Difference between revisions of "Lowenstein PrismaLine optimization"
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Nearly all of these settings can be affected by one another and also the size of the minimum and maximum pressures set. If you analyze breath shapes displayed by OSCAR and use the tools available to shape these breaths and bring your volumes into comfortable ranges, you should be well on your way to mastering this element of your therapy. | Nearly all of these settings can be affected by one another and also the size of the minimum and maximum pressures set. If you analyze breath shapes displayed by OSCAR and use the tools available to shape these breaths and bring your volumes into comfortable ranges, you should be well on your way to mastering this element of your therapy. | ||
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==Anticyclic Servoventilation== | ==Anticyclic Servoventilation== |
Revision as of 01:32, 4 July 2024
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Contents
OSCAR Optimisation for Lowenstein
Prisma Smart & Prisma 20A Devices
Lowenstein PrismaLine machines produce a lot of overlays and event flags. If left in default view, this excessive data will overwhelm your OSCAR display. It will make it impossible for forum members and medical professionals, to quickly understand how you are responding to your machine and its settings. Here are a few tips to help clean up that display and make the detailed data your machine is producing, a lot more meaningful.
If you are starting with a fresh OSCAR install, make sure to optimize first according to apneaboard recommendations here:
https://www.apneaboard.com/wiki/index.php?title=OSCAR_Chart_Organization
Event Types
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Flow Limitation Flag Color
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Adjust y-axis scaling
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Finally, be sure to resize all graphs either through preferences, or by manually dragging them to fit more of the important ones in a single screen clip.
Advanced users
Advanced users may set Y-Axis over-ride on many of the other charts as well. This increases user friendliness and read-ability. Otherwise, outlier data can re-scale the chart, causing irregular display of the main data and confusing day to day comparisons. The increments of Y-Axis may also end up in strange divisions. On the included examples, most of the Y-Axis have been overridden to give a repeatable and consistent view of each metric. Y-axis overrides that increase usefulness are, leak rate 0-50 with dotted line at leak threshold and tidal volume 0-1000. Mask Pressure & Pressure can benefit from overide by setting to a tighter range around your own specific pressures. Try make all Y-Axis increments equal whole numbers. A dotted line at max mask pressure can be handy if using APAP.
Finally, but maybe most helpful for interpreting your data, is to create at least 2 profiles. The first one I call 'compact' and the other 'detailed'. In the compact profile, shrink the height of as many data rows as possible. Size the flowrate graph so the spike ups are not too prominent, but the biggest are still easily seen. This will give you a good general picture of a nights therapy. Most full charts pictured in this wiki are using this compact view.
However, this compact view will not be best for analyzing breath shapes and fine tuning therapy settings. This is especially true as soon as you start using bi-level or any variant of it, like softpap or epr etc. For this you will want a profile you can switch too quickly with a couple of critical changes to at least Flow Rate and Mask Pressure. In order to set these for best viewing, you should make sure the y-axis override is not too far off the actual flow rate and your pressure range. Make sure your OSCAR window is maximized or a least how you usually view it. Pick the best section of one of your best nights. Zoom in with left click until the flowrate duration is 1 minute. From here, drag the row height so that each inhalation is close to semi circle, without being too tall or too squat. Roughly match the mask pressure signal to the same height as each breath signal, so they are relative to each other.
Note: Consistent viewing will be dependent on your window size and flowrate duration being the same as they are when you set this.Without a set baseline and zoom like this, you will not get as good a sense of each day compared to one another. Breaths can appear far taller or flatter, all dependent on these variables. If you are wanting to see subtle change in breath dynamics with a change in pressure support for eg. then this is very helpful.
Extra Settings for Prisma Bi-Level Devices
Apart from the above display settings, Lowenstein Bi-level devices can need some extra tweaking.
Display Deep-Sleep
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User Defined Flow Limitations
NOTE If the custom flags are not showing after restarting OSCAR, you will have to use the 'rebuild cpap data' menu option. |
PrismaLine CPAP & APAP modes
SoftPAP Compared EPR
There is quite a difference in the so called "comfort" settings of the various CPAP & APAP machines. Lowenstein Prisma Smart & Prisma20A provide these settings as a limited form of regular Bi-level modes found on bi-level machines. These bi-level modes allow a more sophisticated pressure range for addressing more complicated respiration needs.
Lowenstein SoftPap is here compared in application to the EPR of Resmed.
