Characteristic Changes of Sway of Center of Gravity with Advancing Afe

Takada, Hiroki, Kitaoka, Yoshiyuki, Iwase, Satoshi, Shimizu, Yuuki, Watanabe, Tomoyuki, Nakayama, Meiho, Miyao, Masaru, Mihashi, Koshin

12 1900

国立情報学研究所で電子化したコンテンツを使用している。

Aging

Righting reflex

Statokinesigram

Modulation of Central Dopamine Receptor Reactivity in the Rat, by Nitric Oxide Donors and Inhibitor: Behavioral Studies

Kasperska, Alicja, Brus, Ryszard, Szkilnik, Ryszard, Oswiecimska, Joanna, Kostrzewa, Richard M., Shani, Jashovam

01 December 1999

Nitric acid has been implicated in a variety of physiological functions of the mammalian brain, and in a large number of its pathologies. Recently we have demonstrated that a nitric oxide donor (L-arginine) and a nitric-oxide-synthase-inhibitor (nitro-L-arginine-methyl-ester) modified the response of central al dopamine D 1 and D 3 receptors to some of their agonists. In the present study we demonstrate the modulatory effect of L-arginine, nitro-L-arginine-methyl-ester and molsidomine (another nitric oxide donor) on the reactivity of the central dopamine receptors to specific agonists and antagonists. The agonists tested were SKF-38393, 7-OH-DPAT and quinpirole, and the antagonists - SCH-23390 and haloperidol. They were evaluated in the rat by the following behavioral methods: locomotor activity, locomotor coordination, rearings and cataleptogenic activity (D 2 modulation); grooming time (D 1 activation); yawning (D 3 activation) and ethanol- and phenobarbital-sleeping-time parameters after SKF-38393 or quinpirole pretreatment. Our results suggest that nitro-L-arginine-methyl-ester is effective in modulating the reactivity of the central dopamine receptors D 2, D 1 and D 3, to their agonists and antagonists, and that it is much more effective than L-arginine in regulating the righting reflex after ethanol and phenobarbital, in both female and male mature rats.

7-OH-DPAT

behavior

catalepsy

dopaminergic receptors

grooming

haloperidol

locomotor activity

locomotor coordination

nitric oxide

quinpirole

rearing

righting reflex

SCH-23390

SKF-38393

yawning

Biomedical Sciences

Optimisation de l’anesthésie du lapin (Oryctolagus cuniculus) par l’application des principes du Enhanced Recovery After Surgery (ERAS)

