ライフサイエンスコーパス: telemedicine

1 eam of subspecialists conducting clinics via telemedicine.

2 The 12-lead ECGs are interpreted via telemedicine.

3 with specialist physician support utilizing telemedicine.

4 end appointment, appointment after 5 pm) and telemedicine.

5 rate similar to that paid without the use of telemedicine.

6 ccess to care via direct parent-to-clinician telemedicine.

7 expansion of retinal screening programs via telemedicine.

8 tor randomly assigned participants to either telemedicine (120 [50%]) or same-room treatment (121 [50

9 ng to BDI also did not differ significantly (telemedicine 19 [24.05%, 90% CI 16.14-31.96] patients; s

10 GDS did not differ significantly between the telemedicine (22 [22.45%, 90% CI 15.52-29.38] patients)

11 formation exists on the subsequent effect of telemedicine activities on eye care resources.

12 ICU telemedicine adoption was initially rapid but recently s

13 ors in an ICU may be markers of overload; 6) telemedicine, advanced practice professionals, or nonint

14 ors in an ICU may be markers of overload; 6) telemedicine, advanced practice professionals, or nonint

15 tional techniques.Telementoring, a subset of telemedicine, allows a surgeon at a remote site to offer

16 ifying children who develop severe ROP using telemedicine and a predictive model synergistically.

17 Telemedicine and air medical transport play a key role i

18 e mHealth's clinical utility, especially for telemedicine and for resource-poor settings and global h

19 mpact and cost-effective designs for various telemedicine and lab-on-a-chip applications.

20 r, we discuss the rapidly evolving fields of telemedicine and mHealth in the context of increasingly

21 be impacted by the increasing prevalence of telemedicine and relative shortage of clinicians.

22 omotion of self-care and home visitations to telemedicine and remote monitoring of external or implan

23 ics between facilities that have adopted ICU telemedicine and those that have not.

24 111 patients were randomised to telemedicine, and 111 patients were randomised to teleph

25 ologist evaluated the first 100 patients via telemedicine, and a neuroradiologist remotely assessed i

26 ther studies, present challenges to adopting telemedicine, and identify future opportunities for the

27 ivered, without modification, via home-based telemedicine, and that this method can be used to overco

28 The cost-effectiveness of specific telemedicine applications has not yet been rigorously de

29 ould create new opportunities especially for telemedicine applications.

30 ally, digital echocardiography has important telemedicine applications.

31 (ETROP) trials and the primary data from the Telemedicine Approaches for the Evaluation of Acute-Phas

32 The Telemedicine Approaches to Evaluating Acute-Phase Retino

33 disease) on diagnostic examination from the Telemedicine Approaches to Evaluating Acute-Phase Retino

34 aocular hemorrhages (IOHs) in infants in the Telemedicine Approaches to Evaluating Acute-Phase Retino

35 age grading and examination results from the Telemedicine Approaches to Evaluating Acute-Phase Retino

36 included secondary analysis of data from the Telemedicine Approaches to Evaluating Acute-Phase Retino

37 Secondary analyses of data from the Telemedicine Approaches to Evaluating of Acute-Phase ROP

38 ddressing providing professional services by telemedicine are detailed.

39 We evaluated the feasibility of using telemedicine as a means of achieving 24-hr intensivist o

40 et Act provisions, Congress has acknowledged telemedicine as a viable, potentially life-saving techno

41 amine and review digital retinal imaging via telemedicine as an important screening and diagnostic to

42 Telemedicine-based collaborative care can successfully e

43 In rural settings, a telemedicine-based collaborative care intervention for d

44 Those assigned to telemedicine-based collaborative care received evidence-

45 Contracting with an off-site telemedicine-based collaborative care team can yield bet

46 Telemedicine-based collaborative care virtually co-locat

47 s of patients assigned to practice-based and telemedicine-based collaborative care.

48 Telemedicine-based competency interviews may facilitate

49 akes into account all costs and effects, the telemedicine-based DR screening model had significantly

50 de a strong economic rationale to expand the telemedicine-based DR screening program in Singapore and

51 The SiDRP is a new telemedicine-based DR screening program using trained te

52 hile generating similar health outcomes, the telemedicine-based DR screening using technicians in the

53 the collaborative care evidence base in the telemedicine-based group.

