IRB-HSR# 14299: The Use of the Intrathoracic Pressure Regulator (ITPR) to Improve Cerebral Perfusion Pressure in Patients With Altered Intracranial Elastance

IRB-HSR# 14299: The Use of the Intrathoracic Pressure Regulator (ITPR) to Improve Cerebral Perfusion Pressure in Patients With Altered Intracranial Elastance

IRB-HSR# 14299: The Use of the Intrathoracic Pressure Regulator (ITPR) to Improve Cerebral Perfusion Pressure in Patients With Altered Intracranial Elastance

Patients who have a functioning intracranial pressure-monitoring device (either a subarachnoid bolt, or an intraventricular catheter) in place, and are either sedated, intubated, and mechanically ventilated (i.e. in the NNICU), or are scheduled to undergo an operation or interventional neuroradiological procedure at the University of Virginia. Patients with a contraindication to TTE will be excluded. For patients in the NNICU, basic hemodynamic variables (systemic blood pressure, central venous pressure, etc.) will be collected. In addition, left ventricular performance (including estimates of LVEDV, LVESV, EF, FAC, and SV) will be assessed using TTE. Once these baseline data are recorded, the ITPR will be inserted in the ventilator circuit and activated to provide either -5 mm Hg or -9 mm Hg endotracheal rube pressure (ETP) (based on a randomization scheme). After the ITPR has been active for at least five minutes, the same intracranial, hemodynamic, and TTE data obtained above will be gathered. The ITPR will then be turned off for five minutes, and intracranial, hemodynamic, and TTE data will again be recorded. The ITPR will be activated a second time (-9 mm Hg or -5 mm Hg ETP, i.e. whichever value was not used previously), and after five minutes of use data will be recorded again. The ITPR will then be disconnected, data will be collected after waiting two minutes, and no further interventions will be made. ABG's will be obtained before and during the use of the device at each setting. This is a proof of concept/feasibility study designed to test the primary hypothesis that use of the ITPR will result in decreased intracranial pressure and increased cerebral perfusion pressure. The effect of the ITPR on secondary indicators of cardiac performance will also be examined. These include but are not limited estimates of ventricular end diastolic volume and pressure (LVEDV/P), ejection fraction (EF), left ventricular end systolic volume and pressure (LVESV/P), fractional area change (FAC), all of which will be assessed by transthoracic echocardiography (TTE) or transesophageal echocardiography (TEE).

The ITPR is an FDA-approved device intended to increase circulation and blood pressure in hypovolemic and cardiogenic shock. The device is inserted within a standard respiratory circuit between the patient and the ventilator. It functions by decreasing intrathoracic pressure during the expiratory phase to subatmospheric levels after each positive pressure ventilation. This decrease in intrathoracic pressure creates a vacuum within the thorax relative to the rest of the body, thereby enhancing venous return to the heart and consequently increasing cardiac output and blood pressure. Activation of the device is also accompanied by a decrease in SVR. The end result is a device that simultaneously improves cardiac output by increasing LVEDV and decreasing SVR while increasing coronary perfusion pressure by increasing blood pressure and decreasing LVESP/LVESV.1-8 Interestingly, while the ITPR was developed as a non-invasive mechanism to increase preload in hypovolemic patients, its mechanism of action (generation of subatmospheric intrathoracic pressure) has been shown to reduce intracranial pressure6. This is critical in brain-injured patients, because elevated intracranial pressure is strongly associated with poor outcome in traumatic brain injury (TBI) patients - in a recent study of 846 TBI patients, those with ICP < 20 mm Hg by 48 hours had a mortality rate of 14%, whereas those with ICP > 20 mm Hg had a mortality rate of 34%9. Particularly interesting are the ITPR's combined benefits of increased MAP and decreased ICP, as hypotension is a well-known poor prognostic indicator in this patient population. In fact, according to the Brain Trauma Foundation Guidelines, "Hypotension, occurring at any time from injury through the acute intensive care course, has been found to be a primary predictor of outcome from severe head injury for the health care delivery systems within which prognostic variables have been best studied. Hypotension is repeatedly found to be one of the five most powerful predictors of outcome and is generally the only one of these five that is amenable to therapeutic modification. A single recording of a hypotensive episode is generally associated with a doubling of mortality and a marked increase in morbidity from a given head injury10." Importantly, cerebral perfusion pressure (mean arterial pressure - the greater of ICP or CVP) is only a surrogate marker for cerebral blood flow. The function of hypotension as a useful clinical variable is dependent on two factors - first, its correlation with the true variable of interest (cerebral blood flow) and second, the ability of clinicians to manipulate the underlying variable of interest (cerebral blood flow) based on the surrogate marker (cerebral perfusion pressure). The acceptable level of hypotension in patients with brain injuries has not been determined, and the Brain Trauma Foundation (BTF) Guidelines recommend maintaining systolic blood pressures > 90 mm Hg, but acknowledge that this number is relatively arbitrary and not based on any high-level studies (thus assigning it a designation of Level II evidence) 11. The BTF Guidelines further state that because hypotension is such a poor prognostic variable, it would be unethical to randomize patients to various blood pressure goals, and therefore Level I evidence is not forthcoming. Further complicating the situation is the lack of agreement on how to increase blood pressure (with the hopes of increasing cerebral perfusion pressure)12-15. Many of the pharmacologic agents used to increase mean arterial pressure have significant vasoconstrictive effects, which could counteract any increase blood pressure and lead to unchanged, or even reduced cerebral blood flow.

