The Use of Passive and Invasive CO 2 Elimination via interventional Lung Assist System iLA [ Novalung ® ] on a Small Intensive Care Unit of a Hospital for Basic and Regular Care

Background: High volume intensive care units with high expertise on respiratory distress syndromes are familiar with extracorporeal CO2 elimination procedures in regard to their maintenance. In contrast, small intensive care units offer a lack of this experience. So, a novel approach (passive, invasive, without any further specification) plugs this lack of experience. Case Report: A 60 years old male patient in poor health conditions was presented to our small intensive care unit due to shortness of breath in regard to bilateral pneumonia in septic shock. Sedated and intubated, we monitored blood gas analyses and observed pCO2 problems, raising to 150mmHg with stable pO2 85mmHg. We used interventional arteriovenous lung assist system iLA (Novalung®, Heilbronn, Germany) and improved respiratory conditions by reduction of pCO2 to normal levels constantly for 10 days. Using iLA (Novalung®) on our small ICU we healed passively and invasive the patient for discharging on day 15. Conclusion: This case report clearly demonstrates the unspectacular use of the highly effectual passive and invasive CO2 elimination system iLA, Novalung® (Heilbronn, Germany) even on a small intensive care unit of a hospital for basic and regular care in Germany. Received: May 05, 2019; Accepted: June 17, 2019; Published: June 18, 2019 European Journal of Respiratory Medicine 2019; 1(1): 101 104. doi: 10.31488/ejrm.101 Eur J Respir Med,1:1 European Journal of Respiratory Medicine Kostov V1, Maier, M1, Stoerzbach S2, Barth T2, Clement R2, Döffert J2, Oberhoff M1, Anger T*1 1. Department for Internal Medicine, Klinikum Calw-Nagold, Germany 2. Department for Anesthesia, Klinikum Calw-Nagold, Germany The Use of Passive and Invasive CO2 Elimination via interventional Lung Assist System iLA [Novalung®] on a Small Intensive Care Unit of a Hospital for Basic and Regular Care

medicine [cardiology, gastro-enterology and hematology/ oncology], orthopedics, neurology, obstetrics-gynecology and anesthesiology and critical care medicine, neurology, orthopedics and trauma surgery, gynecology for basic and regular care in South Germany due to shortness of breath in the emergency room. As co-morbidities, we had to handle with schizophrenia, multiple sclerosis, epilepsy, chronic obstructive lung disease due to extreme consume of nicotine.
The patient got immediately intubated, ventilated and physically dependent to the respiratory breathing system (Evita, Infinity V500, Draeger®, Lübeck, Germany). Related to the ventilation, we were forced to decrease the observed CO2 retention and we monitored blood gas analyses with pCO2 rising to 150mmHg under all additive ventilatory support (bronchoscopy, kinetic mobilisation, lung-targeted use of antibiotics, lung-preventive ventilation support, respectively) with pO2 maximum stable to 85mmHg. On top, pH levels decreased to lowest 6.99. Additional, the septic shock was attacked using nor-epinephrine and hydrocortisone, preventive support was applied as well: pantoprazole or i.e. support of enteral nutritive factors up to 1.75 liter a day (correspondence to 1750kcal a day). The daily medications in reflection to his co-morbidities were applied as well orally.
We decided additionally to use a passive, invasive interventional Lung Assist system to eliminate CO2 (9): iLA (Novalung®, Heilbronn, Germany) [ Figure 2] in regard to the lack of physicians in afternoon-/ night worktime on the ICU board maintaining an active extra corporal lung assist, i.e. CARDIOHELP, Marquet® or LIFEBRIDGE 2.0, Zoll® (10). We assumed 15 French (15F) artery support to the iLA femoral left, set the iLA system (Novalung®) between his legs and re-insufflated the blood venously (15F) to the right femoral vein passively ( Figure 2). Flow of oxygen was initially adapted to 10 liters per minute and nor-epinephrine was used to support blood flow to 1.2 liters per minute in the iLA system and to abolish the CO2 monitored through external device ( Figure 3) with a "device related receptor" fixed on the venous blood flow system ( Figure 4). The iLA Novalung® system was developed as passive as well as invasive artery-venous Shunt system for diffusion and displacement of CO2 to O2 in the patient own blood flow [11]. Therefore, the circulatory cardiac conditions have to be improved, monitored intensively and supported (nor-epinephrine). Inside of the iLA, the membrane ventilation occurs, and displaces CO2 to O2 in the blood flow maintained through the own patient's circulation. In general, the use of these CO2 elimination systems were maintained on ICU's with fast turnover and effective experiences.
Meanwhile in the time course, we were able to reduce passively pCO2 from 150mmHg on iLA-day 1 to 50mmHg on day 10 reducing the initial oxygen flow of 10 liters per minute through the iLA system to almost 0 liter per minute under circulatory stable conditions: nor-epinephrine supported 1.2 liters per minute venous blood flow through the system and 99% saturation of O2 using diffusion to eliminate CO2 on the mem- Figure 1. Chest X-Ray. Chest x-ray slides were performed ad admission to the hospital/ intensive care unit, a�er supply of addi�ve catheters (breathing tube, central vein catheter, probe for stomach) and in episodes of �me course to manage pneumonia infiltra�ons and lung-targeted specific an�bio�cs. Here is an example for the chest x-ray ad admission demonstra�ng emphysema of the lung, signs of chronic obstruc�ve lung disease, old frac�ons of the ribs on le� lower side, infiltra�ve changes in both lower and middle lobs of the lung, diaphragm plane and extremely down and some electro-cardiogramm cables (ecg).

