FR3135902A3 - Medical ventilator displaying an estimate of the amount of oxygen needed - Google Patents

Abstract

Title of the invention Medical ventilator displaying an estimate of the amount of oxygen required The invention relates to a medical ventilator comprising: a breathing gas source (3) for providing a gas flow, a gas circuit (4) for delivering the flow gas from the breathing gas source (3), an oxygen inlet (16) for introducing gaseous oxygen into the gas circuit (4), at least one flow sensor (5, 6) for measuring at minus a gas flow in the gas circuit (4), display means (2), control means (12), and data entry means (11) to allow a user to provide a duration ventilation. The control means (12) are configured to calculate an average flow rate and deduce therefrom an estimated volume of oxygen to carry out ventilation of the patient for the desired ventilation duration. This estimated oxygen volume is displayed. Abstract figure: Fig. 1

Description

Medical ventilator displaying an estimate of the amount of oxygen needed

A medical ventilator displays an estimate of the amount of oxygen needed to fully ventilate a given patient to help caregivers determine what volume of oxygen or how many oxygen cylinders will be needed for ensuring the ventilation in question, in particular during the transport of a ventilated patient from one site to another, and a patient ventilation assembly comprising such a medical ventilator associated with a pressurized oxygen cylinder.

Some people, i.e. patients, need to be put on assisted ventilation to help them breathe or compensate for deficient or altered functioning of their lungs.

To do this, they are administered a respiratory gas rich in oxygen, typically pure oxygen (i.e. 100% vol.) or oxygen-rich air, that is to say air to which we adds a variable quantity of oxygen chosen according to the condition of the patient in question, in particular their blood oxygen saturation.

The administration of respiratory gas is conventionally done by means of a respiratory assistance device or ventilator, commonly called a medical ventilator supplied with oxygen coming from an oxygen source, such as a gas cylinder or a wall outlet supplied by oxygen from a hospital network.

When the medical ventilator is used outside the hospital, typically in an emergency unit, such as an ambulance, SAMU, helicopter or similar type emergency vehicle, it is essential to transport it to the intervention site where it is located the patient to attend and plan the amount of oxygen that will be needed for the procedure, in particular oxygen bottles

Know precisely the quantity of oxygen necessary and/or the number of oxygen cylinders to transport to achieve sufficient ventilation of the patient, particularly during transport from the site of an accident to a hospital or during transfer from a hospital to another, is therefore critical information for healthcare personnel, typically for an emergency physician.

Indeed, if it is important to provide enough oxygen to ensure sufficient ventilation of the patient, the nursing staff must, conversely, take into account the space and weight constraints represented by the oxygen bottles at bring and the medical ventilator itself, particularly in emergency environments which often offer restricted or limited available space, such as for example the cabin of a helicopter or the trunk of an ambulance.

The nursing staff must therefore be able to have a fairly precise idea, including before the intervention, of the number of oxygen bottles to transport to avoid carrying too many or, conversely, an insufficient quantity which could be to the detriment of the patient to ventilate, knowing that hypoxia can cause cardiac arrest and the death of a patient.

To do this, some emergency healthcare workers estimate the volume of oxygen required based on a calculation formula which can be indicated in the user manual for the ventilator used.

However, this calculation is complex, a source of errors and requires having the user manual available at all times, which is not compatible with an emergency environment which requires rapid decision-making and requires the emergency physician to 'Be focused on your patient and not on the ventilator.

Furthermore, the calculation generally results in a result expressed in volume (e.g. in Liters) whereas pressurized oxygen cylinders have manometers giving pressure values, which then requires a transformation of the volume units into pressure units, and therefore generates, here again, complexity, a risk of error, a loss of time not compatible with urgency, etc.

The invention aims to solve this problem by providing the nursing staff with an estimate of the quantity of oxygen which will be necessary during emergency ventilation with transport of the patient, to allow the nursing staff, such as an emergency doctor, to easily and quickly determine the number of oxygen bottles that will be necessary during the intervention and transport of the patient, so as to avoid carrying unnecessary weight while securing ventilation, that is to say avoiding any endangerment of the patient due to an insufficient quantity of available oxygen.

