ライフサイエンスコーパス: resorbable

1 s graft materials and barrier membranes (non-resorbable and bioabsorbable) have been used in GBR.

2 of implants placed in bone regenerated with resorbable and non-resorbable membranes.

3 g materials, guided tissue regeneration with resorbable and nonresorbable membranes, coronally positi

4 the native tissue of interest and should be resorbable as well as biocompatible.

5 pective multi-center study was to evaluate a resorbable barrier membrane designed for periodontal reg

6 expanded polytetrafluoroethylene (ePTFE) non-resorbable barriers and polylactic acid bioabsorbable ba

7 10% porcine collagen fibers combined with a resorbable bilayer membrane composed of non-cross-linked

8 Porous, resorbable biomaterials can serve as temporary scaffolds

9 have been difficult to mimic using synthetic resorbable biomaterials.

10 t electronics, has potential applications in resorbable biomedical devices, eco-friendly electronics,

11 This work presents a chitosan based resorbable biostrip for label-free electrochemical detec

12 The presented resorbable biostrip offers a limit of detection of 10pM

13 iologic blasting, 3) plasma, 4) microblasted resorbable blasting media (microblasted RBM), and 5) alu

14 CAM, when applied to a 3-dimentional printed resorbable calcium-triphosphate/hydroxyapatite scaffold

15 devices compares favourably with that of non-resorbable clinical standards.

16 using freeze-dried bone allograft (FDBA) and resorbable collagen membrane (FDBA/CM).

17 d, third, and fourth mandibular premolars; a resorbable collagen membrane was secured over the implan

18 ARP was performed with an allograft and a resorbable collagen membrane.

19 h as connective tissue, buccal fat pads, and resorbable collagen membranes have been reported in the

20 nerves, are used to seed a synthetic, often resorbable conduit, which is then used to bridge and rep

21 grafts in combination (M) or not (NM) with a resorbable cross-linked barrier membrane in the reconstr

22 a sensor to an implanted (but only partially resorbable) data-communication system, proving the princ

23 freeze-dried bone allograft covered by a non-resorbable dense polytetrafluoroethylene membrane.

24 in a single implantable, biocompatible, and resorbable device.

25 ost sophisticated clinical standards for non-resorbable devices by monitoring intracranial pressures

26 n injury; the measurement performance of our resorbable devices compares favourably with that of non-

27 Such externally controllable, resorbable devices not only obviate the need for seconda

28 Herein, we report a series of resorbable elastomer-like materials that are composition

29 e represents an important alternative to non-resorbable ePTFE barriers in combination with DFDBA for

30 zed laminar bone allograft membrane or a non-resorbable expanded polytetrafluoroethylene (ePTFE) memb

31 half of the implants were covered with a non-resorbable (expanded polytetrafluoroethylene [ePTFE]) me

32 le, polylactic acid (PLA) barrier or the non-resorbable, expanded polytetrafluoroethylene (ePTFE) bar

33 icates their major advantage as a radiopaque resorbable filter material, as the radiopacity allows mo

34 The scaffolds were shown to be highly resorbable following implantation in a porcine femoral a

35 olytetrafluoroethylene (ePTFE) membrane (non-resorbable) for GBR using a bovine bone xenograft/autogr

36 a fresh extraction socket filled with slowly resorbable graft biomaterial and with a delayed prosthet

37 f bone healing compared to PRP-free collagen resorbable graft.

38 eration (GTR) with resorbable (GTRr) and non-resorbable (GTRnr) membrane and GTRr with anorganic xeno

39 Guided tissue regeneration (GTR) with resorbable (GTRr) and non-resorbable (GTRnr) membrane an

40 This resorbable implant was specifically designed to function

41 Resorbable, implantable bioelectronic devices are emergi

42 o macroscales, supporting the fabrication of resorbable implants, drug-delivery systems, microneedle

43 a flexible 32-electrode neural probe with a resorbable insertion shuttle, and a repeater coil-based

44 en shown to be a good candidate material for resorbable IVC filters.

45 Regeneration involves the implantation of a resorbable matrix that is expected to remodel in vivo an

46 de defect was treated using a collagen-based resorbable membrane and a bovine bone graft (GM defect),

47 ided tissue regenerative surgery using a non-resorbable membrane and allograft.

48 atite mineral on its surface combined with a resorbable membrane composed of type I porcine collagen

49 The bone grafts were immobilized by a resorbable membrane glued to the recipient bed with cyan

50 The non-resorbable membrane was retrieved 6 weeks following plac

51 ent in horizontal defect depth compared with resorbable membranes (1.9 +/- 1.4 mm) as shown in one st

52 compared to guided tissue regeneration with resorbable membranes (GTR rm) + CAF (mean difference [MD

53 but no significant difference compared with resorbable membranes was shown.

54 The use of tenting screws and resorbable membranes with a combination of osseous allog

55 , porous hydroxyapatite-collagen grafts with resorbable membranes with or without 10-mg SIM were plac

56 nation with barrier membranes, evaluation of resorbable membranes, and use of bone substitutes or gro

57 issue engineering have introduced the use of resorbable membranes, xenografts, and osteoinductive pro

58 in bone regenerated with resorbable and non-resorbable membranes.

59 izontal furcation defect depth compared with resorbable membranes.

60 or to control treatments but as effective as resorbable membranes.

61 ene, and cell based) and biomaterials (e.g., resorbable, nonresorbable, and 3-dimensionally printed)

62 hetic nonresorbable (SNOR) (n=1458), natural resorbable (NR) (n=241), combined natural and synthetic

63 (n=103), and combined natural and synthetic resorbable (NSR) (n=1).

64 tion biomaterials were designed to be either resorbable or bioactive, the next generation of biomater

65 Barrier films that are both flexible and resorbable over predictable timelines would enable tunab

66 This class of device provides fully resorbable packaging and electronics that can be turned

67 r fixation was achieved with polylactic acid resorbable pins.

68 mentum, using an in situ-generated adherent, resorbable plasma-thrombin biologic scaffold, was evalua

69 selected patients randomly received collagen resorbable plug dressing material (control group).

70 with PRP compared to 38.3% +/- 9.3% collagen resorbable plug.

71 Herein, we report the use of bio-resorbable poly(ester urea) (PEU) films that controllabl

72 All 28 grafted sites were covered with a resorbable polylactide membrane.

73 receive treatment with an everolimus-eluting resorbable scaffold or angioplasty.

74 ry disease, the use of an everolimus-eluting resorbable scaffold was superior to angioplasty with res

75 Drug-eluting resorbable scaffolds (DRS) are conceptually attractive f

76 The most common approach is biodegradable or resorbable scaffolds configured to the shape of the new

77 Synthetic, resorbable scaffolds for bone regeneration have potentia

78 the current BVS and point the way to thinner resorbable scaffolds in the future.

79 The effect of the use of drug-eluting resorbable scaffolds on these outcomes remains unknown.

80 we prepare and characterize a new family of resorbable screws prepared from silk fibroin for craniof

81 When studied on resorbable substrates, osteoclastic resorption was suppr

82 ymer that is used in children every day as a resorbable suture material, and therefore, highly biocom

83 arlier use as biodegradable products such as resorbable sutures, orthopaedic implants, macroscale and

84 Recently, resorbable systems have gained interest because they avo