Intensive Care Ventilator ZislineMV200/MV300
Professor Boris Zislin, Doctor of Medicine, Honored doctor of RussianFederation.
One of the founders of Ural anesthesiology school and Triton Electronic Systems.
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TREATON
WHO WE ARE
Triton Electronic Systems Ltd. is a world-leading manufacturer of medical devices for Intensive Care and Anesthesiology.
Decades ago, a large scientific and technical cluster was formed in the Urals. This region of Russia has accumulated scientific knowledge and R&D experts from different sectors – from medical industry to aerospace. As a result, the Ural Scientific School was founded. Triton Electronic Systems was founded in 1989 by biomedical engineers and physicians from the Ural Scientific School.
Our greatest achievements are closely connected with the name of Prof. Boris Zislin, MD, PhD, DSci, who was the Chief Anesthesiologist of the Ural region for 37 years. Due to his novel ideas, we implement innovative medical technologies and produce a range of medical devices for anesthesiology and intensive care.
In biomedical signal processing,gas monitoring and respiratory support since 1989
Anesthesiology
• Multigas monitors• Depth of anesthesia
and sedation monitors
Intensive Care
• Ventilators forintensive care
ОЕМ‐solutions
• Capnography• Gas monitoring• Sedation control
OUR PRODUCTS
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Human's life is the highest value, themost important public property.
By developing and manufacturingadvanced medical equipment, we help
doctors save lives.
We aspire to ease the work of doctors, to make it more productive and
successful. We equip medical facilities with necessary medical devices with
high consumer characteristics and provide accessible and high quality
service support.
We are fully responsible for thequality, because a human life
depends on our product.
Triton Electronic Systems Ltd. is a member of The Patient Safety Movement Foundation, which founded to confront large problems with actionable ideas and innovations that can transform the process of care and dramatically improve patient safety. We have pledged to make the physiological parameters displayed on our medical devices, subject to all applicable privacy laws, available to anyone or any entity that wants to use them to improve patient care and help reverse the tide of preventable patient deaths.
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OUR MISSION
CERTIFICATES
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CanadaCOVID-19 Medical Device
Authorization for Importation or SaleAuthorization Reference Number: 326828
Issue Date: 2021-05-19
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EXPORT GEOGRAPHY
Over 40 countries around the world
24/7 Customer Support
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Hotline for physicians is available at our website www.treat-on.com
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RESPIRATORY CARE IS AN ART BASED ON PHYSIOLOGY
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What doctor expects from ICU ventilator?
1. One ventilator for different types of patients.2. Monitoring of respiratory mechanics, CO2.3. Wide range of ventilation modes, including NIV.4. Operation in case of gas / mains supply problems.5. Operation from different O2 sources.6. Simple and convenient user interface.7. Advanced specialized functions for different applications.8. Low cost of operation.
What could TREATON offer?
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Zisline. ALL-IN-ONE
Folded display
12.1/15” touch screen(MV200/ MV300)
Built-in turbine
Backup battery (4-6 h)
Universal accessories
Reliable mobile trolleywheels w/brackets
Any O2 sources:pipeline, cylinder, O2
concentrator
Autoclavable reusable expiratory valve &
integrated flow sensor
Patient types: adult, pediatric, neonatal (from 10 ml)
Zisline MV200/ MV300 Options and controls
Alarm indicator
Fast access buttons
Handles
Encoder
CO2
Assessment of metabolic (energy) needs
Auxiliary pressure
SpO2
Ethernet-connection
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VENTILATION
MODES
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Interface
Patientdata
Monitoredparameters
Controls
Alarms
Monitored parameters
Graphs & Loops
Special functions
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Features and OptionsAdaptive ventilation (iSV) Mode of intellectual adaptive ventilation - intended to support of with
any level of spontaneous breathing. iSV provides breaths with optimal values of VТ and RB, depending of patient’s parameters and breathing activity.
Mainstream CO2 Analysis of the gas in the breathing circuit - monitoring of EtCO2 , FiCO2 , respiratory rate (RR), capnogram.
Module for monitoring of cardiac output by the Fick method
Calculation of the cardiac output parameter (CO) based on the data of alveolar ventilation monitoring module.
Gas analysis with metabolism evaluation
The method of indirect calorimetry without the use of disposables. Continuous measurement: oxygen consumption (VO2 ), carbon dioxide elimination (VСO2 ), respiratory quotient (RQ), resting energy expenditure (REE).
Auxiliary pressure module Measurement of esophageal pressure/trachea via the catheter. Displaying on the screen curves of auxiliary pressure Paux.
Pulse oximetry Allows to monitor an oxygen saturation of hemoglobin in arterial blood SpО2 , peripheral pulse rate PR, photoplethysmogram.
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MAINSTREAM CO2
Proprietary original
capnometrytechnology
QuRETM
does not require calibration by
reference gases
ensures stable
operationno influence of anesthetics on measurement
results
suitable for HF ventilation up to 200 bpm
response time < 30 ms
Airway adapters produced by Triton ElectronicSystems Ltd.