Algorithm differences
Bi-level is the application of more than one pressure level during different breathing stages. The example below shows bi-level therapy in action. This is infact not on a "Bi-level" machine, but a Prisma20A with CPAP pressure of 12cmH2o and Softpap2 activated. The machine is now applying 2 different pressures. The lower pressure of EPAP (exhalation positive airway pressure) and the higher pressure of IPAP (inhalation positive airway pressure). The difference between these two pressures is termed pressure support, abreviated normally to PS. The example below shows a PS of 3cmH2o. This is the maximum PS available on a Prisma Smart and delivers the same support as Resmeds EPR 3, although as you will see, the differing air delivery of the two devices, affects how this pressure support shapes your breathing.
If we look closely at the bi-level algorithm in use by Lowenstein, we notice that following the release of IPAP pressure down to EPAP pressure, the machine immediately begins to ramp back up to IPAP pressure. During a period known as EEPAP (end expiratory positive airway pressure), the pressure already well on the way to peak pressure and will arrive at IPAP pressure early during inspiration. This is how Lowenstein achieves Apnea control at lower main pressures. By gently ramping back to max pressure throughout exhalation (when Apneas develop) and stenting the airway during late exhale and into the pause between exhale and inhale at zero on the flow chart.
In contrast, the Resmed example below shows the very different implementation of a Bi-Level mode. The lower pressure of EPAP is maintained throughout exhalation, it does not provide a movement toward IPAP pressure until the beginning of inspiration. Peak IPAP pressure is not reached until mid to late inspiration.
Often when pressure is insufficient, you can see in a Resmed trace, the second hump in the flow rate and/or the fuller second half of inspiration. The example above has pressure set to 6cmH2o and with EPR of 2 (a common minimum pressure new users are sent home with). You can see the obvious instability. This is why with a Resmed machine, the moment you switch on EPR, you are setting a new lower EPAP pressure. Not only that, you will spend a majority of time now at this lower EPAP pressure and during inspiration some time between the two pressures. A user will spend only a very brief time at peak IPAP pressure. You must take this into consideration. If you are looking to keep EPAP where it was, but increase pressure in inhalation then you would increase main pressures by the same amount of EPR that you use.
This same principle is not generally needed with SoftPap. It behaves in the reverse of Resmed EPR. You will spend a large amount of time around IPAP pressures and only briefly drop to EPAP . This does affect how each unit must be set and what disordered breathing conditions these two methods favour. You must understand how each tool works to effectively treat differing conditions.
Response to Events
Another consideration when setting either SoftPap or EPR, is how each responds during an event. Resmed machines maintain EPAP pressure during events, whereas Lowenstein maintains IPAP pressure, or when in lowensteins' Tri-level mode, EEPAP pressure (end expiratory positive airway pressure). This mode is discussed further on.
Resmed EPR3
Lowenstein SoftPap2
Flow Limitations
Lowenstein softPAP 1 & 2 algorithm favors Apnea control at lower pressures on basic CPAP/APSAP models. However there are a vast range of sleep disordered breathing conditions that need specific help. If you look closely at previous example, you can see the holding of steady pressure right through inspiration, can allow inspiratory instability as in this case with UARS (upper airway respiratory syndrome). UARS sufferers may experience persistent narrowing of the airway when this mode of therapy is applied on the models more suited for generalized obstructive sleep apnea.
Softpap3 or Tri-level support does give some advanced level of multilevel support for a mix of OSA and UARS. This mode is introduced in the Prisma20a models and beyond. In this mode the machine addresses the problem of flow limitations by adding an extra level of inspiratory support. This mode applies an extra 1cmH2o to your machine set IPAP pressure. This raises your IPAP by 1cmH2o and applies it during early inspiration to stabilize these flow limitations. This mode has different trigger points for following your breathing pattern.
Normally, in regular Softpap and EPR, the ramp rate is constant. Here, you can see in the example below, that the ramp rate of Softpap3 or Tri-level mode, increases and decreases to stay in time with shorter and longer breaths. SofPap 3 increases the maximum pressure support offered by Tri-Level mode to 4 cmH2o, but this only comes into effect @ 12cm H2o and beyond. Below is a period of flow limitation that softpap 3 is managing.
As you can see, each of these machines must be approached very differently in use. They are tools with various modes of operation, different strengths and weaknesses. Lower level machines are factory limited to reduce the amount of useful pressure support. These entry level machines are often only useful for rudimentary control of OSA. Many people having trouble with obtaining not only apnea control but better sleep, often need these Bi-level or Tri-level modes properly applied. They really change therapy quite drastically. In quite a few instances, more levels of pressure support and finer adjustments to match an individuals breathing patterns are needed and so a step up in machine ability is required. You would be advised to quickly figure out if your machine will do what it needs to. Stop torturing yourself if you need to move to a dedicated bi-level machine.
