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1 ace as a reflector, whilst also being highly portable.
2 s, which are less expensive, safer, and more portable.
3 d, inexpensive, remarkably simple and highly portable.
4               We developed a fully automated portable 2-dimensional (2-D) gas chromatography (GC x GC
5  (CDR) measurements from images taken with a portable, 45-degree nonmydriatic fundus camera to images
6                                Analyzed by a portable AC susceptometer, the changes of the hydrodynam
7                           RapidSCAN is a new portable active crop canopy sensor with three wavebands
8      We needed to validate and calibrate our portable acuity screening tools so amblyopia could be de
9 n-proof mattress and pillow encasements, and portable air purifiers.
10 nd sequenced in a single day by RTnS using a portable, "al fresco" laboratory.
11 ate, the research for developing small-scale portable alcohol detection system has been accelerated w
12 commercially viable and environment friendly portable alcohol detection systems is gaining pace.
13 e laser is implemented for solid sampling in portable ambient mass spectrometry (MS).
14 t and microbial communities, for example, by portable ambient MS.
15 as low-cost electrodes to develop simple and portable amperometric glucose biosensors.
16 esent report highlights a cost effective and portable AMT-Ag nanocrystalline coordination polymer (NC
17 Moreover, BIA methods show great promise for portable analysis because battery-powered instrumentatio
18                 In this work, a low cost and portable analyzer with good accuracy is developed to use
19 droplet magnetofluidics to deliver NAAT in a portable and accessible format.
20 d easy-to-use device will prove valuable for portable and automated diagnostics applications, and can
21 lightweight energy storage what is vital for portable and autonomous device operation with numerous a
22 loForge takes advantage of HTML5 to be fast, portable and avoid the need for local installation.
23                         Here, we report on a portable and battery-operated optical sensor that can ra
24             The methods we describe here are portable and can be accomplished at low cost, and can al
25 ted to spread in the future because they are portable and can sequence long fragments of DNA molecule
26                                            A portable and compact device is demonstrated for measurin
27 nion-sensing platform is reported based on a portable and cost-effective ion-selective optode and a s
28 and samples, provide rapid analysis, and are portable and disposable.
29 nd is a promising tool for simple, low-cost, portable and easy-to-use biosensors.
30 ng technologies could lead to a small-scale, portable and fully integrated personal biomanufacturing
31 es that chromatin-derived peptide motifs are portable and in some cases can be customized to alter th
32                 The preliminary results of a portable and low-cost molecular diagnostics system for Z
33                                              Portable and low-cost platforms for protein biomarker de
34 re can have a broad range of applications in portable and microgas chromatography systems for in situ
35 y promising for the development of low-cost, portable and miniaturized electrochemical systems for po
36 imple device has the potential for low cost, portable and real-time nucleic acid analysis as a Point
37 obile phone camera to create an inexpensive, portable and robust DFM system suitable for use in non-l
38 IR analysis is inexpensive, easy to use, and portable and shows significant potential to replace the
39                    The system was completely portable and the annual cost of the trapping system was
40 upling of these two technologies is enabling portable and user-friendly analytical devices.
41 with its associated detection in a low-cost, portable, and autonomous device remains challenging.
42 olbox described here is simple, low-cost and portable, and can be used in a variety of health care an
43 ction of biomarkers as they are easy to use, portable, and can do analysis in real time.
44 just 1 pound, can be fabricated at low cost, portable, and can transfer test results via mobile phone
45 al analyses since they are specific, simple, portable, and generally disposable and can carry out in
46 tial to develop as rapid, selective, simple, portable, and inexpensive malarial diagnostic device for
47 vide appealing insights into cost-effective, portable, and scalable alternatives for designing new an
48 e development of a chip-based, miniaturized, portable, and self-containing system that allows for the
49 ased assays that are simple, cost-efficient, portable, and user-friendly for various point-of-care ap
50  creating, testing, versioning and archiving portable applications for analyzing neuroimaging data or
51 geneity making it more amenable to low-power portable applications.