Main benefits:• dead space < 5 ml (adult), < 1 ml (neonatal);
• reusable adapters can be autoclaved up to 100 times;
• number of chemical sterilizationcycles is not limited;
• 3 times cheaper than analogues.
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MAINSTREAM CO2
Optionally the device may be equipped with thefunction of volume capnometry, which operates onlytogether with mainstream capnometer.
Volume capnometer enables to define the followingparameters:• elimination of CO2 per minute (VCO2), which
characterizes the metabolism rate (e.g., high value indicates sepsis etc.), and reflects the effectiveness of applied respiratory therapy in dynamics;
• functional dead space (Vd);• minute alveolar ventilation (MValv)
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VOLUMETRIC CAPNOMETRY
The function for cardiac output calculation by Fick operatestogether with the volume capnometry.For the calculation of cardiac output CO it is necessary to know:• the elimination of carbon dioxide VCO2 ,• alveolar concentration of CO2.
Monitoring of cardiac output is recommended for allpatients subjected to ventilation, as the artificial ventilationitself leads to induced inhibition of cardiac output.
The accuracy of the cardiac output calculation by Fick is strongly influenced by the following conditions:• the presence of pulmonary shunts,• the non-ventilated areas of the lung• other abnormalities of ventilation-perfusion ratios.
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MONITORING OF CARDIAC OUTPUT BY THE FICK METHOD
The calculation of cardiac output (CO) is performed by Fick equation:
For displaying of the digital values of cardiac output and minute CO2 elimination select CO/VCO2 for the one of the modules of the measurement parameters.
Also it is necessary to enter the value of the venous (PvCO2) and/or arterial (PaCO2) CO2 concentration obtained using one of the laboratory techniques.
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MONITORING OF CARDIAC OUTPUT BY THE FICK METHOD
METABOLIC EVALUATION FUNCTION
Ventilator can be equipped with the option of indirect calorimetry measurement. It can measure metabolic parameters: • oxygen consumption VO2, ml/min• elimination of CO2 per minute VCO2, ml/min
According to the measured values the module calculates:• respiratory quotient RQ, relative units• resting energy expenditure REE, kcal/day
RQ = VCO2 / VO2
REE (kcal/day) = (3.941 VO2 + 1.106 VCO2) N
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AUXILIARY PRESSURE OPTION
Tracheal catheter is intended for the monitoring of the actual pressure in the trachea and the actual PEEP regardless of the ventilation parameters.
Esophageal balloon catheter in intended mainly for the monitoring of esophageal pressure for the calculation of the transpulmonary pressure on the inspiration and expiration.
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Auxiliary pressure option measures pressure in the trachea and esophagus.
PULSE OXIMETRY FUNCTION
Optionally the device can be equipped with built-in pulseoximetry module which allows monitor to obtain: oxygen saturation of arterial blood hemoglobin SpО2; peripheral pulse rate PR; Photoplethysmogramm.
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Different types of pulse oximetry sensors can be used
Parameter Description
AutoPEEP Residual pressure levelin lungs
Residual pressure in lungs that occurs due to the incompleteness of expiration. It is not measured in the CPAP mode.
SI Stress index Index characterizes the correctness of PEEP and VТ selection. It is determined in the CMV/VCV and SIMV/VC modes for hardware breaths at the rectangular shape of the flow waveform
RSBI Rapid shallow breathingindex
The dimensionless quantity characterizing the depth of patient’s breathing. Measured in CPAP, BiSTEP, APRV modes
P0.1 Respiratory effort index
Index characterizes the strength of the patient's breathing attempts. It is measured in cmH2O
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EXTENDED RESPIRATORY MONITORING
Parameter Description
Tinsp Inspiratory time, including spontaneous breath
Time of the last inspiration made by ventilator or patient
Tinsp/Ttot Factor of breathing cyclefilling
The ratio of inspiratory time to total duration of the respiratory cycle
MVe_sp / MVe Factor of spontaneousbreathing
The ratio of spontaneous breathing minute volume to the total tidal volume
Rexp Resistance to the exhalation Total respiratory resistance during expiratory phase
E Elasticity of respiratoryways (elastance)
Reverse value of static compliance. Measured in mmHg in CMV, SIMV, PCV‐VG modes
Rcirc Resistance of the breathing circuit The resistance of the breathing circuit, measured at breathing circuit calibration
Ccirc Compliance of the breathing circuit The compliance of the breathing circuit, measured at breathing circuit calibration
Cdyn Dynamic compliance The indicator of compiance of the lungs, chest and respiratory tract. Dynamic characteristic, calculated during the respiratory cycle
EXTENDED RESPIRATORY MONITORING
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12/5 Sibirsky Trakt, Ekaterinburg620100 Russian Federation
Tel: +7 (343) 304-60-57E-mail: [email protected]
www.treat-on.com
Importer, Distributor, Regulatory Correspondent in Canada:Neuronix Inc.
219 Ridgemont Dr, Ashton, ON K0A1B0 CanadaTel +1-613-253-3243 Toll-free 1-833-449-7979 Fax +1-613-253-5521
Email [email protected] Web www.neuronix.ca
Canada