ライフサイエンスコーパス: diode laser

1 ed to RFA (VNUS ClosureFAST) or EVLT (810-nm diode laser).

2 V was induced in the Brown-Norway rat with a diode laser.

3 burns in the choroid of each eye with a red diode laser.

4 ature and/or the driven current of the input diode laser.

5 energy delivered to the area using a 689 nm diode laser.

6 fixed additional gain below threshold of the diode laser.

7 ium and an intracavity antireflection-coated diode laser.

8 r general or local anesthesia with an 810 nm diode laser.

9 ntium oxide irradiated by a simple low power diode laser.

10 We delivered TTT with an infrared diode laser.

11 temperature, optically pumped by using a cw diode laser.

12 ve deepithelialization with either Er:YAG or diode laser.

13 rication and utilizes only a single low-cost diode laser.

14 l rupture of Bruch's membrane with an 810-nm diode laser.

15 latively low cost, portable, battery-powered diode lasers.

16 n fermionic systems including widely applied diode lasers.

17 histologic changes from both 532- and 810-nm diode lasers.

18 threshold, highly unidirectional microcavity diode lasers.

19 -implantitis were treated with either 970 nm diode laser (1.2 W, continuous wave) or mucosal flap sur

20 Here, we use a pulsed diode laser (1.94 microm) to stimulate auditory neurons

21 s applied to the mouse fundus using a 532-nm diode laser (100, 150, and 200 mW; 100-mum diameter, 0.1

22 A simple optical system, comprising a diode laser (405 nm), an optical lens, a 515-nm-long pas

23 strument was constructed by using two pulsed-diode lasers (680/780-nm excitation) and two avalanche p

24 2.5 mg/mL WST-D and was illuminated by a NIR diode laser (755 nm, 10 mW/cm(2)).

25 se and postoperative pain after the use of a diode laser (810 nm) (DL) as an adjunct to modified Widm

26 aPDT included ICG dye and diode laser (909 nm) performed together with SRP and rep

27 citation of the fluorescent label by a small diode laser, a CCD camera detects the pattern of fluores

28 The device utilized a 780-nm pulsed diode laser, a single-photon avalanche diode (SPAD), and

29 of a cavity-enhanced, near-infrared tunable diode laser absorption spectrometry system capable of qu

30 e developed a new method, coupling a tunable diode laser absorption spectroscope with a gas-exchange

31 response curves in real-time using a tunable diode laser absorption spectroscope.

32 in the light, in real-time, using a tunable diode laser absorption spectroscope.

33 racteristics using a system based on tunable diode laser absorption spectroscopy (TDIAS).

34 mic K in flames is implemented using tunable diode laser absorption spectroscopy at 769.9 nm and a hi

35 the concentrations of atomic K using tunable diode laser absorption spectroscopy, both at 404.4 and 7

36 ental of C7 are probed by gated detection of diode laser absorption.

37 y was achieved by multiple treatments with a diode laser adapted to a slit lamp biomicroscope.

38 tive pill was superior to the application of diode laser alone, just as the addition of metformin to

39 A diode laser (aluminum-gallium-arsenide, 660 nm) was appl

40 er thermal keratoplasty using the Holmium or diode laser and contact techniques also have gained popu

41 er treatment was comparable between infrared diode laser and conventional surgery, with emphasis on t

42 esorption by a continuous wave near-infrared diode laser and ionization by a dielectric barrier disch

43 e the basis of modern light-emitting diodes, diode lasers and high-speed transistors.

44 th is, however, much wider than those of the diode lasers and the SLEDs.

45 e device applications such as light emitting diodes, lasers and optical modulators.

46 cally pumped ultraviolet-blue light-emitting diodes, lasers and photodetectors.

47 two identical CRDS systems with one 408.5-nm diode laser, and their difference gave the amplified NO2

48 ced singlet oxygen once sensitized by 680 nm diode lasers, and the QPs, conjugated with antibodies, a

49 al elements in photovoltaics, light-emitting diodes, lasers, and photocatalysts due to their tunable

50 (NCs) for use in solar cells, light emitting diodes, lasers, and photodetectors.