52 nted practices of personal ornamentation and portable art, alongside evidence for pigment processing
53 rrected visual acuity to 9.5 (0.5) using the portable artificial vision device at the first visit (me
54                                          The portable artificial vision device was tested at the pati
55                    Mean (SD) scores with the portable artificial vision device were also better in th
56                         When patients used a portable artificial vision device, an increase in scores
57  low-vision aids if available, and using the portable artificial vision device.
58 ated DNA biosensor was considered stable and portable as indicated by a recovery of more than 80% aft
59 , we demonstrate design and fabrication of a portable automatic phoropter with no need for patient's
60  by the availability of relatively low cost, portable, battery-powered diode lasers.
61                               We introduce a portable biochemical analysis platform for rapid field d
62  to serve as a sensitive low-cost method for portable biomarker detection.
63  solutions for affordable, user-friendly and portable biosensing.
64                                A new wave of portable biosensors allows frequent measurement of healt
65 inherent difficulties in developing low-cost portable biosensors for point-of-care diagnostics using
66         Overall, these results indicate that portable biosensors provide useful information for monit
67                                  The simple, portable blood plasma separation design is hand-driven a
68 ne user interface operating in tandem with a portable Bluetooth-enabled cartridge-processing unit fac
69                      We developed a low-cost portable BMI for survivors of cervical spinal cord injur
70  the development and initial validation of a portable brain-computer interface (BCI) for objectively
71 fundus photographs taken with a nonmydriatic portable camera and a mydriatic standard camera.
72          The necessities of developing fast, portable, cheap and easy to handle pesticide detection p
73 fore, it may be useful in creating a: cheap, portable, chronic, dynamic, and precise all-electronic a
74 otential applications in minimally invasive, portable clinical diagnostic equipment.
75 tellite clocks testing general relativity to portable clocks for inertial navigation systems and rela
76                                            A portable colorimetric determination system based on G-qu
77  to capture 30 seconds of laser plume, and a portable condensation particle counter was used to measu
78                              During LHR, the portable condensation particle counters documented an 8-
79  design can be readily adapted to a low-cost portable configuration, which could find use in the oper
80 her with a bespoke, low-power, multichannel, portable data-acquisition system.
81 ltiplexed biomarker detection in a low cost, portable design.
82 e dual-particle imager (DPI) was used with a portable deuterium-tritium (DT) neutron generator to det
83 s the approach can be integrated into small, portable device architectures, and there is significant
84 is not easy to envisage the development of a portable device for in situ analyses based on these meth
85 cal sensors can be integrated as a part of a portable device for point-of-care immunosensing.
86 d Nanopore Technologies, is a USB-connected, portable device that allows real-time DNA analysis.
87             Subjects were then fitted with a portable device that delivered auditory click stimuli th
88 The Oxford Nanopore Technologies MinION is a portable device that uses nanopore technology that can d
89 t is amenable to incorporation into low-cost portable devices and could therefore be suitable for wid
90  efficient ways to save powers of the recent portable devices, but a serious drop of image-quality, s
91  and error-free data recovery from low-cost, portable devices, which is crucial for making the storag
92 ensitivity of the central visual field using portable devices.
93                                    Rapid and portable diagnosis of pathogenic bacteria can save lives
94  mouth and skin odor as a potential tool for portable diagnosis of trimethylaminuria is also illustra
95 dation of ironPhone, a mobile-device coupled portable diagnostics for quantification of serum ferriti
96 n of larger capacity carbon filters into the portable dialysis systems resulted in no further cases o
97 as associated with dialysis sessions using a portable dialysis unit in our hospital.
98 ce of chloramine from the tap water used for portable dialysis.
99 developed methemoglobinemia while undergoing portable dialysis.
100    Technology of displaying static images in portable displays, advertising panels and price tags pur
101 e device, which could be used as a one-step, portable, disposable, low-cost, simple, instrument-free
102 ensing, and have achieved notable success in portable DNA sequencing.
