Embolization of a cavernous carotid fistula through the vein of Labbé: a new alternative transvenous access route.

Endovascular treatment of carotid cavernous fistulas (CCFs) via a transvenous approach is standard, but in rare cases this approach is challenging due to absence or thrombosis of the commonly used venous routes. A 61-year-old woman presented with a symptomatic CCF with all but one of the venous access routes to the CCF thrombosed, leaving an engorged superficial middle cerebral vein (SMCV) as the only venous outflow from the cavernous sinus. Access to the CCF was made possible after careful navigation of the sigmoid sinus, the vein of Labbé and the SMCV, bypassing the need for surgical access to the SMCV or for a direct transorbital puncture. The CCF was completely occluded by coiling and Onyx embolization. The patient made an uneventful recovery, with resolution of her symptoms. To the best of our knowledge, this access route has not been previously reported in the treatment of CCFs.

Embolization of a cavernous carotid fistula through the vein of Labbé: a new alternative transvenous access route.

Endovascular treatment of carotid cavernous fistulas (CCFs) via a transvenous approach is standard, but in rare cases this approach is challenging due to absence or thrombosis of the commonly used venous routes. A 61-year-old woman presented with a symptomatic CCF with all but one of the venous access routes to the CCF thrombosed, leaving an engorged superficial middle cerebral vein (SMCV) as the only venous outflow from the cavernous sinus. Access to the CCF was made possible after careful navigation of the sigmoid sinus, the vein of Labbé and the SMCV, bypassing the need for surgical access to the SMCV or for a direct transorbital puncture. The CCF was completely occluded by coiling and Onyx embolization. The patient made an uneventful recovery, with resolution of her symptoms. To the best of our knowledge, this access route has not been previously reported in the treatment of CCFs.

Mechanical Thrombectomy in Wake-Up Strokes: A Case Series Using Alberta Stroke Program Early CT Score (ASPECTS) for Patient Selection.

BACKGROUND: There is lack of published studies on mechanical thrombectomy with stent retrievers for wake-up stroke (WUS). OBJECTIVE: To report the outcomes of WUS patients with large vessel occlusions, selected for intervention based on Alberta Stroke Program Early CT Score (ASPECTS) and treated with stent retrievers or primary aspiration thrombectomy. METHODS: Data were collected retrospectively for each consecutive WUS patient undergoing mechanical thrombectomy with a stent retriever or primary aspiration catheter between February 2015 and September 2016. ASPECTS ≥ 6 was used as the primary imaging criterion for offering thrombectomy in these WUS patients. Main outcomes were the in-hospital improvement in the National Institutes of Health Stroke Scale (NIHSS) and the occurrence of symptomatic hemorrhage. RESULTS: Twelve patients were included in this study; 11 were treated with stent retrievers and 1 was treated with primary aspiration thrombectomy alone. Successful recanalization was achieved in 100% of the patients (33% thrombolysis in cerebral infarction [TICI] 2B and 67% TICI 3). Every patient experienced a reduction in the NIHSS during hospitalization, with a mean NIHSS decrease of 11.1 ± 5.1 points. There was a trend for a larger reduction in the NIHSS in patients with TICI 3 compared to TICI 2B recanalization. There was no symptomatic intracranial hemorrhage in our cohort. CONCLUSIONS: For patients with WUS, careful selection of patients using ASPECTS may allow for safe interventions, with low risk of clinical deterioration, and no-periprocedural mortality. All our patients demonstrated a reduction in their NIHSS after the thrombectomy and clinical improvement.

Natural history, current concepts, classification, factors impacting endovascular therapy, and pathophysiology of cerebral and spinal dural arteriovenous fistulas.

Dural arteriovenous fistulas (DAVFs) may occur anywhere there is a dural or meningeal covering around the brain or spinal cord. Clinical manifestations are mostly related to venous hypertension, and may be protean, acute or chronic, ranging from minor to severe, from non-disabling tinnitus to focal neurological deficits, seizures, hydrocephalus, psychiatric disturbances, and developmental delay in pediatric patients. Although low-grade lesions may have a benign course and spontaneous involution may occasionally occur (i.e. cavernous sinus DAVFs), the risk of hemorrhage is considerable in high grade lesions. Angiographic features of DAVFs have been clarified since the 1970s when venous drainage pattern was clearly identified as the most significant risk predictor and as a major determinant of success or failure of treatment. The mainstay of therapy is interruption of arteriovenous shunting, which has traditionally been accomplished surgically. Currently, endovascular therapy is generally considered the first line of treatment, allowing elimination of the lesion in most patients, with surgery and stereotactic radiosurgery reserved for complex situations. This review discusses major aspects of DAVFs, including grading systems, clinical presentation, diagnostic evaluation, various issues impacting endovascular therapy, and pathophysiology.