• une source de gaz respiratoire pour fournir un flux gazeux,
• un circuit de gaz pour acheminer le flux gazeux provenant de la source de gaz respiratoire,
• une entrée d’oxygène en communication fluidique avec au moins une bouteille d’oxygène pour introduire de l’oxygène gazeux dans le circuit de gaz,
• au moins un capteur de débit pour mesurer au moins un débit gazeux dans le circuit de gaz,
• des moyens d’affichage configurés pour opérer un affichage d’informations,
• des moyens de pilotage à microprocesseur coopérant avec ledit au moins un capteur de débit et lesdits moyens d’affichage, et
• des moyens d’entrée de données,

The solution of the invention then concerns a medical ventilator comprising:

• a respiratory gas source to provide a gas flow,
• a gas circuit for conveying the gas flow coming from the respiratory gas source,
• an oxygen inlet in fluid communication with at least one oxygen bottle to introduce gaseous oxygen into the gas circuit,
• at least one flow sensor for measuring at least one gas flow in the gas circuit,
• display means configured to display information,
• microprocessor control means cooperating with said at least one flow sensor and said display means, and
• data entry means,

• les moyens d’entrée de données sont configurés pour permettre à un utilisateur de fournir au moins une durée de ventilation aux moyens de pilotage, et
• les moyens de pilotage sont configurés pour :

1. calculer un débit moyen à partir des mesures de débit mesurées par ledit au moins un capteur de débit sur plusieurs cycles ventilatoires successifs,
2. calculer le volume d’oxygène estimé pour opérer une ventilation du patient pendant la durée de ventilation désirée à partir du débit moyen calculé et de la durée de ventilation fournie par l’utilisateur,
3. et commander les moyens d’affichage pour opérer un affichage de la durée de ventilation désirée et du volume d’oxygène estimé calculé.

characterized in that:

• the data entry means are configured to allow a user to provide at least one ventilation duration to the control means, and
• the control means are configured to:

1. calculate an average flow rate from the flow measurements measured by said at least one flow sensor over several successive ventilation cycles,
2. calculate the estimated volume of oxygen to ventilate the patient for the desired ventilation duration from the calculated average flow rate and the ventilation duration provided by the user,
3. and control the display means to display the desired ventilation duration and the calculated estimated oxygen volume.