103 anodes are desirable for both stationary and portable electrical energy storage.
104 ned and developed a novel and cost effective portable electrochemical analyzer for the measurement of
105                              In this work, a portable electrochemical immunosensor capable of detecti
106   This limits the current cost-effective and portable electrochemical immunosensors in harsh environm
107 he results obtained here using the developed portable electrochemical nitrite analyzer were also comp
108                                      We used portable electroencephalogram (EEG) to simultaneously re
109 lace energy storage devices for miniaturized portable electronic applications.
110     Furthermore, pairing was achieved with a portable electronic device capable of delivering many mo
111 wer source for a range of devices, including portable electronic devices and electric vehicles, due t
112 ew high performance random access memory for portable electronic devices.
113 promise for nearly seamless integration with portable electronic devices.
114 uid crystals are widely used in displays for portable electronic information display.
115 romising approach towards the development of portable electronic point of sample analysis devices.
116 vanced rechargeable lithium-ion batteries in portable electronics and electric vehicles has spurred i
117             A solution is developed to power portable electronics in a wearable manner by fabricating
118 are highly desirable in fields of aerospace, portable electronics, and so on.
119  chemistries to meet the growing demands for portable electronics, electric vehicles and grid-scale e
120 ough lithium-ion batteries are ubiquitous in portable electronics, increased charge rate and discharg
121 age technology is of critical importance for portable electronics, transportation and large-scale ene
122 viable devices for next-generation wearable, portable electronics.
123 wered implanted medical devices and wearable/portable electronics.
124  EFs of the Iranian transportation system, a portable emission measurement system (PEMS) was used to
125                                We employed a portable emissions measurement (PEMS) to measure real-wo
126 sel equipped with SCR, were measured using a portable emissions measurement system (PEMS) in the Sacr
127                                      Using a portable emissions measurement system (PEMS), duty cycle
128 ilding-integrated optoelectronic devices and portable energy sources.
129                    Li-ion batteries dominate portable energy storage due to their exceptional power a
130 ecognizing binding events at low cost and in portable environments.
131 more complex measurements and treatments and portable equipment were scarce after standard working ho
132 RNAs and their targets thus emerge as highly portable, evolutionarily tractable regulatory modules th
133 : The Visual Fields Easy test procedure is a portable, fast, effective procedure for detecting modera
134 A&Anti-OTA structures were integrated within portable fiber optic detection system, what is important
135 e final goal would be development of a Raman portable fiber probe device for intraoperative optical b
136                                   This field-portable fluorescent imager on the smartphone involves a
137 ity of the captured FCNs was measured with a portable fluorescent reader.
138 anslatability of the sensor was shown with a portable form factor device, demonstrating a comparable
139 The DNA-sensor developed can be adapted to a portable format to be adopted as an easy-to- use and low
140 n in devices such as metal-air batteries and portable fuel cells has proven elusive.
141 amma-ray detection probe (GP; VITOM-GP) or a portable gamma-camera (GC; Vitom GC), clip-on brackets w
142 amma-ray detection probe (GP; VITOM-GP) or a portable gamma-camera (GC; Vitom GC), clip-on brackets w
143 , the coupling of these TFME devices to hand-portable gas chromatography toroidial ion trap mass spec
144                         With the use of hand-portable GC-TMS instrumentation, membranes cut with dime
145 dehyde was determined in car exhaust using a portable GC/MS.
146       We have developed a cost-effective and portable graphene-enabled biosensor to detect Zika virus
147 synthesize, assemble, and process their own "portable" HA-rich microenvironments to survive in the ci
148 hreat screening, (b) commercially available, portable (hand-held and stand-off) chemical detection sy
149 aturalistic environment (e.g., at home) with portable handheld topography devices.
150                                            A portable haptic display was tested in eight patients in
151                 The size is just as big as a portable hard drive.
152 .Anemia prevalence was 44% with the use of a portable hemoglobinometer during screening.