SoftPap Application in Detail
Available pressure support in each SoftPap level 1, 2 & 3 increases as pressure goes up. This can be confusing, and is best explained visually, with another chart. Gotta love charts. Remember that PrismaSmart only has access to the levels 1 & 2 of softpap. Prisma20a and above to all 3 levels of Softpap.
You can see that as cpap pressure is increased, the size of each level of pressure support increases. 8cmH2o and 12cmH2o are key pressures when this happens. You can have a situation where your IPAP is increased by double that of your EPAP. You can also maintain constant EPAP, whilst auto apap increases your IPAP pressure like this below. Where this could come into play is if you are sitting just beneath one of these pressures with your Apnea well controlled but can benefit from a bump in upper pressure limits during REM. If a user is shy of high pressure, or suffers aerophasia around one of these pressures, this smaller step in EPAP can help. You could, as above image shows, set APAP with a range of 11.5cm to 12cm & softPap 3. During REM or a positional change etc, the extra support kicks in on any flow limitations that develop with virtually no detectable EPAP increase. The Prisma20a can hold this extra pressure for just the right length of time during a rough patch, before letting you back down. This may only put you into aerophasia territory for a very limited time the whole night and minimizes disturbances from moving pressures. Also of note, is what happens at low pressures using SoftPap. On SoftPap 3 the first few pressures are identical. I wonder how many beginners and doctors think they are gradually increasing their pressure over a period, when they are actually not changing anything but a number on the LCD display. |
PrismaLine Bi-Level Modes & Machines
In tuning Bi-levels machines in particular, awareness of ventilation principles, pressure targeted ventilation (PTV) and volume targeted ventilation (VTV) are very helpful. PTV is used in cpap machines like those used for sleep apnea therapy. VTV on the other hand, is generally used for intubated critical care patients.
Each mode has a differing way of calculating and delivering air. VTV aims to hit a settable volume target, where pressure remains variable. PTV aims to hit settable pressure targets like IPAP and EPAP, whilst leaving volumes variable.
The major factor affecting use of each mode, is the mask or tube seal. Volume targeted ventilation, needs a good seal to be effective, any leaks are counted towards volume delivered. Intubation ensures this seal. Pressure targeted ventilation, which commonly use an external mask, naturally accounts for any leaks by simply ensuring that the pressure target is reached at all times. This can be done up until the point where you hit the leak redline, limiting the machines ability to meet its pressure target.
PTV is the mode we are largely dealing with here.
With pressure targeted ventilation, obviously the correct therapy pressures must be set, but this is only the first part of the puzzle. Volume, is an important variable we must control. This is determined by the interaction of complex machine settings, user physiology and pulmonary condition. The variability of this system necessitates careful assessment of each of these three areas, to allow making informed choices when trying to achieve ventilation synchrony. This is a concept whereby machine and user are in time and satisfying the respiratory need, without fighting each other. This can cause arousal and very poor sleep quality, despite possibly having great apnea and hypopnea control.
Due to the increasing complexity of Bi-level support, and the miriad of adjustments offered by Lowenstein, a number of predetermined settings called "scopes" are provided in each bi-level mode. These presets are designed and tested to be used as a starting point for differing pulmonary conditions and co-comorbidities.
These scopes are:
- OVERLAP which is designed for users with obstructive sleep apnea and mild to medium COPD.
- HYPOV which is designed for users with nocturnal hypoventilation.
- OSAS which is designed for users with severe obstructive sleep apnea and a high pressure requirement.
We are going to try explore the various settings available within these "scopes", for essentially creation of your own personalized "scope". Your custom scopes can be saved and recalled from within the PrismaTS software and uploaded to a device via LAN or SD card. Of course manual adjustment of each individual setting is always possible via the machine panel.
The Settings
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Study of your flow rate graph in conjunction with mask pressure will be invaluable in fine tuning therapy settings.
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Further adjustments to the flow shape can be made.
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Nearly all of these settings can be affected by one another and also the size of the minimum and maximum pressures set. If you analyze breath shapes displayed by OSCAR and use the tools available to shape these breaths and bring your volumes into comfortable ranges, you should be well on your way to mastering this element of your therapy.
Anticyclic Servoventilation
The PrismaCR models of Lowensteins PrismaLine range offer an ASV mode for treatment of central and mixed apnea.
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