medical imaging requires further assessment and validati

112 ected to provide a powerful resource for the medical imaging research community.

113 During the past 25 years, medical imaging research has progressed in both scope an

114 markers and has potential in high-throughput medical imaging research.

115 ques in analytical chemistry and noninvasive medical imaging, respectively.

116 current frontier of research in the field of medical imaging science.

117 m, used previously in picture processing and medical imaging, SIFT supplements data at nonuniform poi

118 f luminescent silica-based nanoparticles for medical imaging, starting with an overview of the most c

119 Medical imaging studies achieve a diagnostic purpose and

120 valuated a novel combined x-ray CT and SPECT medical imaging system for quantitative in vivo measurem

121 original scheme was designed to evaluate new medical imaging systems but is less successful when appl

122 Analysis was performed with QMASS (Medis Medical Imaging Systems, Leiden, the Netherlands) and HA

123 nces in many imaging systems, in particular, medical imaging systems.

124 Computed tomography is a widely used medical imaging technique that has high spatial and temp

125 resonance spectroscopy (1HMRS), an emerging medical imaging technique.

126 Despite significant advances in medical imaging techniques and their routine preoperativ

127 ered an impressive variety of biosensing and medical imaging techniques.

128 Current medical imaging technologies allow visualization of tiss

129 We demonstrate the utility of nuclear medical imaging technologies and a readily available rad

130 Today's medical imaging technologies are expected to furnish ana

131 Medical imaging technologies have undergone explosive gr

132 The outcomes of a 2011 Medical Imaging & Technology Alliance (MITA) conference

133 Recently, the Medical Imaging & Technology Alliance (MITA), a Washingt

134 ical energy (and vice versa), are crucial in medical imaging, telecommunication and ultrasonic device

135 nt practices for providing information about medical imaging tests that involve the use of radiation.

136 ms to quantify phenotypic characteristics on medical imaging through the use of automated algorithms.

137 edical fields ranging from drug delivery and medical imaging to management of vascular diseases and d

138 lications from displays, solar cells and bio-medical imaging to single-electron devices.

139 a wide range of potential applications, from medical imaging to surveillance.

140 ontrast agents for safe, reliable ultrasound medical imaging, tracers for magnetic resonance imaging,

141 Historically used for medical imaging, ultrasound (US) has recently been shown

142 Medical imaging using SERS nanoprobes can yield higher s

143 The potential of this source for medical imaging was demonstrated by performing micro-com

144 required in Poland only for those methods of medical imaging which involve the use of ionizing radiat

145 payers to discuss the key drivers of the way medical imaging will develop over the next 10 years.

146 sonation are within the physical therapy and medical imaging windows; thus the applied ultrasound is

147 sed chelator in positron emission tomography medical imaging with (64)Cu, has been synthesized using

148 Medical imaging with multimodality and whole-body techno

149 eview focuses on nanoparticles used in human medical imaging, with an emphasis on radionuclide imagin

150 oth controllers and a commercially available medical imaging workstation.