ライフサイエンスコーパス: ionomer

1 a sensing film of Nafion perfluorosulfonate ionomer.

2 when furcation areas are sealed with a resin-ionomer.

3 n the ionomer peak, for similarly structured ionomers.

4 Aquivion ionomers (790 EW, 830 EW and 980 EW) received in the pro

5 tylammonium bromide (TBAB) to neutralize the ionomer and expand the size of ionic domains for enzyme

6 esion was restored with resin-modified glass ionomer and root coverage was obtained by a lateral slid

7 lecular-scale structural characterization of ionomers and proteins within biocatalytic membranes to a

8 arly three-fold that of resin-modified glass ionomer, and matched/exceeded a composite with little F

9 s, the extents of ionic aggregation of these ionomers are comparable at elevated temperatures.

10 The anchoring of the ionomer-based plastic antibody on the catalyst surface f

11 ing electrolyte in concert with a conjugated ionomer can be used to control redox chemistry by govern

12 estorative material (Biodentine) and a glass-ionomer cement (GIC) with dentin have been studied by co

13 luoride-containing composite (FC), and glass-ionomer cement (GIC).

14 um silicate cement (Biodentine) versus glass ionomer cement (GIC; control group) as indirect pulp cap

15 ease of fluoride from a resin-modified glass-ionomer cement (KetacFil).

16 Glass ionomer cement appears to be a viable, biocompatible mat

17 buccal cup was further stabilized with glass ionomer cement placed on the crown and over the outer su

18 s successfully treated with the use of glass ionomer cement to restore the lesion, and facilitate sub

19 he fluoride-containing amalgam and the glass-ionomer cement, even after a two-week aging process, can

20 acks the dental tissues as well as the glass-ionomer cement.

21 e rate of release of fluoride from the glass-ionomer cement.

22 Bioactive glass ionomer cements (GICs) have been in widespread use for a

23 Glass-ionomer cements (GICs) have been widely used for over fo

24 Due to their good biocompatibility, glass ionomer cements are an interesting restorative option.

25 that the lower mechanical strength in glass ionomer cements results not only from the presence of po

26 ental restorative materials, including glass-ionomer cements, for the specific purpose of leaching fl

27 gh quite well investigated for decades, PFSA ionomers' complex behavior, along with their key role in

28 A), zinc-oxide eugenol cement (ZOEC), hybrid ionomer composite resin (HICR), reverse-transcriptase po

29 The model ionomers contain periodically or randomly spaced charged

30 Mass transport of oxygen through an ionomer contained within the cathode catalyst layer in a

31 es of DNA with the poly(ester sulfonic acid) ionomer Eastman AQ38S or by covalent binding of DNA onto

32 -healing poly (ethylene co-methacrylic acid) ionomers (EMAA) are thermoplastic materials that when pu

33 Both the Na and Cs ionomers exhibit thermally reversible transformation upo

34 ing ORR mass transport parameters using thin ionomer films was evaluated by numerical modeling of the

35 n exchange membrane (AEM) and catalyst layer ionomer for hydroxide ion conduction were used without t

36 hich the oxygen depletion region reached the ionomer/gas interface during the chronoamperometric anal

37 lts indicated that the C-16 alkyl side chain ionomer had a slightly better initial performance, despi

38 Scattering from semicrystalline, precise ionomers has contributions from acid layers associated w

39 Cells with MWNT + ionomer hybrid electrodes showed higher H(+) mobility, a

40 When benchmarked against the 1100 EW Nafion ionomer in glucose/air enzymatic fuel cells (EFCs), EFCs

41 e improved by incorporating a highly durable ionomer in the catalyst layer and optimizing the water f

42 These cationic polymers were employed as ionomers in catalyst layers for alkaline fuel cells.

43 s relative to Nafion is traced to effects of ionomer ion-exchange capacity (IEC, where IEC = EW(-1)),

44 yltriethoxysilane and 5% perfluorosulfonated ionomer) is characterized by the calibration graph, whic

45 processed Nafion and related perfluoroalkyl ionomer materials containing phosphonate and phosphinate

46 se-grained molecular dynamics simulations of ionomer melts with varying polymer architectures and com

47 sent the excess ion depth profiles of ILs in ionomer membrane actuators (Aquivion/1-butyl-2,3-dimethy

48 itude upon reducing the water content of the ionomer membrane by lowering the relative humidity.

