ライフサイエンスコーパス: CO2 laser

1 60-nm coating) than that obtained using the CO2 laser.

2 issociated using infrared irradiation from a CO2 laser.

3 angina underwent TMR as sole therapy with a CO2 laser.

4 9.3, 9.6, 10.3, or 10.6 microm) of a tunable CO2 laser.

5 te the shallower depth of penetration of the CO2 laser.

6 onsidered before treatment with fractionated CO2 lasers.

7 A carbon dioxide (CO2) laser (1.75 W) delivered a uniform disk of continuo

8 (two sites per patient), "epithelial-peel" (CO2 laser, 2 to 4 W, continuous wave),and "brushstroke"

9 ed with lasers show variable response rates (CO2 laser, 50%-100%; Er:YAG laser, 72%-100%; PDL, 47%-10

10 Using a 15-W (14)CO2 laser, a linear calibration with samples from 10(-15

11 deeply infiltrative endometriosis undergoing CO2 laser ablative surgery with bowel resection (study g

12 We used a fractional CO2 laser and anti-PD-1 inhibitor to treat a tumor estab

13 the side of the separation capillary with a CO2 laser and then coating the holes with cellulose acet

14 Both holmium:YAG and CO2 lasers are associated with increased MWC and impaire

15 the laser treated sites, those irradiated by CO2 laser at 5 W (780 J/cm2) exhibited the greater amoun

16 ); 2) a positive control (bur osteotomy); 3) CO2 laser at 5 W (860 J/cm2); 4) CO2 laser at 6 W (1,032

17 eotomy); 3) CO2 laser at 5 W (860 J/cm2); 4) CO2 laser at 6 W (1,032 J/cm2); 5) Nd:YAG laser at 5 W (

18 the gold standard; however, Er:YAG laser and CO2 lasers can be effectively used but with distinct dif

19 face of hydrophobically coated glass through CO2 laser cleaning.

20 layer architectures using a laser printer, a CO2 laser cutter, an office laminator and common overhea

21 surgical blade or a 150-Watt continuous-wave CO2 laser deflected by an x-y galvanometric scanner that

22 Several laser technologies have altered the CO2 laser delivery system, making it useful for the trea

23 imply that higher absorption coefficient for CO2 laser energy results in greater focal temperatures a

24 In addition to the CO2 laser energy source used in early studies, trials of

25 A CO2 laser engraving machine was used to make the channel

26 We present a CO2 laser engraving technique for the rapid prototyping

27 small holes made in polyester sheets using a CO2 laser etching system.

28 The method utilizes a CO2-laser fluorination system that can also be used to q

29 Although CO2 lasers have been used in medicine for almost 30 year

30 Continuous-wave CO2 lasers have performed poorly as tools for burn excis

31 Here we use a CO2 laser heating approach and direct-current SQUID magn

32 f the left ventricle through the use of both CO2 laser in 1 region and a power drill in the alternate

33 ted by irradiation at 10.6 microns from a CW CO2 laser in the source region of the mass spectrometer.

34 ese settings may cause shallower injury than CO2 lasers in humans undergoing clinical treatment.

35 We previously reported that CO2 laser incisions in carcinogen-initiated fields promo

36 By means of isomer-selective heating by a CO2 laser, infrared predissociation spectra of both the

37 bossed, molded, templated, and/or cut with a CO2 laser into a variety of intricate patterns.

38 The thermal load created by CO2 laser irradiation creates a characteristic spectrum

39 first, to evaluate the histologic effects of CO2 laser irradiation on biopsies of porcine oral mucosa

40 of SiGe-core optical fibres, and the use of CO2 laser irradiation to heat the glass cladding and rec

41 band optical interferometry before and after CO2 laser irradiation.

42 measuring corneal surface temperature during CO2 laser irradiation.

43 ative fractional photothermolysis (aFP) with CO2 laser is used for a wide variety of dermatological i

44 sing multiple transparency layers in which a CO2 laser is used to remove the polyester from the chann

45 Clinical outcome after CO2 laser laparoscopic excision of moderate-severe endom

46 The surface changes demonstrated with the CO2 laser likely are indicative of temperature-induced t

47 ricated in polycarbonate plastic material by CO2 laser machining and were assembled using a combinati

48 lges formed at the rim of the channel during CO2 laser micromachining by passing the laser beam throu

49 of hobby laser engravers/cutters, the use of CO2 laser micromachining on poly(methyl methacrylate) (P

50 the feature size created by most entry-level CO2 laser micromachining systems is too large to become

51 white (NZW) rabbits underwent treatment with CO2 laser (n=18), Nd:YAG laser (n=18), or sham thoracoto

52 150-nm coatings of oleic acid using either a CO2 laser or a tunable optical parametric oscillator as

53 application of new technologies, such as the CO2 laser, or molecular biology, such as muscle cell tra

54 to these intuitively appealing results, high CO2 laser powers (approximately 90 mJ/pulse) produce mas

55 Histopathologically, the resurfacing CO2 lasers produce morphologic alterations similar to me

56 lling the column outlet to a fine tip with a CO2 laser puller, and slurry-packing the column with 5-m

57 wood into hierarchical porous graphene using CO2 laser scribing.

58 thylene molecules using a wavelength-tunable CO2 laser steers the chemical reactions and promotes pro

59 These findings demonstrate that the CO2 laser stimulates angiogenesis in normal ovine myocar

60 Fractionated, ultrapulsed carbon dioxide (CO2) laser therapy is a powerful tool for the treatment

61 These changes were not seen after CO2 laser TMR.

62 ore robust and quantitative analysis using a CO2 laser to evaporate the aerosol particle and a vacuum

63 ht of 35 (22.8%) and four of 20 (20%) of the CO2-laser-treated sites showed clinical and histologic r

64 tions secondary to ultrapulsed, fractionated CO2 laser treatment in a patient previously treated with

65 2 unreported adverse effects of ultrapulsed CO2 laser treatment of mature scars in a patient previou

66 appreciated on biopsy specimens taken before CO2 laser treatment, suggesting unique complications not

67 ss spectra are compared to those obtained by CO2 laser vaporization followed by VUV laser ionization.

68 s used for pruritus and erythema; fractional CO2 laser was used for stiffness and abnormal texture.

69 tomy defects created either by a dental bur, CO2 laser with and without removal of the char layer, an

70 bur with simultaneous saline irrigation; 2) CO2 laser with char layer intact; 3) CO2 laser with char

71 ion; 2) CO2 laser with char layer intact; 3) CO2 laser with char layer removed; 4) Nd:YAG laser with