Received 11/15/2018 
Review began 11/19/2018 
Review ended 11/28/2018 
Published 11/30/2018

© Copyright 2018
McDermott et al. This is an open
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Shunting of Oxygenated Blood to the
Venous System in the Avalon® Cannula on
Venovenous Extracorporeal Membrane
Oxygenation with High-frequency
Oscillatory Ventilation
Lydia McDermott  , Nicholas C. Cavarocchi  , Hitoshi Hirose 

1. Surgery, Thomas Jefferson University, Philadelphia, USA 2. Cardiothoracic Surgery, Thomas Jefferson
University, Philadelphia, USA

 Corresponding author: Hitoshi Hirose, genex@nifty.com 
Disclosures can be found in Additional Information at the end of the article

Abstract
High-frequency oscillatory ventilation (HFOV) may assist in the prevention of volutrauma for
high-risk patients with acute respiratory distress syndrome (ARDS) during venovenous
extracorporeal membrane oxygenation (VV ECMO). In combined VV ECMO and HFOV, we
noted that increased intrathoracic pressure contributed to shunt formation in the dual-lumen
Avalon® cannula (Maquet, Rastatt, Germany).

A 51-year-old female with ARDS secondary to aspiration pneumonia was placed on VV ECMO
using a single Avalon cannula. By ECMO Day 16, she became unable to ventilate due to elevated
peak airway pressures, even with low tidal volume ventilation and an otherwise stable VV
ECMO course. HFOV was introduced to minimize ventilator-induced lung injury. Shortly after
HFOV started, the patient desaturated, and consequently, the fraction of inspired oxygen (FiO2)

was increased to 100%. We noted that a flash of bright red, oxygenated blood was flowing
retrograde in the Avalon cannula at the same rate as the beat of the oscillator, while the
patient's ECMO flow rate, arterial blood gas, and blood pressure all remained stable. The ECMO
flow was increased above 5.5 L/min and the resolution of the retrograde shunt through the
Avalon cannula was immediately observed. 

Concurrent use of HFOV with VV ECMO using an Avalon cannula may result in a shunt that
becomes visible with arterial O2 saturations nearing 100%. Due to pressure differences between

the venous and arterial lumens of the Avalon cannula, increasing the ECMO flow rate appeared
to decrease this shunting effect caused by elevated intrathoracic pressure.

Categories: Cardiac/Thoracic/Vascular Surgery, Cardiology, Pulmonology
Keywords: high-frequency oscillatory ventilation (hfov), acute respiratory distress syndrome (ards),
extracorporeal membrane oxygenation (ecmo), avalon cannula

Introduction
In addition to removal of the initial insult, treatment of acute respiratory distress syndrome
(ARDS) consists primarily of symptom management. Conventionally, lung protective
ventilation practices are used to decrease further volutrauma, while extracorporeal membrane

1 2 2

 
Open Access Case
Report  DOI: 10.7759/cureus.3661

How to cite this article
Mcdermott L, Cavarocchi N C, Hirose H (November 30, 2018) Shunting of Oxygenated Blood to the
Venous System in the Avalon® Cannula on Venovenous Extracorporeal Membrane Oxygenation with
High-frequency Oscillatory Ventilation. Cureus 10(11): e3661. DOI 10.7759/cureus.3661

https://www.cureus.com/users/110176-lydia-mcdermott
https://www.cureus.com/users/11465-nicholas-c-cavarocchi
https://www.cureus.com/users/13484-hitoshi-hirose


oxygenation (ECMO) is introduced for added support in cases complicated by refractory hypoxia
and/or hypercarbia. Common additional adjuncts include prone therapy, deep sedation and
paralysis, and nebulized vasodilators.  

For ARDS patients with high airway pressures intractable to maximum therapies, including
lung protective ventilation and ECMO, high-frequency oscillatory ventilation (HFOV) should be
considered [1-3]. HFOV provides a small tidal volume (1 - 4 ml/kg) in high-frequency (3 - 15 Hz)
to optimize alveolar gas exchange while eliminating peak pressure and full pulmonary
expansion in the setting of restricted compliance.  