54 ns in severity over time for patients in the telemedicine-based group.

55 e of future cost savings associated with the telemedicine-based model is estimated to be S$29.4 milli

56 The addition of a supplemental, telemedicine-based, remote intensivist program was assoc

57 iatric cardiologists often favor "real-time" telemedicine because of the ability to guide sonographer

58 the need for standardized approaches as ROP telemedicine becomes more widespread.

59 care, improving access, and capturing other telemedicine benchmark data.

60 attention of researchers from fields such as telemedicine, biotechnology, chemical sciences and envir

61 Telemedicine can be used to educate physicians in spoke

62 ther research is needed to establish whether telemedicine can deliver on the promise of improved acce

63 Telemedicine can include a variety of aspects of patient

64 This network operates as follows: The Telemedicine Center sends each ECG suggestive of STEMI t

65 nternet, clinical trials, and neurology; and telemedicine, clinical trials, and neurology), reference

66 id not differ for those randomly assigned to telemedicine compared with those randomly assigned to in

67 emedicine include lack of standardization of telemedicine components, confusing legal issues and lice

68 ograms after regular working hours through a telemedicine connection to on-call cardiologists.

69 maging system, a point-of-care laboratory, a telemedicine connection to the hospital, and appropriate

70 scanner plus a point-of-care laboratory and telemedicine connection.

71 a CT scanner, point-of-care laboratory, and telemedicine connection; a stroke identification algorit

72 Internet telemedicine consistently supported real-time intraopera

73 One telemedicine consultation was aborted for technical reas

74 lity was highest among patients who received telemedicine consultations (n=58; beta=0.50 [95% CI, 0.1

75 The authors of this trial report that stroke telemedicine consultations result in more accurate decis

76 Telemedicine consultations were associated with more fre

77 ne was superior for decision making in acute telemedicine consultations.

78 Providing specialty care to patients via telemedicine could help alleviate this growing problem.

79 Telemedicine could increase access to best-practice care

80 e providers in 63%; hospitalists in 21%; and telemedicine coverage in 14%.

81 Telemedicine-defined here as the use of real-time, synch

82 roved access to neurologist care and whether telemedicine-delivered care is comparable to in-person c

83 wn the feasibility and potential benefits of telemedicine-delivered care.

84 Telemedicine-delivered psychotherapy for older adults wi

85 recapitulate and evaluate the advantages of telemedicine described in other studies, present challen

86 rding the role of mosaic photography for ROP telemedicine diagnosis.

87 There were 6 telemedicine disconnections, none of which lasted longer

88 Search terms included telemedicine, eHealth, mobile health, mHealth, app, and

89 The term telemedicine encompasses a wide range of telecommunicati

90 mpleted by staff intensivists following each telemedicine encounter were reviewed.

91 cine in the ICU operation costs included the telemedicine equipment-installation (start-up) costs wit

92 The median duration of telemedicine evaluation was 20 minutes (interquartile ra

93 lthough studies have examined the effects of telemedicine, few reports have characterized its current

94 orated with emerging technologies, including telemedicine, flexible and wearable sensing, smart mater

95 Additional studies are needed in the area of telemedicine for age-related macular degeneration.

96 ime requirements all support the efficacy of telemedicine for making treatment decisions, and might e

97 ency departments and the potential effect of telemedicine for ophthalmology triage and consultation.

98 ogist can be eliminated by relying solely on telemedicine for physician presence.

99 cidence of ROP continues to rise, the use of telemedicine for screening, diagnostic and educational p

100 studies evaluating the cost-effectiveness of telemedicine for vitreoretinal diseases.

101 dicine in the ICU, compared with ICU without telemedicine, from the healthcare system perspective.

102 and screening results from the Philadelphia Telemedicine Glaucoma Detection and Follow-up Study.

103 lete data in the telephone group than in the telemedicine group (12%vs 3%, 0.2, 0.1-0.3; p=0.0001).

104 patients in the per-protocol analysis in the telemedicine group and 104 (86%) in the same-room group.