• les moyens d’affichage sont configurés pour afficher la durée de ventilation désirée et le volume d’oxygène estimé ayant été calculé par lesdits moyens de pilotage.
• les moyens de pilotage sont configurés pour calculer le volume d’oxygène estimé en utilisant les équations données ci-après.
• les moyens de pilotage sont configurés pour calculer le débit moyen à partir de mesures de débit mesurées par ledit au moins un capteur de débit sur au moins 10 cycles ventilatoires successifs, de préférence de l’ordre de 15 cycles ventilatoires successifs.
• le ventilateur est configuré pour fonctionner selon des cycles ventilatoires successifs, chaque cycle comprenant au moins une phase inspiratoire avec envoi de gaz au patient et une phase expiratoire pendant laquelle le patient expire du gaz enrichi en CO₂.
• les moyens de pilotage pilotent la turbine motorisée pour fonctionner selon les cycles ventilatoires successifs.
• les moyens de pilotage comprennent une carte électronique.
• les moyens de pilotage à microprocesseur comprennent un ou plusieurs microprocesseurs mettant en œuvre un ou plusieurs algorithmes, tels des algorithmes de calcul, de pilotage de la turbine, de contrôle de l’affichage, de traitement des mesures de pression ou de débit....
• il comprend en outre des moyens de mémorisation, telle une mémoire informatique.
• les moyens de mémorisation sont portés par la carte électronique.
• les moyens d’affichage comprennent un écran d’affichage à dalle tactile, de préférence à affichage en couleurs.
• la source de gaz respiratoire comprend une turbine motorisée.
• les moyens d’entrée de données comprennent au moyen une touche tactile.
• l’entrée d’oxygène est située en amont ou en aval de la turbine motorisée.
• la turbine motorisée fournit de l’air ou de l’air enrichi en oxygène.
• le circuit patient véhicule un flux gazeux riche en oxygène, en particulier de l’air enrichi en oxygène.
• le circuit de gaz achemine le flux gazeux, typiquement de l’air enrichi en oxygène, jusqu’à une sortie de gaz du ventilateur.
• la sortie de de gaz du ventilateur est raccordée fluidiquement à un circuit patient comprenant au moins un tuyau flexible alimentant une interface respiratoire, tel un masque respiratoire, délivrant le flux gazeux au patient.
• il comprend une carcasse externe.
• les moyens de pilotage sont en outre configurés pour calculer, i.e. estimer, une pression d’oxygène nécessaire pour opérer la ventilation du patient pendant la durée de ventilation désirée, et pour commander les moyens d’affichage pour opérer un affichage de la pression d’oxygène calculée.
• les moyens de pilotage sont configurés pour calculer la pression d’oxygène en utilisant les équations données ci-après.
• il comprend des moyens d’alimentation en courant électrique alimentant au moins les moyens de pilotage et les moyens d’affichage en courant électrique.
• les moyens d’alimentation en courant électrique comprennent au moins une batterie rechargeable et/ou des moyens de raccordement au secteur.

Depending on the embodiment considered, the fan of the invention may comprise one or more of the following characteristics:

• the display means are configured to display the desired ventilation duration and the estimated volume of oxygen having been calculated by said control means.
• the control means are configured to calculate the estimated volume of oxygen using the equations given below.
• the control means are configured to calculate the average flow rate from flow measurements measured by said at least one flow sensor over at least 10 successive ventilation cycles, preferably of the order of 15 successive ventilation cycles.
• the ventilator is configured to operate according to successive ventilation cycles, each cycle comprising at least one inspiratory phase with sending gas to the patient and an expiratory phase during which the patient exhales gas enriched in CO ₂ .
• the control means control the motorized turbine to operate according to the successive ventilation cycles.
• the control means include an electronic card.
• the microprocessor control means comprise one or more microprocessors implementing one or more algorithms, such as calculation algorithms, turbine control algorithms, display control algorithms, pressure or flow measurement processing algorithms, etc. .
• it further comprises storage means, such as a computer memory.
• the storage means are carried by the electronic card.
• the display means comprise a touch screen display screen, preferably with a color display.
• the breathing gas source includes a motorized turbine.
• the data entry means comprises by means of a touch key.
• the oxygen inlet is located upstream or downstream of the motorized turbine.
• the motorized turbine provides air or oxygen-enriched air.
• the patient circuit conveys a gas flow rich in oxygen, in particular air enriched in oxygen.
• the gas circuit routes the gas flow, typically oxygen-enriched air, to a gas outlet of the fan.
• the gas outlet of the ventilator is fluidly connected to a patient circuit comprising at least one flexible pipe supplying a respiratory interface, such as a respiratory mask, delivering the gas flow to the patient.
• it includes an external carcass.
• the control means are further configured to calculate, ie estimate, an oxygen pressure necessary to operate the ventilation of the patient for the desired ventilation duration, and to control the display means to display the oxygen pressure. calculated oxygen.
• the control means are configured to calculate the oxygen pressure using the equations given below.
• it comprises electric current supply means supplying at least the control means and the display means with electric current.
• the electric current supply means comprise at least one rechargeable battery and/or means of connection to the sector.

The invention also relates to a patient ventilation assembly comprising a medical ventilator according to the invention, and an oxygen cylinder fluidly connected to the oxygen inlet of the medical ventilator.