Rousseau-Blass, Frédérik

12 1900

L’adaptation des principes ERAS à l’anesthésie du lapin pourrait améliorer leur taux de mortalité périopératoire élevé. Le développement d’un protocole IM réversible pourrait raccourcir le réveil et diminuer les complications. Les objectifs de ce mémoire sont 1) d’investiguer la relation entre l’administration d’oxygène et la ventilation et 2) de définir les paramètres PK-PD du midazolam IV midazolam et son antagoniste flumazénil chez le lapin. Dans une étude prospective, randomisée, à l’aveugle, 25 lapins de Nouvelle-Zélande (4 mâles, 21 femelles ; 3,1–5,9 kg ; 1 an) ont été anesthésiés avec l’alfaxalone (4 mg/kg), dexmédétomidine (0,1 mg/kg) et midazolam (0,2 mg/kg) IM et randomisés à attendre 5 (n = 8) ou 10 (n = 17) minutes entre l’injection anesthésique et l’administration d’oxygène (100%) ou air médical (masque,1 L/minute). Avant (PREoxy/air5/10) et 2 minutes après l’oxygène ou l’air médical (POSToxy/air5/10), la fréquence respiratoire (fR), pH, PaCO2, PaO2 ont été investigués. L’hypoxémie (PaO2 < 88 mmHg) était présente à tous les temps PRE : PREoxy5 [71 (61–81) mmHg] ; PREoxy10 [58 (36–80) mmHg] et PREair10 [48 (32–64) mmHg]. L’hypoxémie a persisté avec l’air médical : POSTair10 [49 (33–66) mmHg]. L’administration d’oxygène a corrigé l’hypoxémie, mais était associée avec une diminution de fR (> 70% ; p = 0,016, deux groupes) et de l’hypercapnie (p = 0,016, deux groupes). fR restait inchangé avec l’air médical (p = 0,5). PaCO2 était plus élevé avec l’oxygène que l’air (p < 0,001). L’administration d’oxygène précoce a résolu l’hypoxémie reliée à l’anesthésie, mais a empiré l’hypoventilation démontrant que la stimulation respiratoire hypoxique est un facteur important contribuant à la ventilation lorsque ce protocole anesthésique est utilisé. Dans une étude prospective, randomisée, à l’aveugle et croisé, 15 lapins de Nouvelle-Zélande (7 mâles, 8 femelles; 2,73 – 4,65 kg ; 1 an) ont reçu midazolam IV (1,2 mg/kg) à T0 suivi de flumazénil IV (FLU ; 0,05 mg/kg) ou saline (SAL ; même volume) pour renverser la perte du réflexe de redressement (LORR). Le traitement (FLU/SAL) était injecté 30 secondes après LORR. L’échantillonnage sanguin artériel était analysé avec la technique de chromatographie liquide/spectrométrie de masse. Le temps pour le retour du réflexe de redressement (ReRR) était analysé. Demi-vie, clairance plasmatique and volume de distribution du FLU étaient 26,3 min [95%CI : 23,3–29,3], 18,74 mL/min/kg [16,47–21,00] et 0,63 L/kg [0,55–0,71], respectivement. ReRR était 25 fois plus rapide pour FLU (23 [8–44] secondes) versus SAL (576 [130–1141] secondes ; p<0.001, 95%CI [425–914 secondes]). Le retour de la sédation (LORR) était présent dans les deux groupes (4/13 FLU ; 7/13 SAL) à 1540 [858–2328] secondes. Le flumazénil a rapidement antagonisé la sédation du midazolam. Cependant, le potentiel de resédation après l’utilisation du flumazénil nécessite une surveillance accrue durant la période de réveil. / Adapting ERAS guideline principles to rabbit anesthesia could improve their risk of perioperative mortality which remains elevated. The development of a reversible IM protocol could hasten recovery and decrease complications. The objectives of this thesis were 1) to investigate the relationship between oxygen administration and ventilation, 2) to define PK-PD parameters of IV midazolam and its antagonist flumazenil in rabbits. In a prospective, randomized, blinded study, 25 New Zealand White rabbits (4 males, 21 females; 3.1–5.9 kg; 1 year old) were anesthetized with IM alfaxalone (4 mg/kg), dexmedetomidine (0.1 mg/kg) and midazolam (0.2 mg/kg) and randomized to a 5 (n = 8) or 10 (n = 17) minutes waiting period between drug injection and oxygen (100%) or medical air administration (facemask, 1 L/minute). Immediately before (PREoxy/air5/10) and 2 minutes after oxygen or medical air (POSToxy/air5/10), respiratory rate (fR), pH, PaCO2, PaO2 were investigated. Hypoxemia (PaO2 < 88 mmHg) was observed at all PRE times. PREoxy5 [71 (61–81) mmHg]; PREoxy10 [58 (36–80) mmHg] and PREair10 [48 (32–64) mmHg]. Hypoxemia persisted when breathing air: POSTair10 [49 (33–66) mmHg]. Oxygen administration corrected hypoxemia but was associated with decreased fR (> 70%; p = 0.016, both groups) and hypercapnia (p = 0.016, both groups). fR was unchanged breathing air (p = 0.5). PaCO2 was higher when breathing oxygen than air (p < 0.001). Early oxygen administration resolved anesthesia-induced hypoxemia, but worsened hypoventilation indicating that hypoxic respiratory drive is an important contributor to ventilation using the studied drug combination. In a prospective, randomized, blinded, crossover study, 15 New Zealand White rabbits (7 males, 8 females; 2.73 – 4.65 kg, 1 year old) received IV midazolam (1.2 mg/kg) followed by IV flumazenil (FLU; 0.05 mg/kg) or saline control (SAL; equal volume) to reverse loss of righting reflex (LORR). Midazolam was injected (T0). Treatment (FLU/SAL) injected 30 seconds after LORR. Arterial blood samples were collected and analyzed using liquid chromatography/mass spectrometry. Time to return of righting reflex (ReRR) compared between groups. FLU terminal half-life, plasma clearance and volume of distribution were 26.3 min [95%CI: 23.3–29.3], 18.74 mL/min/kg [16.47–21.00] and 0.63 L/kg [0.55–0.71], respectively. ReRR was 25 times faster in FLU (23 [8–44] seconds) versus SAL (576 [130–1141] seconds; p<0.001, 95%CI [425–914 seconds]). Return of sedation (LORR) occurred in both groups (4/13 in FLU; 7/13 in SAL) at 1540 [858–2328] seconds. Flumazenil quickly and reliably reversed sedation from midazolam injection. However, the potential resedation after flumazenil administration warrants careful monitoring in the recovery period.

Lapin

Anesthésie

Flumazénil

Réflexe de redressement

Pré-oxygénation

Hypoxémie

Gaz sanguin

Rabbit

Anesthesia

Early Recovery After Surgery

Eras

Flumazenil

Righting reflex

Pre-oxygenation

Hypoxemia

Blood gas