51 velopment of highly efficient light-emitting diodes, lasers, and solar cells based on 2D materials.

52 Here, we show that blue-diode laser annealing dramatically improves mechanical p

53 luate the effectiveness of adjunctive use of diode laser application to SRP.

54 al range, similar in operation simplicity to diode lasers, are highly desired for applications.

55 was to evaluate the clinical efficacy of the diode laser as an adjunct to scaling and root planing (S

56 study is to evaluate the effect of a 980-nm diode laser as an adjunct to scaling and root planing (S

57 emperature by simply using a continuous-wave diode laser as an optical pumping source.

58 photochemical properties and an inexpensive diode laser as light source, we produce hydrated electro

59 spectroscopy (CERS) with optical feedback cw-diode lasers as a sensitive analytical tool.

60 proach that uses recently available infrared diode lasers as heat sources.

61 r induced deeper gingival tissue injury than diode laser, as judged by bleeding at surgery, delayed h

62 Herein, a novel diode laser-assisted micro-pyrolysis program (LAMP) tech

63 tcomes of external, endoscopic endonasal, or diode laser-assisted transcanalicular DCR in adults with

64 id not improve outcomes statistically in any diode laser-assisted transcanalicular DCR studies.

65 g-down spectroscopy (CRDS) technique using a diode laser at 644 nm and a right-angled prism for evane

66 rom 1500 to 1600 nm) when it is excited by a diode laser at 980 nm.

67 se of 6 mg/m(2) body surface area and 689 nm diode laser at an intensity of 600 mW/cm(2) for 83 secon

68 We present a tunable diode laser atomic absorption spectroscopy (TDLAAS) meth

69 th an extremely accurate and precise tunable diode laser-based absorption spectrometer showed that th

70 A simple diode laser-based fluorescence system capable of interro

71 the amenability of the technique to compact, diode laser-based instrumentation.

72 H(3) concentrations based on a near-infrared diode laser-based photoacoustic system.

73 A diode laser beam, incident upon and illuminating the ent

74 Diode lasers can remove granulation tissue and submucosa

75 trometer employing a near-IR external cavity diode laser capable of measuring 13C/12C isotopic ratios

76 illion by volume (ppmv) concentrations using diode laser cavity enhanced absorption spectroscopy.

77 ity was found to be comparable with those of diode lasers currently available for this near-IR region

78 , trabeculectomy in 2 eyes, and transscleral diode laser cyclophotocoagulation in 1 eye.

79 urgical option in three of the patients, and diode laser cyclophotocoagulation was applied to one pat

80 Seven eyes underwent diode laser cyclophotocoagulation; 4 required repeat tre

81 le mid-infrared distributed feedback tunable diode lasers (DFB-TDL), provide 1 s ethane measurements

82 cal advances in screening tools and portable diode lasers enable ophthalmologists to provide prompt,

83 With 10 mW of 636.2 nm diode laser excitation and 30 s integration time, cavity

84 dispersive Raman spectrometer, using 785-nm diode laser excitation.

85 ty ring-down spectroscopy with near-infrared diode laser excitation.

86 (FTMH) in the right eye following accidental diode laser exposure during a hair removal procedure at

87 0-second, 0.78-mm spot size, 810-nm infrared diode laser exposures with power settings ranging from 5

88 of 6 mg/m(2) body surface area and a 689 nm diode laser for 83 seconds.

89 ction of 30-50 pg/mL in immunoassays using a diode laser for excitation and a PMT for detection.

90 detection system, which includes a miniature diode laser for excitation.

91 This study highlights the efficacy of diode laser for photoablative deepithelialization of hyp

92 ed laser for ablation and counter-propagated diode laser for saturated absorption, enabling preparati

93 Using a widely tunable external cavity diode laser, four nearby wavelengths within the range of

94 dal neovascularization was induced by 532-nm diode laser in C57BL/6 mice.