Figure 2.
iLA Novalung® CO2 elimination system, passive, invasive, comfortable. Interven�onal Lung Assist system iLA (Novalung®, Heilbronn, Germany) to eliminate CO2 and to displace it with O2 on membranes in the devices was used for this pa�ent on the intensive care unit of the small hospital for basic and regular care in Germany. The device maintaining the membranes was put in the bed between the legs. Incoming arterially blood was managed through 15F success of le� femoral artery and goes into the device, oxygen support (divers oxygen flow from 0 liter per minute up to 10 liters per minute -see green tubing on the device) will manage diffusion of CO2 and will displace CO2 to O2 in the device. Back to the pa�ent, blood flow will get monitored and successfully maintained through 15F access to right femoral vein.

pO2 [mmHg]
branous filters of the iLA system ( Figure 5 -upper diagram)without any further medical support and without having physicians continuously monitored the iLA system throughout the afternoon-/ night worktime. Oxygen levels stayed stable throughout the whole use of the device ( Figure 5 -lower diagram). Additionally, initial decreased pH levels to lowest 6.99 were maintained to increase to normal levels over the complete use of iLA on ICU and marked stable (see figure 6). The patient was sedated in a RASS-State -3-4 (Richmond Agitation and Sedation Scale) with Sevoflurane via the AnaConDa-S®-System.
On iLA-day 10 (in total day 12 on the ICU) we retracted successfully the system by primarily removing the venous tubing (15F) manually and secondly the arteriosus system (15F) using Femostop, St. Jude Medical® for at least 12h. Finally, we found unremarkable conditions on both groins and warm pulsed feed. Lastly, the patient recovered quick and got discharged from hospital on day 15 in total for rehabilitation in reflection to medical purposes.

Summary and Conclusions
This case report clearly demonstrates (i) the unspectacular use of the highly effectual passive and invasive CO2 elimination system iLA from Novalung® (Heilbronn, Germany) even on a small intensive care unit of a hospital for basic and regular care in Germany [12]. (ii) The effectual elimination of CO2 in patients suffering septic pneumonia will support faster recovery, will lower breathing mechanics [13] for the patients under specific intensive care unit conditions and ventilatory support even when no further problem for oxygenation occurs [10]. Therefore, (iii) pH levels and pCO2 levels were improved as fast as possible. Without specific vascular surgeons (iv) we handled and managed the device successfully. During afternoon and night-shift, (v) no additional physician was necessary to maintain the CO2 elimination system.  (Novalung®, Heilbronn, Germany). Satura�on data of O2 in the probe will care for the successful diffusion of CO2 on the membranes (data on the le� of the display), blood flow [liter per minute] will maintain correct and adequate circula�on to support effec�ve blood flow to the iLA device (data on the right of the display).  The upper diagram shows the course of the pCO2 levels, the lower diagram the course of the pO2 levels for the pa�ent on the intensive care unit in our hospital for basic and regular care. Due to known severe chronic obstruc�ve lung disease commi�ed by ac�ve consump�on of nico�ne, we decided to remove the iLA system while pCO2 levels were below 70mmHg and pO2 levels above 85mmHg -see diagrams. Shown here are the various BGA's of pH levels in rela�on to the use of the iLA system for 10 days. The use of the passive and invasive iLA system (Novalung®, Heilbronn, Germany) improved quickly the reduced pH levels from 6.99 to normal and kept these normal levels during the ICU stay as demonstrated in the shown diagram.