153                                            A portable high volume desorption module prototype was als
154  step towards the development of a low-cost, portable, high-precision diagnostic and monitoring techn
155 serve as a platform for the development of a portable, high-throughput device for use in the real-tim
156 ssay is accompanied by a smartphone-assisted portable imaging device that can autonomously perform th
157 itional sandwich lateral flow immunoassay, a portable imaging device, and a mobile interface, we demo
158 omography (DOT) is a relatively low cost and portable imaging modality for reconstruction of optical
159 plasmon resonance (SPR) biochip and a simple portable imaging setup for label-free detection of imida
160 lopment of highly sensitive, and potentially portable immunosensors suitable for fast determination o
161 mportant for the development of low cost and portable immunosensors.
162                      We have also designed a portable impedance analyzing device to connect the immun
163          Here we introduce a Rapid Adaptable Portable In vitro Detection biosensor platform (RAPID) f
164 ra of potato extracts were collected using a portable infrared system and partial least squares regre
165                                     Overall, portable infrared system with PLSR showed great potentia
166                     With the availability of portable instrumentation to accurately detect biological
167 n be implemented that allow miniaturized and portable instrumentation.
168                                              Portable instruments were compacted into a backpack to f
169 s particle captured on the substrate using a portable interface.
170                        CONCLUSION A modified portable isolation chamber, which conforms to CDC infect
171                       Here, we demonstrate a portable IVPA-US system capable of imaging at up to 25 f
172 l of this biosensor platform to be used in a portable "just-add-sample" format for near real-time det
173 at promise for the development of simple and portable lab-on-a-chip systems.
174 nduct reactions in a simple, inexpensive and portable "LAMP box" supplemented with a consumer class s
175 powered surgical laser diode is employed for portable laser diode thermal desorption (LDTD) at 940 nm
176 clinical ultrasound system integrated with a portable laser.
177 ions - a standard well-based paper kit and a portable layer-by-layer stick kit.
178 many of the results from these studies using portable low-cost equipment, focusing on the robustness
179 that allows for an accurate, reliable, field-portable, low-cost device for practical applications.
180                 Here, we present Seq-Well, a portable, low-cost platform for massively parallel singl
181                      We anticipate that this portable, low-cost, and scalable IM-PCR holds great prom
182 -modified NAA-RFs with RIfS can be used as a portable, low-cost, and simple system for establishing t
183       We report the development of a simple, portable, low-cost, high-throughput visual colorimetric
184  can be performed within 22 min using only a portable luminometer.
185 rganic analyses prior to analysis in a field portable mass spectrometer.
186 preparation, thus making MAI ideal for field-portable mass spectrometers.
187                               We developed a portable mass spectrometric system ("miniRuedi") for qua
188  and functionalization of an ion source for (portable) mass spectrometry (MS).
189 lymer substrate and easily integrated with a portable measurement unit, to carry out quantitative tro
190 sor would greatly facilitate applications in portable medical devices for on-the-spot diagnosis and e
191 requently done due to the lack of robust and portable methods.
192 rite can also be administered using a novel, portable micronebulizer system suitable for chronic use.
193 ptimized library preparation methods for the portable MinION sequencer (Oxford Nanopore Technologies)
194                                              Portable mobile and media devices have become a ubiquito
195 able apnea prediction score followed by home portable monitor testing for detecting severe OSA syndro
196  or prediction tools, diagnostic accuracy of portable monitors, or association between apnea-hypopnea
197                      The feasibility of many portable MS applications is facilitated by the availabil
198     The cartridge is read out by an original portable multichannel reader based on the magnetic parti
199              We demonstrate the potential of portable nanojets by imaging different sub-wavelength st
200      This study optimizes the application of portable Near Infrared-Acousto Optically Tunable Filter
201                        On the same fruits, a portable NIR device in diffuse reflectance mode was empl
202                                            A portable, nonmydriatic, fundus camera can facilitate rem
203                             In addition, MPA Portable now supports state-of-the-art database search e
204 dvances have been made in the development of portable nucleic acid amplification devices for near-pat
205 sis is hindered by the lack of sensitive and portable on-chip optical detection technology.