105 [43.33%, 90% CI 34.74-51.93] patients in the telemedicine group and 46 [48.42%, 90% CI 39.99-56.85] i

106 atment decisions were made more often in the telemedicine group than in the telephone group (108 [98%

107 .5 (SD 8.1) points (11.4 [8.7] points in the telemedicine group versus 7.7 [7.0] points in the teleph

108 The telemedicine group was more likely to receive a diabetic

109 Telemedicine has been used to support care at a distance

110 Telemedicine has potential to expand access to high-valu

111 Telemedicine has rapidly flourished in the United States

112 The advent and development of telemedicine has the potential to ensure that patients w

113 Telemedicine holds the potential to increase the number

114 re integration, and expansion of the role of telemedicine in areas where intensivists are inaccessibl

115 he scientific evidence evaluating the use of telemedicine in cardiovascular and stroke care and to pr

116 To describe the expanding role of telemedicine in healthcare, the key criteria required fo

117 Practical experience with telemedicine in neurological practice contributed to the

118 Current models of telemedicine in ophthalmology are largely performed via

119 However, the use of telemedicine in ophthalmology is currently in its infanc

120 an serve as a model for the effectiveness of telemedicine in other medical specialties.

121 recommendations for the practice and use of telemedicine in primary care and reimbursement policies

122 able amount of federal funding has supported telemedicine in recent years, and legislators and federa

123 Telemedicine in retinopathy of prematurity (ROP) has the

124 The role of telemedicine in ROP education will impact both screening

125 e summarize the utility and effectiveness of telemedicine in the evaluation and treatment of infectio

126 yses, help hospitals determine the impact of telemedicine in the ICU and potential cost saving.

127 e ICU, hospitals have been slow to introduce telemedicine in the ICU due to high up-front costs and m

128 Telemedicine in the ICU effectiveness was measured by cu

129 Our analyses suggest that telemedicine in the ICU is cost-effective in most cases

130 Telemedicine in the ICU operation costs included the tel

131 aim was to examine potential cost saving of telemedicine in the ICU through probabilistic analyses a

132 e case cost-effectiveness analysis estimated telemedicine in the ICU to extend 0.011 quality-adjusted

133 the incremental cost-effectiveness ratio of telemedicine in the ICU, compared with ICU without telem

134 The intervention was the introduction of telemedicine in the ICU, which was assumed to affect per

135 The use of telemedicine in the management of acute infectious disea

136 senting the current data on the economics of telemedicine in vitreoretinal diseases.

137 Obstacles to widespread implementation of telemedicine include lack of standardization of telemedi

138 The number of hospitals using ICU telemedicine increased from 16 (0.4% of total) to 213 (4

139 The number of ICU beds covered by telemedicine increased from 598 (0.9% of total) to 5,799

140 Telemedicine increased the percentage of diabetic retino

141 mputer, a low- or high-speed connection, and telemedicine inputs.

142 The post periods are 1, 2, and 3 yrs after telemedicine intensive care unit program implementation

143 A telemedicine intensive care unit program with remote 24/

144 After 3 yrs of deployment of a telemedicine intensive care unit program, this retrospec

145 ysicians in training report experiences with telemedicine intensivists that are positive and increase

146 Clinical data and conventional and telemedicine interpretations were collected prospectivel

147 significant differences associated with the telemedicine intervention for hospital mortality (relati

148 Telemedicine is a cost-effective means for screening dia

149 ICU telemedicine is a novel approach for providing critical

150 Telemedicine is a useful clinical method to extend healt

151 Telemedicine is available to help community medical cent

152 Importance: Telemedicine is becoming an increasingly important compo

153 Cutting-edge technology in the form of telemedicine is being implemented in stroke care network

154 An MSTU using telemedicine is feasible, with a low rate of technical f

155 Low-bandwidth, Internet-based telemedicine is inexpensive, effective, and almost ubiqu

156 Research on the effectiveness of telemedicine is somewhat limited, although the work that

157 Because ROP telemedicine is used more widely, development of standar

158 Overall mean agreement rate between telemedicine laptop interpretation and conventional work

159 mercially available equipment, suggests that telemedicine may provide a means for hospitals to achiev

160 However, the potential benefits of telemedicine must be measured against the risks and chal

161 d in the study and were randomly assigned to telemedicine (n = 9) or in-person care (n = 11).

162 The telemedicine network can be used to transmit real-time d

163 nd the 5 North Carolina Diabetic Retinopathy Telemedicine Network sites by zip code and the density o

164 be stored at one site and forwarded across a telemedicine network to a receiving station for review a

165 g in the North Carolina Diabetic Retinopathy Telemedicine Network, (2) the locations of primary care

166 l in the North Carolina Diabetic Retinopathy Telemedicine Network.

