產品描述

塔望科技研發的全身體積描記系統（whole-body plethysmograph，WBP）可對清醒自由活動動物呼吸參數進行測量，如呼吸頻率，潮氣量，氣道高反應性測試（Airway hyperresponsiveness，AHR）等。測試過程中，動物可以處于清醒自由狀態，避免了創傷性氣管切開及麻醉的影響，使實驗過程更加簡便，用于呼吸系統模型動物對藥物等反應性研究，呼吸性藥物的藥理和毒理學研究，特別適合于大批量動物快速初篩試驗，適合長期跟蹤研究和重復性篩查。

產品特點

· 不需要做手術，操作簡單

· 可多通道同時監測

· 可在動物在自然狀態下呼吸的研究以及長期跟蹤實驗，適合進行藥物初篩

· 具有藥物氣溶膠霧化模塊· 具有自動標定功能

· 具有飲水口和食物口，可進行長期連續監測

· 可選配測量心電、血壓、體溫、心率等指標，可與植入式遙測設備聯合使用

· 具有分析軟件，數據可保存至excel或txt格式

可選配的功能模塊：

· 同步視頻監測：同步的視頻錄像文件

· 咳嗽檢測：通過軟件自動監測咳嗽事件

· 其它生理指標測量：可在麻醉或清醒狀態下測量心電、血壓、體溫、心率等指標，可與植入式遙測設備聯合使用

檢測參數

Ti：吸氣時間（s）

Te：呼氣時間（s）

PIF：最大吸氣流速（ml/s）

PEF：最大呼氣流速（ml/s）

Volbal：吸氣時間/呼氣時間

F：呼吸頻率（次/min）

Vt：潮氣量（ml）

Mv：分鐘通氣量（ml）

AV：累積體積（ml）

EF50：呼出50%氣量時對應的呼氣流速（ml/s）

EIP：吸氣末暫停時間

EEP：呼氣末暫停時間

TR：松弛時間

PenH：增強呼氣間歇（enhanced pause）

Rpef：相對時間

適用領域

· 各種呼吸疾病研究，如：哮喘、肺纖維化、肺損傷、ARDS、肺癌等

· 安全藥理：藥物對呼吸系統的影響

· 睡眠呼吸：監測動物低通氣、阻塞性呼吸暫停等

· 環境毒理：環境污染物對動物呼吸的影響

· 吸入式毒理：染毒物質對呼吸系統的毒性影響

· 高原醫學：高原環境對呼吸系統的影響

· 其它需要對呼吸參數評價的場合

相關文獻

[1] Zhou J W, Bai Y, Guo J Q, et al. Peroxiredoxin 4 as a switch regulating PTEN/AKT axis in alveolar macrophages activation[J]. Signal Transduction and Targeted Therapy (IF 52.7), 2025, 10(1): 352.

[2] Jiang C, Huang H, Yang X, et al. Targeting mitochondrial dynamics of morphin-responsive dopaminergic neurons ameliorates opiate withdrawal[J]. The Journal of Clinical Investigation (IF 19.5), 2024.

[3] Wang Z, Miao Z, Cao Z, et al. Mild Hyperthermia‐Assisted Coaxial Electrospun Nanofiber Patches for Epicutaneous Allergen‐Specific Immunotherapy[J]. Advanced Functional Materials (IF 19.0), 2025: e09955.

[4] Dong S, Fang H, Zhu J, et al. Inhalable siRNA Targeting IL-11 Nanoparticles Significantly Inhibit Bleomycin-Induced Pulmonary Fibrosis[J]. ACS nano (IF 15.8), 2025.

[5] Chen J, Wang J, Zheng W, et al. Brain–cervical lymph node crosstalk contributes to brain injury induced by subarachnoid hemorrhage in mice[J]. Nature Communications (IF 15.7), 2025, 16(1): 8551.

[6] Wang Y, Zhao Q, Zhang Q, et al. Targeted Delivery of CNS‐Specific Hesperidin as a Leptin Sensitizer for Treating Obesity‐Associated Sleep‐Disordered Breathing[J]. Advanced Science (14.1), 2025, 12(45): e06182.