Our current venovenous extracorporeal membrane oxygenation (VV ECMO) practice includes
the use of a single, dual-lumen Avalon® cannula (Maquet, Rastatt, Germany) placed to the right
internal jugular vein, although with this positioning, the applied intrathoracic pressure created
by HFOV may compete with the ECMO flow. Herein, we report a case of blood shunting
observed in an Avalon cannula and treated with an increase of ECMO flow.

Case Presentation
A 51-year-old female (weight: 73.5 kg; height: 160 cm) with ARDS secondary to aspiration
pneumonia was placed on VV ECMO using a single 27 Fr Avalon cannula to the right internal
jugular vein. Her peak airway pressure was 46 cm H2O, even with low tidal volume (200 ml)

ventilation, and eventually, she was unable to ventilate safely due to decompensated
compliance. HFOV with a frequency of 300 bpm and 5 Hz was introduced on ECMO Day #16 to
decrease the risk of volutrauma while also preventing atelectasis from hypoventilation. Her
mean airway pressure (mPaw) became 29.3 cm H2O with HFOV, which comparatively had been

16 cm H2O on the conventional ventilator. At the time of transition to HFOV, her settings were:

ECMO flow 4.56 L/min, Sweep 6 L/min, FiO2 70%, with ventilator FiO 2 50%. Approximately two

hours later, the patient desaturated requiring FiO2 100% on both the ECMO and HFOV to

maintain an O2 saturation (SaO2) of 85%, although the ECMO flow was maintained at 4.5

L/min. These same settings were continued before a flash of bright red, oxygenated blood was
noted flowing into the venous return lumen of the Avalon cannula which synchronized with
each beat of the oscillator (Video 1). 

VIDEO 1: Avalon cannula
Flash of bright red, oxygenated blood is noted flowing into the outflow lumen in the patient
from the Avalon extracorporeal membrane oxygenation (ECMO) cannula (yellow arrow), suggesting
recirculation of oxygenated and unoxygenated blood.

View video here: https://youtu.be/ZiueEO7Fhnc

2018 McDermott et al. Cureus 10(11): e3661. DOI 10.7759/cureus.3661 2 of 4



The correct placement of the Avalon catheter and endotracheal tube were confirmed by chest x-
ray, and an echocardiogram further confirmed the cannula position (the tip in the inferior vena
cava and the access lumen facing the tricuspid valve), as well as ruled out a patent foramen
ovale or an atrial septal defect. Inter-atrial shunting within the Avalon cannula was diagnosed,
and the ECMO flow was increased above 5.5 L/min to overcome the additional resistance. This
provided a resolution of the retrograde shunt. Despite all efforts, this patient, unfortunately,
expired due to multi-organ failure. Her family elected to withdraw care after a total of 20 days
on ECMO and four days on HFOV.

Discussion
It was hypothesized that the pulses of applied intrathoracic pressure created by the HFOV
contrasted with the systemic low pressures of the venous system where the Avalon cannula lies,
causing the intra-atrial shunt. As described by Sklar et al., elevation of the right atrial (RA) and
pulmonary artery pressures (PAP) were observed during HFOV [4]. In an ECMO circuit, negative
pressure (approximately -80 mmHg assuming an ECMO flow of 4.5 L/min with an Avalon
cannula size 27 Fr) was maintained through the return lumen while positive pressure
(approximately 240 mmHg assuming an ECMO flow of 4.5 L/min with an Avalon cannula size 27
Fr) is applied by the centrifugal pump into the access lumen. Using the Avalon cannula allows
the circuit to suction de-oxygenated blood from the superior vena cava (SVC) and inferior vena
cava (IVC) and instill oxygenated blood toward the tricuspid valve simultaneously creating a VV
ECMO system through only one insertion site. With augmented external pressure from HFOV,
the PAP suddenly elevates and causes the Avalon catheter’s oxygenated out-flows to face an
increased resistance which can dilate the RA when sustained. Thus, turbulent flow within the
RA may cause shunting that can exacerbate hypoxia as oxygenated blood recirculates towards
the venous return lumen of the Avalon cannula. In our patient, we believe the intra-atrial
recirculation became noticeable due to a deepened contrast between the venous and arterial
blood as the FiO2 from ECMO was raised to 100%.