206                           Here, we present a portable, online, and disposable gas sensor platform for
207  as interesting candidates for the design of portable optical biosensor platforms considering the pot
208            We developed molecular assays and portable optical imaging designs that permit on-site dia
209 anufacturing systems are not compatible with portable or distributed production of biologics, as they
210 lts from laboratory experiments with a field portable oxidation flow reactor (F-OFR) to study the evo
211                                 Inexpensive, portable paper strips were designed for a rapid, on-site
212 grees Celsius), so the focus for vehicle and portable PEMFC applications has been on aqueous-phase re
213 roach and an easily adaptable protocol, this portable platform has the potential to be utilized as a
214                           Here, we present a portable platform that provides the means for on-site, o
215 it a suitable candidate for integration into portable platforms for POC and in resource-limited setti
216 thods that can be seamlessly integrated into portable platforms.
217       This new RT-iiPCR assay along with the portable POCKIT nucleic acid analyzer could provide a hi
218 c biosensors have recently been advanced for portable point-of-care diagnostics by integrating lab-on
219 r sensing NMP22 and their integration with a portable potentiostat in a homecare system may have grea
220                                            A portable potentiostat was assembled and a data acquisiti
221 orods electrodes that were integrated into a portable potentiostat, revealing NMP 22 concentrations i
222                                              Portable power sources and grid-scale storage both requi
223                                   Finally, a portable power-supplying system, which provides enough d
224 ptical components are mounted on a 10cmx10cm portable prototype, illustrating its facile miniaturizat
225                                              Portable purification systems are easy ways to obtain cl
226 e invented Eigen Diagnosis Platform (EDP), a portable quantitative immunoassay platform based on Gian
227 nstration would pave a way for a compact and portable quantum device required for quantum information
228       When this method is fully developed, a portable Raman instrument could be used for the infield
229 eshness assessment could be achieved using a portable Raman instrument.
230       Here we show for the first time that a portable, random-access platform may be implemented in p
231 combined with the increasing availability of portable, random-access sequencing technology, offer the
232 ort with the United States Army to develop a portable, rapid drug detection device.
233 resistive (GMR) biosensors integrated with a portable reader system and smartphone to detect THC in s
234 netization at combinatorial frequencies by a portable reader that offers the detection limit of 60 ze
235 sm's bio-attacks have promised the future of portable real-time quantitative polymerase chain reactio
236                                    Recently, portable, real-time, nanopore sequencing (RTnS) has beco
237 (F-Wood/CNTs) is demonstrated as a flexible, portable, recyclable, and efficient solar steam generati
238 cond advance: the development of a low cost, portable red cell analyzer to measure these parameters.
239 igns could be expanded to other organisms as portable regulatory resources or to implement biological
240                               Development of portable, reliable, sensitive, simple, and inexpensive d
241                                 The airborne portable remote imaging spectrometer (PRISM) was used to
242  present the development and validation of a portable, robust and inexpensive electrochemical magneti
243 hysical Performance Battery (SPPB) and Short Portable Sarcopenia Measure (SPSM).
244 hysical Performance Battery (SPPB) and Short Portable Sarcopenia Measure (SPSM).
245 ells), a 3 muL plasma sample was imaged by a portable scanner and analyzed through a custom algorithm
246 mine whether there is an association between portable screen-based media device (eg, cell phones and
247                                              Portable sensing of trimethylamine vapors at ppb concent
248                 It is desirable to develop a portable sensitive sensing platform for on-site screenin
249          To help prevent outbreaks, a rapid, portable, sensitive, and reliable method for onsite dete
250                        Therefore, developing portable, sensitive, selective, and cost-effective sensi
251 ensitive filter-based laboratory methods and portable sensors for near real-time measurement of cryst
252 n be used to produce simple, fully automated portable sensors for the in situ determination of H2S in
253 lution monitoring encourage a growing use of portable sensors.