[7] Wang Z, Lu X, Wu L, et al. Co-delivery of targeted hypoallergens and resiquimod powders using silk fibroin microneedles for effective allergen-specific immunotherapy[J]. Theranostics (IF 13.3), 2025, 15(16): 8096.

[8] Liu Y, Li G, Xiong A, et al. Fine particulate matter exacerbates asthma by activating STC2-mediated mitophagy through METTL3/YTHDF2-dependent m6A methylation[J]. Journal of Hazardous Materials (IF12.2), 2025: 138854.

[9] Li H, Liu S, Dai W, et al. Pressure-sensitive multivesicular liposomes as a smart drug-delivery system for high-altitude pulmonary edema[J]. Journal of Controlled Release (IF 11.5), 2024, 365: 301-316.

[10] Hou T, Zhu L, Zhang Y, et al. Lipid peroxidation triggered by the degradation of xCT contributes to gasdermin D-mediated pyroptosis in COPD[J]. Redox Biology (IF 10.1), 2024, 77: 103388.

[11] Luo L, Qin Z, Chen M, et al. γ-Aminobutyric acid–mediated parafacial zone: Integrating consciousness and respiratory control in sevoflurane anesthesia[J]. Anesthesiology (IF 9.1), 2025, 144(1): 116.

[12] Duan L L, Cai P, Li Z S, et al. Role of the supramammillary nucleus–medial septum glutamatergic pathway in mediating the effects of isoflurane anesthesia[J]. Anesthesiology (IF 9.1), 2025, 143(4): 944.

[13] Wei X, Cao X, Xu C, et al. Revolutionizing antibiotic therapy: polymyxin B and Fe2+-enriched liposomal carrier harness novel bacterial ferroptosis mechanism to combat resistant infections[J]. Journal of Pharmaceutical Analysis, 2025: 101293.

[14] Zhou W, Zhou Y, Zhang S, et al. Gut microbiota’s role in high-altitude cognitive impairment: The therapeutic potential of Clostridium sp. supplementation[J]. Science China Life Sciences, 2025, 68(4): 1132-1148.

[15] Liu J, Gao J, Xiong A, et al. Exploring Cistanche's therapeutic potential and molecular mechanisms in asthma treatment[J]. Phytomedicine, 2025, 136: 156265.

[16] Wang X, Zhao H, Lin W, et al. Panax notoginseng saponins ameliorate LPS-induced acute lung injury by promoting STAT6-mediated M2-like macrophage polarization[J]. Phytomedicine, 2025, 139: 156513.

[17] Jiang J, Ai S, Yuan C, et al. Dysfunction of cholinergic neuron in nucleus ambiguous aggravates sepsis-induced lung injury via a GluA1-dependment mechanism[J]. Brain, Behavior, and Immunity, 2025.

[18] Xu Z, Wu Y, Zhao X, et al. Integrating nontargeted metabolomics and RNA sequencing of dexamethasone-treated and untreated asthmatic mice reveals changes of amino acids and aminoacyl-tRNA in group 2 innate lymphoid cells[J]. International Journal of Biological Macromolecules, 2024, 283: 137630.

[19] Su J, Tu Y, Hu X, et al. Ambient PM2. 5 orchestrates M1 polarization of alveolar macrophages via activating glutaminase 1-mediated glutaminolysis in acute lung injury[J]. Environmental Pollution, 2025, 366: 125467.

[20] Shan C, Li W, Sun Y, et al. Benzo (a) pyrene exposure aggravates airway remodeling in asthma by activating AhR-GDF15 pathway in epithelial cells[J]. Environmental Pollution, 2025: 127557.

[21] Zhang M, Xu B, Li N, et al. All-Hydrocarbon Stapled Peptide Multifunctional Agonists at Opioid and Neuropeptide FF Receptors: Highly Potent, Long-Lasting Brain Permeant Analgesics with Diminished Side Effects[J]. Journal of Medicinal Chemistry, 2023.