Brain temperature changes during selective cooling with endovascular intracarotid cold saline infusion: simulation using human data fitted with an integrated mathematical model.

The feasibility of rapid cerebral hypothermia induction in humans with intracarotid cold saline infusion (ICSI) was investigated using a hybrid approach of jugular venous bulb temperature (JVBT) sampling and mathematical modeling of transient and steady state brain temperature distribution. This study utilized both forward mathematical modeling, in which brain temperatures were predicted based on input saline temperatures, and inverse modeling, where brain temperatures were inferred based on JVBT. Changes in ipsilateral anterior circulation territory temperature (IACT) were estimated in eight patients as a result of 10 min of a cold saline infusion of 33 ml/min. During ICSI, the measured JVBT dropped by 0.76±0.18°C while the modeled JVBT decreased by 0.86±0.18°C. The modeled IACT decreased by 2.1±0.23°C. In the inverse model, IACT decreased by 1.9±0.23°C. The results of this study suggest that mild cerebral hypothermia can be induced rapidly and safely with ICSI in the neuroangiographical setting. The JVBT corrected mathematical model can be used as a non-invasive estimate of transient and steady state cerebral temperature changes.

Brain cooling maintenance with cooling cap following induction with intracarotid cold saline infusion: a quantitative model.

Intracarotid cold saline infusion (ICSI) is potentially much faster than whole-body cooling and more effective than cooling caps in inducing therapeutic brain cooling. One drawback of ICSI is hemodilution and volume loading. We hypothesized that cooling caps could enhance brain cooling with ICSI and minimize hemodilution and volume loading. Six-hour-long simulations were performed in a 3D mathematical brain model. The Pennes bioheat equation was used to propagate brain temperature. Convective heat transfer through jugular venous return and the circle of Willis was simulated. Hemodilution and volume loading were modeled using a two-compartment saline infusion model. A feedback method of local brain temperature control was developed where ICSI flow rate was varied based on the rate of temperature change and the deviation of temperature to a target (32 degrees C) within a voxel in the treated region of brain. The simulations confirmed the inability of cooling caps alone to induce hypothermia. In the ICSI and the combination models (ICSI and cap), the control algorithm guided ICSI to quickly achieve and maintain the target temperature. The combination model had lower ICSI flow rates than the ICSI model resulting in a 55% reduction of infusion volume over a 6h period and higher hematocrit values compared to the ICSI model. Moreover, in the combination model, the ICSI flow rate decreased to zero after 4h, and hypothermia was subsequently maintained solely by the cooling cap. This is the first study supporting a role of cooling caps in therapeutic hypothermia in adults.

Local control of temperature in a theoretical human model of selective brain cooling.

A method of feedback control of local brain temperature during therapeutic intracarotid cold saline infusion is presented and tested on a theoretical cerebral heat transfer model based on the Pennes bioheat equation. In this temperature control method, the infusion rate of cold saline is varied based on the rate of temperature change, and the deviation of temperature to a target, within a voxel in the treated region of brain. This control method is tested in cases where the head is exposed to ambient room temperature, and where the head is packed in ice. In both the ice and non-ice cases, target temperature (33 degrees C) is achieved in the voxel according to the desired time constant (2 minutes). Two hours of treatment decreased the required inflow of ice-cold saline from 30 ml/min to 21 and 7 ml/min in the non-ice and ice cases, respectively. Intracarotid hematocrit had higher values in the non-ice case.

The role of intracarotid cold saline infusion on a theoretical brain model incorporating the circle of willis and cerebral venous return.

This study describes a theoretical model of brain cooling by intracarotid cold saline infusion which takes into account redistribution of cold perfusate through the circle of Willis (CoW) and cold venous return (VR) from the head. This model is developed in spherical coordinates on a four tissue layer hemispherical geometrical configuration. Temperature evolution is modeled according to the Pennes bioheat transfer equation. Simulations were run over a 1 hour period and 30 ml/min of freezing cold saline with the baseline model (no VR, no CoW), VR model (without CoW), and CoW model (with VR). The VR model demonstrates continuing temperature drop in the treatment region of the brain not observed in the baseline model and its final mean ipsilateral anterior temperature was approximately 31 degrees C. The temperature effect in the CoW model was present but less robust in the ipsilateral anterior region, as final temperature was 32 degrees C. However, cooling was also achieved in contralateral and posterior brain regions. This model continues to demonstrate the feasibility of intracarotid cold saline infusion for ischemic stroke therapy.