254  through addressing, and leverages efficient portable sequencing via new iterative alignment and dele
255 -field imaging in a cost-effective and field-portable setup, making it a promising technique for poin
256 cus on recent advancement towards developing portable, simple and efficient alcohol sensors.
257 Therefore, there is an unmet need to develop portable, simple, rapid, and accurate methods for PoC de
258 owards that application, we have developed a portable single-cell system that is comprised of a micro
259                                          Our portable single-cell system will potentially have broad
260                              The MinION is a portable single-molecule DNA sequencing instrument that
261 y, we present a simple, sensitive, rapid and portable smartphone based fluorescence device for E. col
262 the working of a low cost, robust, and field portable smartphone platform fluoride sensor that can de
263  artifacts, would allow fast, sensitive, and portable SNP detection with single-nucleotide resolution
264 ere introduce the MetaProteomeAnalyzer (MPA) Portable software.
265 e most promising solutions for renewable and portable solar energy generation and other related phase
266                          Rapid, low-cost and portable solution is in highly demand for point of care
267 at provide cost-effective, fast, simple, and portable solutions for health and environmental applicat
268     Comparison with a commercially available portable spectrometer and an optical spectrum analyzer s
269 ctrometry methods have the potential to make portable spectrometers small, ubiquitous, and cheap.
270 s such as ion selective electrodes (ISE) and portable spectrophotometers are commercially available f
271                     The VP1 detection in the portable SPR biosensor had a detection limit of approxim
272 herefore, there is a need to generate a new, portable, standardized, and more advanced system that pr
273                    The key requirement for a portable store of natural gas is to maximize the amount
274  Here, we describe a rapid, inexpensive, and portable strategy to robustly re-identify human DNA call
275  We have developed a simple, cost-effective, portable surface enhanced Raman scattering (SERS) approa
276 us to test non-specific interference using a portable surface plasmon resonance (SPR) biosensor (SPIR
277 thod for human enterovirus 71 (EV71) using a portable surface plasmon resonance (SPR) system.
278 iosensor to detect B. cereus and to become a portable system for food quality control.
279                             It consists in a portable system for on-site detection composed of three-
280 ntegrated optical pH and oxygen sensors in a portable system for on-site detection.
281                                            A portable system for sensitive and quantitative detection
282 r to solve this problem, here we developed a Portable System for the Analysis of Metabolic Models (PS
283 loped with the purpose in mind of creating a portable system that could be easily moved to various te
284 hieved by exploiting a simple, economic, and portable system with spectrophotometric detection.
285 and sequencing has emerged as a competitive, portable technology.
286 this method with a hand-held luminometer for portable testing.
287 llization point, unlocking opportunities for portable thermal energy storage systems.
288 ion of the mutations appears to be generally portable to other synthetic antibodies and may serve as
289 ant steps for the implementation of these as portable tools in an out-of-lab setting.
290                           With the advent of portable touchscreen devices, this association may be ex
291  extraction of VOCs from the headspace using portable tubes is described.
292                    Paper-based devices are a portable, user-friendly, and affordable technology that
293 eye or imaged by a smartphone camera under a portable UV light source.
294 used to develop of disposable, low cost, and portable various types of dehydrogenase based biosensor
295  could be extended to various electrodes for portable/wearable electronics.
296 o utilize ambient mechanical energy to drive portable/wearable/implantable electronics.
297 ography (LDIH) is a promising technology for portable, wide field-of-view imaging.
298  ME antennas have potential implications for portable wireless communication systems.The miniaturizat
299                  In this paper, we present a portable wireless electrocorticography (ECoG) system.
300 tals, with 12 fixed x-ray machines (23%), 11 portable x-ray machines (13%), 13 computed tomographic s

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