[22] Long Y, Ang Y, Chen W, et al. Hydrogen alleviates impaired lung epithelial barrier in acute respiratory distress syndrome via inhibiting Drp1-mediated mitochondrial fission through the Trx1 pathway[J]. Free Radical Biology and Medicine, 2024, 218: 132-148.

[23] Wang Y, Liu X, Zhang Q, et al. Bioluminescence-optogenetics-mediated gene therapy in a sleep-disordered breathing mouse model[J]. Biomedicine & Pharmacotherapy, 2024, 178: 117159.

[24] Tabynov K, Tailakova E, Rakhmatullayeva G, et al. Comparison of rArt v 1-based sublingual and subcutaneous immunotherapy in a murine model of asthma[J]. npj Vaccines, 2025, 10(1): 66.

[25] Jiang Y, Zhang Y, Wang X, et al. Phosphatase PHLPP1 is an alveolar-macrophage-intrinsic transcriptional checkpoint controlling pulmonary fibrosis[J]. Cell Reports, 2025, 44(3).

[26] Liu S, Chu J, Yin X, et al. The adeno associated viral vectored Dp12S vaccine effective alleviation of asthma symptoms in mice[J]. npj Vaccines, 2025.

[27] Jin M, Liu J, Shao M, et al. Chitosan Nanoparticles for Pulmonary Delivery of Curcumin/Nintedanib to Treat Pulmonary Fibrosis[J]. International Journal of Nanomedicine, 2025: 12959-12973.

[28] Xiong A, He X, Liu S, et al. Oxidative stress-mediated activation of FTO exacerbates impairment of the epithelial barrier by up-regulating IKBKB via N6-methyladenosine-dependent mRNA stability in asthmatic mice exposed to PM2. 5[J]. Ecotoxicology and Environmental Safety, 2024, 272: 116067.

[29] Jia X, Liu S, Sun C, et al. METTL16 controls airway inflammations in smoking-induced COPD via regulating glutamine metabolism[J]. Ecotoxicology and Environmental Safety, 2025, 289: 117518.

[30] Lu X, Tan Z X, Yao Y X, et al. Inhaling arsenic aggravates airway hyperreactivity by upregulating PNEC-sourced 5-HT in OVA-induced allergic asthma[J]. Ecotoxicology and Environmental Safety, 2025, 290: 117764.

[31] Li Q, Ang Y, Zhou Q, et al. Coral calcium hydride promotes peripheral mitochondrial division and reduces AT-II cells damage in ARDS via activation of the Trx2/Myo19/Drp1 pathway[J]. Journal of Pharmaceutical Analysis, 2024: 101039.

[32] Zhang X, Hu T, Yu X, et al. Human umbilical cord mesenchymal stem cells improve lung function in chronic obstructive pulmonary disease rat model through regulating lung microbiota[J]. Stem Cells, 2024: sxae007.

[33] Akhtemova N, Sergazina A, Bolatbekov T, et al. The role of major allergens Art v 1 and Art v 3 in Artemisia pollen-induced asthma: a mouse model study[J]. Frontiers in Immunology, 2025, 16: 1590791.

[34] Tabynov K, Nedushenko I, Tailakova E, et al. Intranasal monoclonal antibodies to mugwort pollen reduce allergic inflammation in a mouse model of allergic rhinitis and asthma[J]. Frontiers in Immunology, 2025, 16: 1595659.

[35] Zhang Y, Jiang M, Xiong Y, et al. Integrated analysis of ATAC-seq and RNA-seq unveils the role of ferroptosis in PM2. 5-induced asthma exacerbation[J]. International Immunopharmacology, 2023, 125: 111209.

[36] Yao W, Huang S X, Zhang L, et al. Central amygdala somatostatin neurons modulate stress-induced sleep-onset insomnia[J]. Communications Biology, 2025, 8(1): 381.

[37] Lin Y, Wu Y, Ma F, et al. Exploration of the mechanism of Qi-Xian decoction in asthmatic mice using metabolomics combined with network pharmacology[J]. Frontiers in Molecular Biosciences, 2023, 10.

[38] Yang D, Li Y, Liu T, et al. IL‐1β promotes IL‐17A production of ILC3s to aggravate neutrophilic airway inflammation in mice[J]. Immunology, 2025, 176(1): 16-32.