167 f geographically wide and technically robust telemedicine networks, with a minimum of expense.

168 urse practitioners and physician assistants, telemedicine, offering critical care training positions

169 Telemedicine offers an opportunity to take advantage of

170 The use of telehealth and telemedicine offers powerful tools for delivering clinic

171 ) triaged for specialist review conducted by telemedicine only.

172 onsultation coverage and perceived effect of telemedicine ophthalmology consultation at each facility

173 vioural activation for depression either via telemedicine or in the same room.

174 ough a web-based, permuted blocks system, to telemedicine or telephone consultation to assess their s

175 lementation of future drug therapies through telemedicine-organized stroke networks will likely subst

176 The Telemedicine Outreach for PTSD (TOP) study used a pragma

177 The percent of telemedicine participants requiring referral ranged from

178 ive diabetic retinopathy), and percentage of telemedicine participants who would require referral to

179 hysicians highlight a meaningful approach to telemedicine policies and regulations that will have las

180 The two primary modes of telemedicine practice are "store and forward" and "real-

181 The inclusion of an ICU telemedicine program as a major part of their critical c

182 Implementation of an ICU telemedicine program is one practical way to increase ac

183 The cost-effectiveness of the DR telemedicine program was determined by using a finite-ho

184 Care Services (TECS), a novel ophthalmologic telemedicine program.

185 nterpreting fundus photographs captured in a telemedicine program.

186 Many telemedicine programs are currently being investigated a

187 y studies suggest that implementation of ICU telemedicine programs has been associated with lower num

188 The development of telehealth and telemedicine programs requires the consideration of seve

189 hesiologists have the opportunity to develop telemedicine programs that can improve the delivery of c

190 The first telemedicine programs were established almost 40 years a

191 Its implementation in the existing telemedicine programs would require minimal resources.

192 her improvements could bring applications in telemedicine, prototyping, advertising, updatable 3D map

193 ed with the remote evaluation of images at a telemedicine reading center has been advanced as a strat

194 We prospectively assessed whether telemedicine (real-time, two-way audio and video, and di

195 vascular neurologist connected to the MSU by telemedicine, reducing manpower requirements and costs.

196 Telemedicine refers to the application of telecommunicat

197 Sensitivity and specificity of telemedicine relative to indirect ophthalmoscopy for dia

198 median interval time between the ECG and the telemedicine report was 31 minutes (interquartile range,

199 ICU telemedicine research including comparative effectivenes

200 f $516 per patient compared with ICU without telemedicine, resulting in an incremental cost-effective

201 To evaluate telemedicine retinal screenings for patients with type 1

202 Despite telemedicine's potential to improve patients' health out

203 Telemedicine screening also allows for the extension of

204 Patient and provider costs of telemedicine screening and hospital-based DR treatment w

205 Telemedicine screening for CMV retinitis instituted at t

206 An integrated telemedicine screening intervention in primary care offi

207 The results indicate that telemedicine screening is cost-effective for DR under mo

208 In a DR telemedicine screening program in urban clinic or pharma

209 and average additional cost incurred by the telemedicine screening program.

210 Telemedicine screening programs and epidemiological stud

211 Epidemiologic studies and telemedicine screening typically use monocular fundus ph

212 ening population since the implementation of telemedicine screening: the number of known DR cases has

213 extend Medicare coverage to a wide range of telemedicine services and providers, allowing for medica

214 Simulation using telemedicine services can provide educational opportunit

215 Telemedicine services facilitate the evaluation, diagnos

216 a number of states provide reimbursement for telemedicine services offered in several specialties, in

217 any barriers to widespread implementation of telemedicine services remain to be addressed, including

218 he most likely scenario for the expansion of telemedicine services to rural counties will be through

219 ure, coupled with Medicare reimbursement for telemedicine services, present medical providers with a

220 ility fee of $20 to the originating site per telemedicine session.

221 ents within our changing health care system, telemedicine should be incorporated into our strategy.

222 ns and patients indicate that application of telemedicine should not be limited to physician-to-physi

223 n the e-ROP Study (a multicenter prospective telemedicine study) and the Postnatal Growth and Retinop

224 etting was a community-based study assessing telemedicine success of the MSTU in Cleveland, Ohio.