To decrease PAP, deep sedation and paralysis may be necessary, though these were already
being applied in this case. Furthermore, inhaled vasodilators, such as nitric oxide or
epoprostenol, are an additional adjunct; however, we have found this therapy to be impractical
during HFOV use. Instead, we increased the VV ECMO flow above 5.5 L/min, which was able to
unload the RA by overcoming the raised PAP (access lumen approximately 400 mmHg) and
optimizing suction from the SVC and IVC (return lumen approximately -110 mmHg), resolving
the intra-atrial shunt. While maintaining a high ECMO flow is possible, this requires additional
patient monitoring and care due to a concomitant heightened risk of mechanical hemolysis. For
this reason, we determined that, while interesting to note, intra-atrial shunt presence is
clinically relevant to the patient primarily when contributing to decompensated hypoxia
refractory to typical management strategies (namely, increasing FiO2). Therefore, we elected to

continue this patient’s ECMO management per usual protocols by setting the ECMO flow based
on the body surface area (BSA) and symptom severity (with the goal to maintain the SaO2 above

85% and a normal pH) rather than on the mere presence or visibility of a shunt.  

Upon review of this case, we are reminded that the mPaw on HFOV is higher than that of lung
protective ventilation via a conventional ventilator. While this comparative increase is
expected due to the need for accommodation of the loss of dynamic PEEP, perhaps the mPaw
could have been decreased in a setting of resolved hypoxia. As suggested in Sklar et al.,
elevated mPaw itself may contribute to volutrauma, potentially explaining the failure of HFOV
to be proven beneficial thus far [4]. It should be considered that while lung protective
ventilation has been shown to improve ARDS outcomes during conventional ventilation,
standard practice settings are applied during HFOV to maintain an adequate gas exchange.
Facilitation of lung protective ventilation while on HFOV could be possible with the concurrent

2018 McDermott et al. Cureus 10(11): e3661. DOI 10.7759/cureus.3661 3 of 4



use of HFOV and high-flow ECMO, however. While we were unable to attempt this method for
our patient due to sustained hypoxia, it may simply be that stricter parameters and a decreased
mPaw are required to create a mortality benefit, as well as limit intra-atrial shunting, as we
described. Further research is required to evaluate the outcomes of severe ARDS patients on
minimized, lung protective HFOV settings. 

It is known that HFOV may promote hemodynamic instability and other sequelae, though once
identified, mitigation of these problems may be possible. Regardless, present information
suggests that HFOV worsens ARDS mortality for mild-moderate cases and remains unproven as
a benefit for severe cases. Its use continues to be up for debate; therefore, it is not
recommended as an initial therapy. However, HFOV can be a useful adjunct in patients who
continue to fail after conventional ventilator management is maximized with concurrent use of
ECMO, paralysis, prone therapy, and nebulized epoprostenol. The expansion of care modalities
is critical to continue advancing the ability for high-risk patients to recover from severe
episodes of ARDS.

Conclusions
By maintaining safer pulmonary pressures with HFOV, while improving the exchange of gasses
via ECMO, lungs impaired by ARDS that have failed conventional ventilation may be further
allowed to heal. In the event that a clinically relevant intra-atrial shunt occurs during the
concurrent use of HFOV with VV ECMO via an Avalon cannula, it is likely that an increase in
the ECMO flow rate will decrease the shunting effect.

Additional Information
Disclosures
Human subjects: Consent was obtained by all participants in this study. Thomas Jefferson
University Institutional Review Board issued approval 11D.185. We are submitting a case report
which is waived from consent form. All ECMO patient registry at Thomas Jefferson University
was approved by Thomas Jefferson University IRB file number #11D.185 (Outcome after ECMO
(extracorporeal membranous oxygenation)). Conf licts of interest: In compliance with the
ICMJE uniform disclosure form, all authors declare the following: Payment/services info: All
authors have declared that no financial support was received from any organization for the
submitted work. Financial relationships: All authors have declared that they have no
financial relationships at present or within the previous three years with any organizations that
might have an interest in the submitted work. Other relationships: All authors have declared
that there are no other relationships or activities that could appear to have influenced the
submitted work.

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	Shunting of Oxygenated Blood to the Venous System in the Avalon® Cannula on Venovenous Extracorporeal Membrane Oxygenation with High-frequency Oscillatory Ventilation
	Abstract
	Introduction
	Case Presentation
	VIDEO 1: Avalon cannula

	Discussion
	Conclusions
	Additional Information
	Disclosures

	References