[39] Zhang Y, Yang Y, Liang H, et al. Nobiletin, as a Novel PDE4B Inhibitor, Alleviates Asthma Symptoms by Activating the cAMP-PKA-CREB Signaling Pathway[J]. International Journal of Molecular Sciences, 2024, 25(19): 10406.

[40] Tsentsevitsky A N, Sibgatullina G V, Odoshivkina Y G, et al. Functional and Structural Changes in Diaphragm Neuromuscular Junctions in Early Aging[J]. International Journal of Molecular Sciences, 2024, 25(16): 8959.

[41] Ma J, Ni Z, Chen Q, et al. Exploring the kidney-tonifying effect of Qi-Xian decoction for asthma treatment by modulating the proliferation and migration of endogenous BMSCs[J]. Chinese Journal of Natural Medicines, 2025, 23(12): 100009.

[42] Liu K, Gu Y, Gu S, et al. Trim27 aggravates airway inflammation and oxidative stress in asthmatic mice via potentiating the NLRP3 inflammasome[J]. International Immunopharmacology, 2024, 134: 112199.

[43] Yuan Z, Wang Q, Tan Y, et al. Methylprednisolone alleviates lung injury in sepsis by regulating miR-151-5p/USP38 pathway[J]. International Immunopharmacology, 2024, 138: 112548.

[44] Wang Y, Peng M, Yang X, et al. Total alkaloids in Fritillaria cirrhosa D. Don alleviate OVA-induced allergic asthma by inhibiting M2 macrophage polarization[J]. Journal of Ethnopharmacology, 2025, 337: 118935.

[45] He J, Li J, Lin Q, et al. Anti-CD20 treatment attenuates Th2 cell responses: implications for the role of lung follicular mature B cells in the asthmatic mice[J]. Inflammation Research, 2024, 73(3): 433-446

[46] Liu Y, Tang A, Liu M, et al. Tuberostemonine may enhance the function of the SLC7A11/glutamate antiporter to restrain the ferroptosis to alleviate pulmonary fibrosis[J]. Journal of Ethnopharmacology, 2024, 318: 116983.

[47] Chen N, Xie Q M, Song S M, et al. Dexamethasone protects against asthma via regulating Hif-1α-glycolysis-lactate axis and protein lactylation[J]. International Immunopharmacology, 2024, 131: 111791.

[48] Li R, Zhang W, Huang B, et al. Dayuan Yin alleviates symptoms of HCoV-229E-induced pneumonia and modulates the Ras/Raf1/MEK/ERK pathway[J]. Natural Products and Bioprospecting, 2024, 14(1): 58.

[49] Wei M, Song M, Lin L, et al. Mechanism of Keke tablets in treating post-infectious cough following influenza A virus infection based on network pharmacology, molecular docking, molecular dynamics and in vivo experiments[J]. International Immunopharmacology, 2025, 162: 115123.

[50] Gong X T, Li Z S, Chen Z L, et al. Basal forebrain-ventral tegmental area glutamatergic pathway promotes emergence from isoflurane anesthesia in mice[J]. Journal of Neuroscience, 2025.

[51] Cheng S, Huang H, Zhang Z, et al. Pulmonary delivery of excipient-free tobramycin DPIs for the treatment of Pseudomonas aeruginosa lung infection with CF[J]. Frontiers in Pharmacology, 2025, 16: 1528905.

[52] Yan C X, Sun K, Zhu X, et al. Oligomeric proanthocyanidins mitigate acute lung injury by inhibiting NETs and inflammation via the gut-lung axis[J]. Journal of Functional Foods, 2024, 118: 106272.

[53] Liu Y, Wang X, Wei J, et al. Comprehensive profiling of amino acids and derivatives in biological samples: A robust UHPLC-MS/MS method for investigating acute lung injury[J]. Journal of Chromatography A, 2024, 1721: 464816.

[54] Zakyrjanova G F, Tsentsevitsky A N, Matigorova V A, et al. Cholesterol-lowering treatment suppresses neuromuscular transmission via presynaptic mechanism at the mouse diaphragm muscle[J]. Neurochemical Research, 2025, 50(5): 1-23.