95 ive study was to evaluate the 655-nm InGaAsP diode laser in detecting subgingival calculus in patient

96 d wavelengths, enabling the use of low-power diode lasers in future devices.

97 spectroscopy (CERS) with optical feedback cw-diode lasers in the gas phase, including a new mode-matc

98 , and the labeled antibody was detected with diode laser-induced fluorescence.

99 st wooden (bio)sensing device fabricated via diode laser-induced graphitization.

100 t irrigation with methylene blue, and 660-nm diode laser irradiation at 100 mW for 50 s.

101 diation power (P < 0.001), especially if the diode laser irradiation was associated with the applicat

102 Because the diode laser is fusion-spliced directly to the doped fibe

103 A hand-held diode laser is implemented for solid sampling in portabl

104 The use of the diode laser is motivated by its low cost, ease of use, a

105 CERS with low power diode lasers is suitable for online monitoring of natura

106 th two additional treatments with micropulse diode laser (IVOM+Laser-Group; n = 10).

107 re randomly divided into two groups as SRP + diode laser (L) (0.80W power, 940 nm wavelength and 0.80

108 Using a pulsed diode laser (lambda=1.85 microm, tau(p)=2 ms, 50 Hz, H=7

109 Low-power (2.0- to 4.5-W) diode laser light (805 nm) diffused within tissue induce

110 Hence, the 655 nm diode laser may be used as an additional tool for calcul

111 Three treatments with the 810-nm diode laser may induce significant improvements in skin

112 Applying the diode laser, molten substrate material is incorporated i

113 ate if a combination therapy with micropulse diode laser (MPL) shows non-inferiority on visual acuity

114 heres versus infrared light at 810 nm from a diode laser on multispecies oral biofilms in vitro.

115 of different energy sequences from a 1467 nm diode laser operated at 1k Hz.

116 ration with excitation provided by a near-IR diode laser operating at 750 nm.

117 cavity where it is probed by a near-infrared diode laser operating at approximately 1670 nm.

118 A diode laser (operating at 675 nm with a retinal power de

119 lesions 6 months after treatment with either diode laser or conventional mucosal flap surgery.

120 This dual-channel diode-laser PERCA-CRDS instrument was compact and capabl

121 time and at different levels of energy using diode laser photocoagulation coupled with an intraocular

122 retreating the retina with heat via infrared diode laser prior to the induction of CNV.

123 ured by monitoring the deflection angle of a diode laser probe beam, which is orthogonal to both the

124 engraver, equipped with a low-power (0.5 W) diode laser, programmably irradiates the surface of the

125 The use of an 810-nm diode laser provided additional benefits to MWF surgery

126 e to 10-50 J cm(-2), 30 milliseconds, 800 nm diode laser pulses, microscopy revealed preferential the

127 ics for delivery and return of low intensity diode laser radiation to and from the measurement chambe

128 m Gallium Arsenide Phosphide (InGaAsP) based diode laser radiation to be a useful tool to detect subg

129 in order to absorb the energy offered by the diode laser radiation.

130 stems based on laser ablation, it uses a NIR diode laser rather than an expensive high-energy pulsed

131 relay optics onto which was mounted a pulsed diode laser (repetition rate 80 MHz, lasing wavelength 6

132 varnish application + 0.5 W, 0.7 W, and 1 W diode laser, respectively).

133 roup): G1, G3, and G5 (0.5 W, 0.7 W, and 1 W diode laser, respectively); G2, G4, and G6 (fluoride var

134 The use of diode laser showed additional advantages compared to Er:

135 ws that the intralesional 1470 nm bare-fibre diode laser significantly improved hypertrophic and kelo

136 haracteristics for high-power light-emitting-diodes, lasers, single-molecular tracking, super-resolut

137 both modes by broadening the linewidth of a diode laser source by application of a radio frequency p

138 observed by using a supersonic cluster beam-diode laser spectrometer.

139 ite, have been measured by direct-absorption diode-laser spectroscopy.

140 re was determined by lateral deflection of a diode laser spot.