The invention will now be better understood thanks to the following detailed description, given by way of illustration but not limitation, with reference to the appended figure where:

schematizes the internal architecture and operation of a medical ventilator according to the invention, and

schematizes an embodiment of the display of the medical ventilator according to the invention of .

is a block diagram of the internal architecture of a medical ventilator 1 according to one embodiment of the invention comprising a gas source 3 serving to supply atmospheric air, that is to say air sucked into the ambient atmosphere, which air can be supplemented with oxygen supplied by an oxygen source 13, in particular a pressurized oxygen cylinder, in order to provide oxygen-enriched air to the patient.

The medical ventilator 1 comprises a carcass or external shell 14 in which the gas source 3 is arranged, namely here a motorized turbine 3.1, also called a (micro-)blower or compressor, which is equipped with an electric motor driving a wheel with fins (not visible), here delivering a flow of air (i.e. oxygen content equal to 21% by vol.), in a gas path or internal gas circuit 4, in fluid communication with the gas outlet of the turbine 3.1. Air is taken from the atmosphere and sucked in through the air inlet of turbine 3.1.

The internal gas circuit 14 comprises one or more gas conduits or passages, or the like, configured to convey the gas within the carcass 14 of the fan 1 to a gas outlet 10, also called outlet orifice or port or more simply fan output.

According to another embodiment (not shown), the gas source 3 can be an external source of the fan 1, such as a compressed air supply, for example a flexible conduit connected to a pressurized air container, such as a bottle air under pressure. In this case, fan 1 does not include a motorized turbine 3.1 but different components, such as valve(s), gas regulator, etc.

Whatever the embodiment, the air coming from the gas source 3 is conveyed by the internal gas circuit 4 to a patient P via a patient circuit 8, such as a flexible gas conduit , for example one (or more) flexible polymer tubes, to which it is administered by means of a respiratory interface 9, such as a nasal or facial mask for example. The patient circuit 8 is fluidly connected to the gas outlet 10 of the ventilator 1.

The air supplied by the air source 3, such as the turbine 3.1, is added with oxygen to obtain an air/O ₂ mixture which is then supplied to the patient P, when the latter needs an oxygen content greater than 21% by vol, for example oxygen-enriched air containing 30%, 40% or 50%, or more oxygen (vol.%).

To do this, means are provided for adding oxygen, namely a bottle of pure oxygen 13 (ie content of 100% vol. of O ₂ ) connecting to an oxygen inlet 16 fluidly connected to the gas circuit 4 of the fan 1, via a gas conduit, so as to introduce oxygen into the air flow coming from the turbine 3.1 and circulating in the gas circuit 4. The introduction of oxygen is done at an addition site 15 located here between a pressure sensor 6 and a first flow sensor 7. However, the introduction of oxygen can be done at another addition site, for example upstream of the turbine 3.1, or at the air outlet of turbine 3.1 (not shown).

Generally, the patient circuit 8 can be single branch, as illustrated in , or with double branch (not shown), that is to say comprising an inspiratory branch to bring the respiratory gas to the patient P and an expiratory branch serving to recover the gas exhaled by the patient which is enriched in CO ₂ coming from the pulmonary gas exchanges, then convey it to an exhaust valve or the like used to release it into the ambient atmosphere.

A first flow sensor 6, a pressure sensor 7 and a second flow sensor 5 are arranged or connected, in series, on the internal gas circuit 4, downstream of the turbine, to carry out pressure measurements P and flow rate Q of the gas circulating there. Here, the pressure sensor 6 is arranged or connected between the first flow sensor 5 and the second flow sensor 7.

In general, such a ventilator 1 is controlled by control means 12 also called control unit, data processing means or the like, which are configured to carry out processing of the measurements and all other data necessary for the operation of the medical ventilator. 1, and this, to control or control the proper operation of the fan 1, such as the operating cycles of the motorized turbine 3.1, typically the accelerations and decelerations of its electric motor, the displays on the display screen 2 as explained below -after or other fan components 1.