[55] Zhang J, Huang M, Zhou J, et al. Bmi-1 overexpression mitigates vitamin D deficiency-induced pulmonary fibrosis via TIME pathway[J]. Cellular Signalling, 2025: 112180.

[56] Sun G, Hao W, Li Q, et al. Therapeutic and prophylactic effects of Qipian on COPD in mice: the role of lung and gut microbiota[J]. Microbiology Spectrum, 2025: e01969-24.

[57] Khaziev A N, Tsentsevitsky A N, Fedorov N S, et al. Exogenous nanomolar zinc ion (Zn2+) as a negative modulator of neuromuscular transmission via presynaptic mechanism in mouse diaphragm[J]. BioMetals, 2025: 1-24.

[58] Fu X, Wang L T, Xu Q, et al. Necroptosis Inhibition Preserves Diaphragm Function in Experimental Sepsis[J]. The American Journal of Pathology, 2025, 195(12): 2373-2386.

[59] Zheng R, Yang W, Yan J, et al. DNAH10 mutation cause primary ciliary dyskinesia with defects of IDAf complex assembly and lung fibrosis manifestation[J]. Orphanet Journal of Rare Diseases, 2025, 20(1): 469.

[60] Chen X Y, Wang L, Ma X, et al. Development of fentany-specific monoclonal antibody (mAb) to antagonize the pharmacological effects of fentany[J]. Toxicology and Applied Pharmacology, 2024, 486: 116918.

[61] Han C H, Zhang P X, Liu Y, et al. Inhibition of renin-angiotensin system attenuates type I alveolar epithelial cell necroptosis in rats after hyperbaric hyperoxic exposure[J]. Frontiers in Medicine, 2025, 12: 1521729.

[62] Yin, Lijun; Guan, Zhenbiao; Xu, Jiajun; Yu, Xuhua; Wen, Yukun; Wang, Shifeng; Liu, Wenwu. Assessment of hyperbaric hyperoxic lung injury in rats. Medical Gas Research 15(1):p 129-131, March 2025. | DOI: 10.4103/mgr.MEDGASRES-D-24-00030 

[63] Yin L, Wen Y, Liang Z, et al. Lung function and blood gas of rats after different protocols of hypobaric exposure[J]. Medical Gas Research, 2025, 15(1): 180-187.

[64] Aisanjiang M, Dai W, Wu L, et al. Ameliorating lung fibrosis and pulmonary function in diabetic mice: Therapeutic potential of mesenchymal stem cell[J]. Biochemical and Biophysical Research Communications, 2024, 737: 150495.

[65] Jia X, Sun J, Zhuo Q, et al. Effect of the NLRP3 inflammasome on increased hypoxic ventilation response after CIH exposure in mice[J]. Respiratory Physiology & Neurobiology, 2024, 321: 104204.

[66] Kuznetsova E A, Fedorov N S, Zakyrjanova G F, et al. 25-Hydroxycholesterol as a negative regulator of diaphragm muscle contractions via estrogen receptor and Ca2+-dependent pathway[J]. Histochemistry and Cell Biology, 2025, 163(1): 1-15.

[67] Wu Y, Dai T, Qin J, et al. Regulation of Dendritic Cell Function by RFX5 through Interaction with HDAC2 and Its Mechanism in Pediatric Asthma[J]. Biocell, 2025, 49(4).

[68] Xu X, Nie X, Zhang W, et al. A brainstem circuit controls cough-like airway defensive behaviors in mice[J]. bioRxiv, 2024: 2024.09. 08.611924.

[69] Li W, Wu L, Lu X, et al. Prenatal Benzo [A] Pyrene Exposure Exacerbates Ova-Induced Asthma in Offspring Mice[J]. Available at SSRN 5265037.

*我公司可以根據客戶的特殊應用、特殊需求提供功能定制服務，也可以提供相關的實驗服務，詳情請聯系我們。

*此介紹及參數為產品基礎信息，可能滯后于產品更新，具體參數請與我司聯系