ライフサイエンスコーパス: laryngeal nerve

1 al nerve and external branch of the superior laryngeal nerve.

2 ed short-latency coordinated activity in the laryngeal nerve.

3 s laevis 1 and 5 months after section of the laryngeal nerve.

4 and project to the airways via the superior laryngeal nerves.

5 rostral trachea and larynx via the recurrent laryngeal nerves.

6 y by electrical stimulation of both superior laryngeal nerves.

7 -triggered averages of phrenic and recurrent laryngeal nerve activities.

8 y phrenic nerve activity (PNA) and recurrent laryngeal nerve activity (RLNA), as well as dynamic chan

9 ns, we developed a preparation in which both laryngeal nerve activity and electromyograms can be reco

10 ike-triggered averages of efferent recurrent laryngeal nerve activity.

11 geons about the functioning of the recurrent laryngeal nerve and external branch of the superior lary

12 we recorded extracellular activity from the laryngeal nerve and muscles and intracellular activity i

13 ion of the central cut ends of both superior laryngeal nerves and lung stretch afferent activity was

14 rve integrity, particularly in the recurrent laryngeal nerve, and provide a basis for the evaluation

15 well known that variations of the recurrent laryngeal nerve are prone to iatrogenic injuries.

16 roid tadpoles did not exhibit the decline in laryngeal nerve axon number characteristic of age-matche

17 acteristic of age-matched controls, nor were laryngeal nerve axon numbers sexually dimorphic.

18 surgery can result in hypoparathyroidism or laryngeal nerve damage.

19 vely understand the anatomy of the recurrent laryngeal nerve during thyroid operation.

20 Electrically stimulating the laryngeal nerve elicited primarily IPSPs in premotor neu

21 ion of the posterior branch of the recurrent laryngeal nerve following the progressive opening of the

22 ice disturbances for patients with preserved laryngeal nerve function has not been systematically stu

23 There were no recurrent laryngeal nerve injures in either group.

24 There were no iatrogenic recurrent laryngeal nerve injuries; one patient required recurrent

25 cemia patients had higher rates of recurrent laryngeal nerve injury (13.4% vs 6.6%), unplanned reoper

26 Avoidance of recurrent or superior laryngeal nerve injury and maintenance of normal larynge

27 proach was associated with reduced recurrent laryngeal nerve injury and mortality of 0.9% and is now

28 Factors other than laryngeal nerve injury appear to alter post-thyroidectom

29 believed that Galli-Curci suffered superior laryngeal nerve injury during her thyroidectomy by Arnol

30 ewis or a McKeown RAMIE procedure, recurrent laryngeal nerve injury occurred in 3% and 11% of patient

31 n either group developed permanent recurrent laryngeal nerve injury or hyperparathyroidism.

32 Rates of temporary and permanent recurrent laryngeal nerve injury were 5% and 0% respectively.

33 Permanent hypoparathyroidism and laryngeal nerve injury were not observed.

34 e absence of the typical effects of superior laryngeal nerve injury, and the presence of other explan

35 One patient (<1%) exhibited a recurrent laryngeal nerve injury.

36 es and reducing risks of bilateral recurrent laryngeal nerve injury.

37 ent laryngeal nerve injury; one had superior laryngeal nerve injury.

38 morbidity rate was limited to one recurrent laryngeal nerve injury.

39 No patient developed recurrent laryngeal nerve injury; one had superior laryngeal nerve

40 Neuromonitoring of the recurrent laryngeal nerve is increasingly utilized in thyroid and

41 Injury to the recurrent laryngeal nerve is one of the most severe complications

42 t run in the internal branch of the superior laryngeal nerve (ISLN) activates neurons of the periaque

43 vated by the internal branch of the superior laryngeal nerve (ISLN) are activated by swallowing, and

44 ry complications (46.7% vs 31.9%), recurrent laryngeal nerve palsy (9.5% vs 0.5%), reoperations (18.6

45 .4% to -2.2%]), lower incidence of recurrent laryngeal nerve palsy (risk difference, -7.3% [95% CI, -

46 nent hypoparathyroidism, transient recurrent laryngeal nerve palsy (RLNP), reoperations for bleeding,

47 ications of surgery were frequent (recurrent laryngeal nerve palsy 25.3%; hypoparathyroidism 6%).

48 repeated surgery and postoperative recurrent laryngeal nerve palsy and hypoparathyroidism.

49 ectomies and 0.99 to 2.13 cases of recurrent laryngeal nerve palsy per 100 operations.

50 c leak, anastomotic stricture, and recurrent laryngeal nerve palsy rate was significantly higher in t

51 nia, 2%, intrathoracic hemorrhage, recurrent laryngeal nerve paralysis, chylothorax, and tracheal lac

52 ia (2%), intrathoracic hemorrhage, recurrent laryngeal nerve paralysis, chylothorax, and tracheal lac

53 eriority over visualization of the recurrent laryngeal nerve (RLN) alone.

54 The recurrent laryngeal nerve (RLN) is responsible for normal vocal-fo

55 acid challenges were abolished by recurrent laryngeal nerve (RLN) transection and mimicked by electr

56 ative VCP, deliberate sacrifice of recurrent laryngeal nerve (RLN), inadvertent RLN resection, and su

57 h surgeons must avoid damaging the recurrent laryngeal nerve (RLN), which is responsible for human sp

58 elocity testing of the innervating recurrent laryngeal nerves (RLn) was conducted in horses with norm

59 t-term outcomes (anastomotic leak, recurrent laryngeal nerve [RLN] palsy, pulmonary and total complic

60 cal stimulation of afferents in the superior laryngeal nerve (SLN) or by deflection of mechanorecepto

61 oning of the internal branch of the superior laryngeal nerve (SLN).

62 ry phrenic motoneuronal response to superior laryngeal nerve stimulation and abolished or reduced abd

63 Unilateral electrical superior laryngeal nerve stimulation was used to elicit early (R1

64 s during respiration, vomiting, and superior laryngeal nerve stimulation.

65 hat accompany midbrain reticular or superior laryngeal nerve stimulations.

66 ing the vagus nerves caudal to the recurrent laryngeal nerves, thus leaving the preganglionic parasym

67 In cases where recurrent laryngeal nerve transection is not present, a local infl

68 ut they were virtually abolished by superior laryngeal nerve transection.

69 The incidence of injury to the recurrent laryngeal nerve was 1.3%.

70 The left recurrent laryngeal nerve was cryo-damaged in all animals and an L

71 nerve activity, transection of the superior laryngeal nerves was without effect on baseline choliner

72 hea and larynx whereas severing the superior laryngeal nerves was without effect on coughing.

73 atory motor pattern of phrenic and recurrent laryngeal nerves were comparable.

74 tive cough) in phrenic, lumbar and recurrent laryngeal nerves were elicited by mechanical stimulation

75 pharyngeal branch of the vagus, or superior laryngeal nerves) were recorded.

76 vocalizations" in the in vitro CPG from the laryngeal nerve while simultaneously recording premotor

77 branching pattern, and relation of recurrent laryngeal nerve with inferior thyroid artery and tracheo

78 rect apposition of the trachea and recurrent laryngeal nerves with the esophagus puts children at ris

79 ssess the anatomical variations of recurrent laryngeal nerves, with inferior approach using inferior