In other words, the control means 12 of the fan 1 here control the motorized turbine 3.1 delivering the air flow into the gas circuit 4, and the addition of oxygen coming from the pressurized oxygen bottle 13, so as to to deliver a flow rate and/or a pressure of gas (ie air/O ₂ mixture) according to the terms of the ventilation mode(s) selected by the doctor or the like and which are adapted to the patient P to be treated.

The ventilation modes and the associated modalities, such as the pressures, volumes and gas flow rates to be supplied, are for example indicated by means of buttons or adjustment keys 11 and/or a display screen 2, preferably with a panel. tactile and/or in color, forming a man-machine interface or HMI. Advantageously, the display screen 2 may include one or more tactile keys 11-1 used for selections or adjustments.

In fact, the HMI which includes one or more rotary buttons 11 or translational cursors or the like, and/or one or more tactile keys 11-1, allows the user, namely a nursing staff, such as a doctor, to enter one or more pieces of information or instructions into the fan 1, and/or make one or more choices, validations or selections in pre-recorded menus for example and displayed on the display screen 2, for example by pressing with a finger on the touch button(s) 11-1.

The display screen 2, such as a digital screen with a touch panel and touch keys 11-1, is configured to allow not only the display of different information, data, pictograms, graphics, etc., but also the entry or entry of data in view of their use, in particular by the control means 12, or also to make choices, selections, validations, etc. of parameters, operating modes or others.

In other words, the HMI cooperates with the control means 12 given that the settings or other selections made by the user are provided to the control means for processing and that the control means also control the information displays (e.g. selected values, curves, barograph etc.) to be displayed on the display screen 22.

The ventilation modes and/or the associated modalities can be stored in storage means, such as a computer memory, which can be part of the control means 12.

Advantageously, the control means 12 are configured to control the control valve 14, for example a controlled solenoid valve, controlling the arrival of oxygen and its supply to the gas circuit 4 to produce the air/oxygen mixture and obtain the gas. enriched with the desired oxygen, in particular depending on the gas flow delivered to the patient.

In general, such control means 12 comprise one (or more) electronic card comprising one (or more) microprocessor, such as a microcontroller, implementing at least one algorithm, which is configured to receive and process the measurements or data carried out by the pressure sensors 6 and flow sensors 5, 7, that is to say the signals coming from the sensors 5, 6, 7. The storage means can be arranged on this electronic card.

In such a fan 1, the main components of the fan 1, in particular the motorized turbine but also the pressure and flow sensors 5, 6, 7, at least part of the gas circuit 4 and the control means 12 are arranged in the external casing 11 of the fan 1, that is to say they are permanently fixed there and are normally not extractable, except when they are damaged and they must then be replaced and/or operated maintenance.

Of course, the fan 1 further comprises means of supplying electric current (not shown) such as a cord and a socket for connection to the sector (110/220V), and/or a current transformer and/or an internal battery , powering the components requiring electric current to operate, in particular the turbine, in particular its electric motor, the control means 12, the sensors 5, 6, 7, the screen 2 of the HMI or any other component.

In the context of the present invention, an estimate of the oxygen required is made based on the ventilation of the patient.

More precisely, this estimate is based on the average flow rate of several ventilation cycles, in particular the last ventilation cycles, by approximately 5 to 30 cycles, preferably from 10 to 20 cycles, advantageously approximately 15 cycles, as well as the time of ventilation considered, for example the time taken to transport the patient from one site to another.

The average flow rate of the last ventilation cycles can be determined by the control means 12 with microprocessor(s) which calculate it from the flow measurements coming from the first sensor(s) and second flow sensors 5, 6.

Concerning the planned ventilation time, this can be estimated by the nursing staff since they know approximately the time it took them to get, for example, from the hospital to the intervention site or they can do so. determine easily with a route planner available on the internet or integrated into certain applications (Apps) for multifunction telephones (i.e. smartphones), such as the Waze® Apps. Once estimated, this ventilation time can be supplied to the control means 12 via the HMI, and preferably stored there.