the ITPR will be inserted in the ventilator circuit and activated to provide either -5 mm Hg or -9 mm Hg endotracheal tube pressure (ETP) Each subject will have all measurements recorded at both -5 & -9 mm Hg

the ITPR will be inserted in the ventilator circuit and activated to provide either -5 mm Hg or -9 mm Hg endotracheal tube pressure (ETP) Each subject will have all measurements recorded at both -5 & -9 mm Hg

the ITPR will be inserted in the ventilator circuit and activated to provide either -5 mm Hg or -9 mm Hg endotracheal tube pressure (ETP) Each subject will have all measurements recorded at both -5 & -9 mm Hg

the ITPR will be inserted in the ventilator circuit and activated to provide either -5 mm Hg or -9 mm Hg endotracheal tube pressure (ETP) Each subject will have all measurements recorded at both -5 & -9 mm Hg

hemodynamic variables (systemic blood pressure, central venous pressure, ICP) will be collected at baseline, 5 minutes after device activation & 5 minutes after device turned off

cardiac performance will also be examined. These include but are not limited estimates of ventricular end diastolic volume and pressure (LVEDV/P), ejection fraction (EF), left ventricular end systolic volume and pressure (LVESV/P), fractional area change (FAC)

Inclusion Criteria: 1. patients who have a functioning intracranial pressure-monitoring device (either a subarachnoid bolt, or an intraventricular catheter) in place, and are either sedated, intubated, and mechanically ventilated (i.e. in the NNICU)and have an arterial line in place, or are scheduled to undergo an operation or interventional neuroradiological procedure at the University of Virginia. 2. age 18 years of age and older 3. informed consent/ surrogate consent has been obtained Exclusion Criteria: 1. pneumothorax 2. hemothroax 3. uncontrolled bleeding 4. uncontrolled hypertension defined as SBP > 180 mmHg at the time of surgery 5. known respiratory disease such as chronic emphysema, COPD, or Cystic Fibrosis

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Yannopoulos D, McKnite S, Metzger A, Lurie KG. Intrathoracic pressure regulation improves 24-hour survival in a porcine model of hypovolemic shock. Anesth Analg. 2007 Jan;104(1):157-62. doi: 10.1213/01.ane.0000249047.80184.5a.

Yannopoulos D, McKnite SH, Metzger A, Lurie KG. Intrathoracic pressure regulation for intracranial pressure management in normovolemic and hypovolemic pigs. Crit Care Med. 2006 Dec;34(12 Suppl):S495-500. doi: 10.1097/01.CCM.0000246082.10422.7E.

Yannopoulos D, Metzger A, McKnite S, Nadkarni V, Aufderheide TP, Idris A, Dries D, Benditt DG, Lurie KG. Intrathoracic pressure regulation improves vital organ perfusion pressures in normovolemic and hypovolemic pigs. Resuscitation. 2006 Sep;70(3):445-53. doi: 10.1016/j.resuscitation.2006.02.005. Epub 2006 Aug 9.

Yannopoulos D, Nadkarni VM, McKnite SH, Rao A, Kruger K, Metzger A, Benditt DG, Lurie KG. Intrathoracic pressure regulator during continuous-chest-compression advanced cardiac resuscitation improves vital organ perfusion pressures in a porcine model of cardiac arrest. Circulation. 2005 Aug 9;112(6):803-11. doi: 10.1161/CIRCULATIONAHA.105.541508. Epub 2005 Aug 1.

Jiang JY, Gao GY, Li WP, Yu MK, Zhu C. Early indicators of prognosis in 846 cases of severe traumatic brain injury. J Neurotrauma. 2002 Jul;19(7):869-74. doi: 10.1089/08977150260190456.

The Brain Trauma Foundation. The American Association of Neurological Surgeons. The Joint Section on Neurotrauma and Critical Care. Hypotension. J Neurotrauma. 2000 Jun-Jul;17(6-7):591-5. doi: 10.1089/neu.2000.17.591.

Brain Trauma Foundation; American Association of Neurological Surgeons; Congress of Neurological Surgeons; Joint Section on Neurotrauma and Critical Care, AANS/CNS; Bratton SL, Chestnut RM, Ghajar J, McConnell Hammond FF, Harris OA, Hartl R, Manley GT, Nemecek A, Newell DW, Rosenthal G, Schouten J, Shutter L, Timmons SD, Ullman JS, Videtta W, Wilberger JE, Wright DW. Guidelines for the management of severe traumatic brain injury. I. Blood pressure and oxygenation. J Neurotrauma. 2007;24 Suppl 1:S7-13. doi: 10.1089/neu.2007.9995. No abstract available. Erratum In: J Neurotrauma. 2008 Mar;25(3):276-8. multiple author names added.

Pfister D, Strebel SP, Steiner LA. Effects of catecholamines on cerebral blood vessels in patients with traumatic brain injury. Eur J Anaesthesiol Suppl. 2008;42:98-103. doi: 10.1017/S0265021507003407.

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