141 Lead-salt tunable diode lasers (TDLs) are the only devices currently avail

142 only white light and also with only a 655-nm diode laser that causes calculus to fluoresce.

143 e laser system uses a single extended cavity diode laser that gives enough power for interrogating th

144 er testing with a high-pulse-repetition-rate diode laser that, when applied to melanoma, is free of t

145 Upon irradiation with 690 nm diode laser, the aminoacrylate linker of the prodrug was

146 By including an additional diode laser, the instrument can be extended to make simu

147 itional near-infrared, distributive feedback diode lasers, the instrument can also be extended to oth

148 oot planing (SRP) plus the adjunctive use of diode laser therapy to SRP alone on changes in the clini

149 Diode laser therapy was applied to periodontal pockets o

150 group-IV photonic active devices, including diode lasers, thereby significantly limiting our ability

151 ductively coupled mass spectrometry (ICPMS), diode laser thermal vaporization (DLTV) is described.

152 with local treatments for 31 patients (86%): diode laser thermotherapy for all of them and cryotherap

153 Melphalan SOAC associated with diode laser thermotherapy, cryotherapy, or both at 4-wee

154 405 nm continuous wave (CW) ultraviolet (UV) diode laser to a three-dimensionally (3D) printed low-te

155 rt of a feedback loop, we stabilize a 780 nm diode laser to achieve a linewidth better than 1 MHz.

156 ult rats and mice were photocoagulated using diode laser to induce CNV.

157 nt received treatment with the 810-nm pulsed diode laser to the arm randomized to be the treatment si

158 -division multiplexing, enhanced optics, and diode lasers to maximize light capture and minimize opti

159 Novel laser applications (micropulse diode laser trabeculoplasty, titanium sapphire laser tra

160 nt of erythema and texture in KP may require diode laser treatment combined with other laser or medic

161 Diode laser treatment of ICG saturated episcleral veins

162 e eye of 35 adult Wistar rats by translimbal diode laser treatment to the trabecular meshwork.

163 reen (ICG) dye into the anterior chamber and diode laser treatment.

164 investigated the effectiveness of a 1470 nm diode laser using an intralesional optical fibre deliver

165 The 655-nm diode laser was able to detect subgingival calculus.

166 equently, a more robust distributed feedback diode laser was employed to tune the laser wavelength on

167 rol quadrants (control groups [CG]), and the diode laser was used adjunctively with SRP in contralate

168 After the solder was placed on the wound, a diode laser was used to activate the solder, resulting i

169 A near-infrared diode laser was used to excite efficiently the SERS sign

170 A 640-nm diode laser was used to generate the illumination beam,

171 ed with a IV-VI semiconductor tunable mid-IR diode laser was used to make sensitive measurements of b

172 tment modalities: hydrosoluble chlorine plus diode laser (wavelength 662 nm, power 100 mW, continuous

173 Diode laser welding was performed, supporting standard s

174 ely 417 nm) of a single-mode external cavity diode laser, which was continuously scanned across the c

175 The combination of diode laser with either metformin or combined oral contr

176 x dynamical system using a photonic neuron-a diode laser with external optical feedback.

177 with a fiber-coupled near-infrared (808 nm) diode laser with laser power of 0.56 W/cm(2) for 3 minut

178 multiple adjunctive applications of a 980-nm diode laser with SRP showed PD improvements only in mode

179 Moreover, the incorporation of the miniature diode laser with the self-contained biochip design allow

180 ced unilaterally in 174 Wistar rats, using a diode laser with wavelength of 532 nm aimed at the trabe

181 ich we use for absolute frequency-locking of diode lasers with very high signal-to-noise ratios.

182 whether generated by a contact heat probe or diode laser), with no change in their response to noxiou

183 ptical fiber was attached to a 15-mW, 635-nm diode laser, with a thumbscrew connector.

184 root dentin after irradiation with a 980-nm diode laser, with or without associated fluoride varnish

185 ity, effectively creating an external cavity diode laser within which spontaneous Raman scattering en

186 echnologies such as solid-state lighting and diode lasers, yet there is no analogous MOCVD process fo