As illustrated in , the emergency physician can enter the estimated ventilation duration 2-1, such as here a transport time, directly on the screen 2 of the ventilator HMI, for example via one (or more) touch keys 11-1, at know here a duration of 1 hour and 50 minutes. This duration can be canceled or updated using other dedicated keys 11-1.

Knowing this information (ie estimated duration and average flow rate), or even other information such as pressure, FiO ₂ , etc., the control means 12 can calculate an estimate of the volume of oxygen planned for the estimated ventilation duration, here the 2-1 patient transport time of 1 hr 50 min.

Depending on the type of oxygen bottle 17 used, it may also be necessary to indicate the size/capacity of the bottle used, for example 5L, 10L, 11L or other (water equivalent capacity), or even another additional information, such as the volume or pressure of oxygen in the cylinder(s) considered. Indeed, such additional information may be necessary, in certain cases, for example when the cylinders are equipped with needle pressure gauges giving a pressure value and not a volume quantity, to estimate the necessary oxygen pressure value, for a certain size of cylinders, to obtain the desired volume of oxygen for emergency ventilation during transport for example. In any case, additional information can be entered as before via keys 11-1 or other keys.

At any time of ventilation, the user can request an update of the estimated oxygen volume estimate, which can be useful if, for example, the patient's condition has changed, i.e. say that the oxygen flow had to be changed, i.e. increased or decreased.

With this information, the control means 12 can calculate the estimate of the volume of oxygen as explained below.

To calculate the volume of oxygen (V) required per respiratory cycle, the control means 12 will be based on the average flow rate over several ventilation cycles, for example here 15 cycles:

V(t)= Machine flow

Once the average volume per cycle is known, the control means 12 can calculate, i.e. estimate, the total volume of oxygen necessary during the desired ventilation duration (expressed in hours and minutes for example), such as a time transport, using the following calculation formula:

V _O2 =

• V_O2est le volume d’oxygène total à calculer,
• FiO2 est la fraction d’oxygène inspirée du patient,
• Tcycle est la durée moyenne d’un cycle respiratoire.

Or :

• V _O2 is the volume of total oxygen to calculate,
• FiO2 is the fraction of oxygen inspired by the patient,
• Tcycle is the average duration of a respiratory cycle.

The FiO2 is data entered by the user into the fan 1 via the HMI or measured by a dedicated sensor connected to the fan 1, while the duration of a cycle (Tcycle) is determined by the fan 1, it is that is to say the control means 12. Here, as visible on , the FiO2 is displayed (in 2-5) by the graphic display of the display means 2, namely a FiO2 of 60% in this case.

The estimated oxygen volume value V _O2 obtained is expressed for example in mL or in L and is then displayed (in 2-3) by the graphic display of the display means 2.

We can also, if desired, determine a necessary oxygen pressure.

In this case, the control means 12 calculate the oxygen pressure necessary for ventilation from the ideal gas equation:

Or :

-P_O2(atm) is a measurement atmospheric pressure operated by a pressure sensor, for example a fan 1 sensor (expressed in Pa),

- V _O2 (atm) is the volume of total oxygen calculated above (expressed in m ³ ),

- n expresses the quantity of matter (in mol),

- R is the universal constant of ideal gases (≈8.314 JK ^-1 .mol ^-1 ), and

- T(patient) is the temperature of the gas in the patient's lungs (expressed in K), i.e. 37°C or 310.15 K.

Using the same formula as above applied to the oxygen cylinder, we obtain:

• P_O2(bouteille) est la pression d’oxygène dans la bouteille.
• V_O2(bouteille) est le volume de la bouteille (en m³).
• T (bouteille) est la température du gaz dans la bouteille (en K). Elle correspond à la température ambiante.
• n et R sont définis ci-avant.

Or :

• P _O2 (bottle) is the oxygen pressure in the bottle.
• V _O2 (bottle) is the volume of the bottle (in m ³ ).
• T (bottle) is the temperature of the gas in the bottle (in K). It corresponds to ambient temperature.
• n and R are defined above.