225 Sensitivity and specificity of the telemedicine system for detecting referral-warranted ROP

226 Applying a postnatal growth model and telemedicine system in a tiered approach may reduce the

227 ase Retinopathy of Prematurity (e-ROP) Study telemedicine system of remote fundus image grading and T

228 A complete telemedicine system requires a modified computer, a low-

229 ly minimally improved the sensitivity of the telemedicine system to detect RW-ROP.

230 he federal government proposes regulation of telemedicine technologies and medical software, communic

231 Telemedicine technologies are rapidly being integrated i

232 In addition, the use of telemedicine technologies may provide the ability to scr

233 educate members on the use of telehealth and telemedicine technologies.

234 Evolving telemedicine technology has the potential to improve acc

235 Telemedicine technology, which can enable intensivists t

236 s tissue plasminogen activator treatment via telemedicine (telestroke) are similar to those achieved

237 for patients who received consultations with telemedicine than for patients who received either telep

238 ently when consultations were provided using telemedicine than telephone.

239 Despite the expansion of telemedicine, the volume of patients receiving services

240 Telemedicine-the use of technology to deliver care at a

241 Two years after enrollment, we offered telemedicine to all participants.

242 ster's level psychology technician utilizing telemedicine to allow specialized multidisciplinary trea

243 lt and pediatric clinical studies have shown telemedicine to be accurate and cost-effective, improve

244 After we offered telemedicine to both groups, we could not identify a dif

245 Few trials, however, have used telemedicine to improve blood pressure in patients with

246 A major component of the model is the use of telemedicine to leverage clinical expertise and facilita

247 g the long-term comparative effectiveness of telemedicine to provide diabetic retinopathy screening e

248 A supports appropriate use of telehealth and telemedicine to provide timely, cost-effective specialty

249 n therapy for major depression delivered via telemedicine to same-room care in largely male, older ad

250 g suggests that primary care clinics can use telemedicine to screen for diabetic retinopathy and moni

251 By combining telemedicine tools and new care models, we can redesign

252 the evidence from studies that have employed telemedicine tools in other disciplines and makes sugges

253 e and reimbursement policies associated with telemedicine use.

254 After-hours emergency echocardiography telemedicine using a laptop computer is more rapid than

255 tcomes between ICD patients followed-up in a telemedicine video-conferencing clinic (TMVC) and a conv

256 Compared with in-person visits, each telemedicine visit saved participants, on average, 100 m

257 rally Qualified Health Centers were used for telemedicine (Visit 1).

258 easibility, as measured by the percentage of telemedicine visits completed as scheduled.

259 Of the 27 scheduled telemedicine visits, 25 (93%) were completed, and of the

260 e after treatment with thrombolytics (2 [7%] telemedicine vs 2 [8%] telephone, 0.8, 0.1-6.3; p=1.0).

261 ere used at an overall rate of 25% (31 [28%] telemedicine vs 25 [23%] telephone, 1.3, 0.7-2.5; p=0.43

262 eived quality were significantly higher when telemedicine was used, compared with telephone, for six

263 al suggestions to improve the quality of DTC telemedicine websites and apps and avoid further growth

264 f rapidly expanding direct-to-consumer (DTC) telemedicine websites and smartphone apps diagnosing and

265 onses for 62 clinical encounters from 16 DTC telemedicine websites from February 4 to March 11, 2016.

266 diagnosis and treatment provided by many DTC telemedicine websites.

267 n-adopting hospitals, hospitals adopting ICU telemedicine were more likely to be large (percentage wi

268 highlight many of the latest technologies in telemedicine, which are applicable to MIS and provide an

269 re delivery systems make initiatives such as telemedicine, which reduce costs while achieving excelle

270 hat recent changes in HCFA reimbursement for telemedicine will have a dramatic impact on the delivery

271 ity for surgical applications, low-bandwidth telemedicine will open the operating room environment to

272 We assigned participants to telemedicine with a nonmydriatic camera in a primary car

273 es deserve consideration in the quest to use telemedicine with remote reading for efficient delivery

274 ntinue to evolve and expand the footprint of telemedicine within ophthalmology.

275 identify future opportunities for the use of telemedicine within the realm of clinical infectious dis