49 hnique, transmission measurements can sample ionomer membrane materials more uniformly and suffer les

50 (*)) radicals with perfluorinated sulfonated ionomer membrane, Nafion 211, is described.

51 eters are correlated to water content of the ionomer membrane.

52 ransmission infrared spectroscopy studies of ionomer membrane.

53 ard this, we modified perfluorosulfonic acid ionomer membranes with organic pyrenol-based photoacid d

54 study focuses on changes in the structure of ionomer membranes, provided by the 3M Fuel Cells Compone

55 gradation of perfluorosulfonated acid (PFSA) ionomer membranes.

56 microg/(cm(2) x day) of resin-modified glass ionomer (p > 0.1).

57 The low wavevector ionomer peak in the counterion scattering is observed fo

58 The characteristic 'ionomer peak' arises from long parallel but otherwise ra

59 onomers that show the same two trends in the ionomer peak, for similarly structured ionomers.

60 is relates to various models used to fit the ionomer peak, is quantified and discussed.

61 Here I show that the perfluorosulphonic acid ionomer (PFSA), which has only one broad reversible phas

62 electrocatalysts, gas diffusion media (GDM), ionomers, polymer electrolyte membranes (PEMs), and elec

63 For that, the ionomer present in the anode catalytic layer of the DMFC

64 e precisely controlled acid spacing in these ionomers reduces the polydispersity in the aggregate cor

65 FCs containing the short side chain Aquivion ionomers relative to Nafion is traced to effects of iono

66 r in combination with a resin-modified glass ionomer restoration (CTG+R).

67 eral sliding flap and a resin-modified glass ionomer restoration in an HIV-positive individual.

68 obliterating the furcation utilizing a resin ionomer restoration.

69 ellent results when treating furcations with ionomer restorations.

70 erage was obtained on a resin-modified glass ionomer-restored surface in an HIV-positive individual.

71 One resin-modified glass-ionomer (RMGI) (Ketac Nano, 3M ESPE), 2 compomers (Dyrac

72 e cariostatic effect of resin-modified glass ionomer (RMGI) on secondary root caries is well-document

73 Resin-modified glass ionomers (RMGI) set by at least 2 mechanisms dependent u

74 recently available short side chain Aquivion ionomers spanning a range of equivalent weight (EW) suit

75 )-neutralized poly(ethylene-co-acrylic acid) ionomers that show the same two trends in the ionomer pe

76 The structure of the Nafion ionomer used in proton-exchange membranes of H(2)/O(2) f

77 Using an open flap procedure, a resin-ionomer was placed into all 3 furcation defects.

78 Individual segments of the ionomer were monitored to show that the backbone is resi

79 hodes prepared from TBA(+) modified Aquivion ionomers were able to reach maximum power densities (Pma

80 he ionic aggregates in an amorphous, precise ionomer with 22 mol % acid and 66% neutralization adopt

81 aggregate self-assembly onto a lattice in an ionomer with an all-carbon backbone.

82 ayer of the DMFC is partially replaced by an ionomer with molecular recognition capability working as

83 aluate changes in chemical structure of PFSA ionomers with a much higher degree of certainty than pre

84 y(ethylene-co-acrylic acid) zinc-neutralized ionomers with either precisely or randomly spaced acid g

85 rved for all systems, and it is sharpest for ionomers with periodically spaced pendant charged beads

86 A series of sulfonate polyester ionomers with well-defined poly(ethylene oxide) spacer l