Knowing that: V _O2 (bottle) = Size (bottle). P (fill)

• Taille(bouteille) est la taille connue de la bouteille ; cette information peut être entrée via l’IHM. Par exemple, sur , la taille affichée (en 2-2) est B5, soit une bouteille de 5 litres de contenance (en équivalent eau).
• P (remplissage) est la pression de remplissage de la bouteille d’oxygène, par exemple 200 bar en Europe, exprimée en Pa (1 bar = 1 Pa)

Or :

• Size(bottle) is the known size of the bottle; this information can be entered via the HMI. For example, on , the size displayed (in 2-2) is B5, i.e. a bottle of 5 liters capacity (in water equivalent).
• P (filling) is the filling pressure of the oxygen cylinder, for example 200 bar in Europe, expressed in Pa (1 bar = 1 Pa)

We then obtain:

Either :

Once calculated by the control means 12, the value of P _O2 (bottle) can be displayed (in 2-4) on the display means 2 by being expressed in Pa or in Bar, as illustrated in .

Thus, on , we see that, in the example given, for an estimated transport time of 1h50min and a B5 bottle, we must be able to have approximately 25 L of oxygen or a pressure of approximately 150 bar in the bottle.

If the bottle in question contains less than 25 L or a pressure less than 150 bar (indicated by the electronic or needle pressure gauge fitted to the bottle), then the nursing staff must provide at least one additional bottle or use another full or almost full bottle. -full, that is to say containing at least the estimated quantities of oxygen (i.e. at least 25 L or at least 150 bar) and preferably more to provide a safety margin.

The present invention is particularly suitable for use by emergency teams by enabling them to determine what volume of oxygen or what pressure of oxygen will be necessary to ensure effective and sufficient ventilation of a ventilated patient during transport. 'one site to another.

Claims (7)

Medical ventilator (1) comprising:

• a respiratory gas source (3) to provide a gas flow,
• a gas circuit (4) for conveying the gas flow coming from the respiratory gas source (3),
• an oxygen inlet (16) in fluid communication with at least one oxygen bottle (13) to introduce gaseous oxygen into the gas circuit (4),
• at least one flow sensor (5, 6) for measuring at least one gas flow in the gas circuit (4),
• display means (2) configured to display information,
• microprocessor control means (12) cooperating with said at least one flow sensor (5, 6) and said display means (2), and
• data entry means (11),

characterized in that:

• the data input means (11) are configured to allow a user to provide at least one ventilation duration to the control means (12), and
• the control means (12) are configured to:

1. calculate an average flow rate from the flow measurements measured by said at least one flow sensor (5, 6) over several successive ventilation cycles,
2. calculate the estimated volume of oxygen to ventilate the patient for the desired ventilation duration from the calculated average flow rate and the ventilation duration provided by the user,
3. and controlling the display means (2) to display the desired ventilation duration (2-1) and the calculated estimated oxygen volume (2-3).

Medical ventilator (1) according to claim 1, characterized in that the display means (2) are configured to display the desired ventilation duration and the estimated volume of oxygen having been calculated by said control means (12). Medical ventilator (1) according to claim 1, characterized in that the control means (12) are configured to:

• calculate an oxygen pressure necessary to ventilate the patient for the desired ventilation duration, and
• control the display means (2) to display the calculated oxygen pressure (2-4).

Medical ventilator (1) according to claim 1, characterized in that the display means (2) comprise a touch screen display screen. Medical ventilator (1) according to claim 1, characterized in that the respiratory gas source (3) comprises a motorized turbine (3.1). Medical ventilator (1) according to claims 1 and 4, characterized in that the data input means (11) comprise by means of a touch key (11-1) displayed on the touch screen display screen. Patient ventilation assembly (1, 13) comprising a medical ventilator (1) according to one of the preceding claims, and an oxygen bottle (13) fluidly connected to the oxygen inlet (16) of the medical ventilator ( 1).