大小鼠自主活動跑輪

大鼠、小鼠自動活動跑輪，提供了一種簡單方便的方法來測量大鼠、小鼠在長時間活動中對化學或環境刺激的反應。

可連接到52600數據接口和加裝ANYmaze行為學分析軟件，實現對晝夜節律或運動功能等方面的研究。

型號：1800（大鼠型）、1850（小鼠型）

產品特點

· 適用于大鼠和小鼠 
· 易于監控：兼容多種何數據采集系統 
· 透明的聚碳酸酯籠子，具有的可見性 
· 全不銹鋼車輪結構，便于維護

· 可獨立工作，也可連接電腦

· 可選配打印機，具有內部存儲和電腦軟件

· 易于監測，易于維護，多功能接口可同時連接12只籠子

1850型小鼠自動活動跑輪 

· 11850型小鼠跑輪采用經典的25cm直徑，由不銹鋼制成，配有低摩擦特氟隆襯套，運作非常平穩；

· 小鼠在2mm直徑的桿上自由跑到，桿子間隔7mm； 

· 跑輪裝在一個透明的聚碳酸酯籠子里，不銹鋼金屬蓋和含U型顆粒料斗的專用蓋鎖； 
· 小鼠活動籠尺寸：37(h)x26(w)x35(d)cm；

1800型大鼠自主活動跑輪
· 大鼠跑輪的直徑為35cm，桿子直徑為2mm，桿子的間距為8.8 mm； 
· 大鼠籠尺寸：48(h)x32(w)x47(d)cm；

轉數計數器 
· 大鼠和小鼠活動籠配有磁性開關和LCD計數器，可統計轉輪累計轉數；

· 根據需要，還可以選擇不帶計數器的1800-S大鼠自動活動跑輪和1850-S型小鼠自主活動跑輪

· 使用數據線與軟件在電腦端進行數據收集；

數據采集 
· 配備多功能接口52600，能夠同時連接12活動跑輪； 
· 可選配專業的分析軟件ANYmaze進行管理，進行分析和統計；

選擇52600多功能數據采集接口時，不需要計數器，這時需要選擇的型號是：1800-S型大鼠自動活動跑輪和1850-S型小鼠自主活動跑輪。

大鼠活動示意圖：

參考文獻：

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7.Miletta, Maria Consolata et al. “AgRP neurons control compulsive exercise and survival in an activity-based anorexia model." Nature metabolism vol. 2,11 (2020): 1204-1211. doi:10.1038/s42255-020-00300-8

8.Brigger, Daniel et al. “Eosinophils regulate adipose tissue inflammation and sustain physical and immunological fitness in old age." Nature metabolism vol. 2,8 (2020): 688-702. doi:10.1038/s42255-020-0228-3

9.van Veen, J Edward et al. “Hypothalamic estrogen receptor alpha establishes a sexually dimorphic regulatory node of energy expenditure." Nature metabolism vol. 2,4 (2020): 351-363. doi:10.1038/s42255-020-0189-6

10.Brocker, David T et al. “Optimized temporal pattern of brain stimulation designed by computational evolution." Science translational medicine vol. 9,371 (2017): eaah3532. doi:10.1126/scitranslmed.aah3532

11.Janota, Cátia Silva et al. “Shielding of actin by the endoplasmic reticulum impacts nuclear positioning." Nature communications vol. 13,1 2763. 19 May. 2022, doi:10.1038/s41467-022-30388-3

12.Bobba, Christopher M et al. “Nanoparticle delivery of microRNA-146a regulates mechanotransduction in lung macrophages and mitigates injury during mechanical ventilation." Nature communications vol. 12,1 289. 12 Jan. 2021, doi:10.1038/s41467-020-20449-w

13.Mridha, Zakir et al. “Graded recruitment of pupil-linked neuromodulation by parametric stimulation of the vagus nerve." Nature communications vol. 12,1 1539. 9 Mar. 2021, doi:10.1038/s41467-021-21730-2

14.Navas-Olive, Andrea et al. “Multimodal determinants of phase-locked dynamics across deep-superficial hippocampal sublayers during theta oscillations." Nature communications vol. 11,1 2217. 5 May. 2020, doi:10.1038/s41467-020-15840-6

15.Nohara, Kazunari et al. “Nobiletin fortifies mitochondrial respiration in skeletal muscle to promote healthy aging against metabolic challenge." Nature communications vol. 10,1 3923. 28 Aug. 2019, doi:10.1038/s41467-019-11926-y

     

    

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