Integration of jugular venous return and circle of Willis in a theoretical human model of selective brain cooling.

A three-dimensional mathematical model was developed to examine the induction of selective brain cooling (SBC) in the human brain by intracarotid cold (2.8 degrees C) saline infusion (ICSI) at 30 ml/min. The Pennes bioheat equation was used to propagate brain temperature. The effect of cooled jugular venous return was investigated, along with the effect of the circle of Willis (CoW) on the intracerebral temperature distribution. The complete CoW, missing A1 variant (mA1), and fetal P1 variant (fP1) were simulated. ICSI induced moderate hypothermia (defined as 32-34 degrees C) in the internal carotid artery (ICA) territory within 5 min. Incorporation of the complete CoW resulted in a similar level of hypothermia in the ICA territory. In addition, the anterior communicating artery and ipsilateral posterior communicating artery distributed cool blood to the contralateral anterior and ipsilateral posterior territories, respectively, imparting mild hypothermia (35 and 35.5 degrees C respectively). The mA1 and fP1 variants allowed for sufficient cooling of the middle cerebral territory (30-32 degrees C). The simulations suggest that ICSI is feasible and may be the fastest method of inducing hypothermia. Moreover, the effect of convective heat transfer via the complete CoW and its variants underlies the important role of CoW anatomy in intracerebral temperature distributions during SBC.

Reperfusion injury following cerebral ischemia: pathophysiology, MR imaging, and potential therapies.

INTRODUCTION: Restoration of blood flow following ischemic stroke can be achieved by means of thrombolysis or mechanical recanalization. However, for some patients, reperfusion may exacerbate the injury initially caused by ischemia, producing a so-called "cerebral reperfusion injury". Multiple pathological processes are involved in this injury, including leukocyte infiltration, platelet and complement activation, postischemic hyperperfusion, and breakdown of the blood-brain barrier. METHODS/RESULTS AND CONCLUSIONS: Magnetic resonance imaging (MRI) can provide extensive information on this process of injury, and may have a role in the future in stratifying patients' risk for reperfusion injury following recanalization. Moreover, different MRI modalities can be used to investigate the various mechanisms of reperfusion injury. Antileukocyte antibodies, brain cooling and conditioned blood reperfusion are potential therapeutic strategies for lessening or eliminating reperfusion injury, and interventionalists may play a role in the future in using some of these therapies in combination with thrombolysis or embolectomy. The present review summarizes the mechanisms of reperfusion injury and focuses on the way each of those mechanisms can be evaluated by different MRI modalities. The potential therapeutic strategies are also discussed.

A theoretical model of selective cooling using intracarotid cold saline infusion in the human brain.

A three-dimensional mathematical model was developed to examine the transient and steady-state temperature distribution in the human brain during selective brain cooling (SBC) by unilateral intracarotid freezing-cold saline infusion. To determine the combined effect of hemodilution and hypothermia from the cold saline infusion, data from studies investigating the effect of these two parameters on cerebral blood flow (CBF) were pooled, and an analytic expression describing the combined effect of the two factors was derived. The Pennes bioheat equation used the thermal properties of the different cranial layers and the effect of cold saline infusion on CBF to propagate the evolution of brain temperature. A healthy brain and a brain with stroke (ischemic core and penumbra) were modeled. CBF and metabolic rate data were reduced to simulate the core and penumbra. Simulations using different saline flow rates were performed. The results suggested that a flow rate of 30 ml/min is sufficient to induce moderate hypothermia within 10 min in the ipsilateral hemisphere. The brain with stroke cooled to lower temperatures than the healthy brain, mainly because the stroke limited the total intracarotid blood flow. Gray matter cooled twice as fast as white matter. The continuously falling hematocrit was the main time-limiting factor, restricting the SBC to a maximum of 3 h. The study demonstrated that SBC by intracarotid saline infusion is feasible in humans and may be the fastest method of hypothermia induction.

Neuroprotection for ischemic stroke using hypothermia.

The development of animal models of acute stroke has allowed the evaluation of mild and moderate hypothermia as a therapeutic modality in this clinical setting. Studies have demonstrated that animals subjected to hypothermia up to 3 hours after the primary central nervous system insult have reduced mortality and neuronal injury, and improved neurological outcome. These results warranted the evaluation of hypothermia in clinical trials. Even though hypothermia has potent neuroprotective effects in animal models of ischemic stroke, there are only a few clinical studies of therapeutic hypothermia in humans. Because of the small number of patients in the studies and the absence of matched controls, clinical studies are considered pilot studies for feasibility and safety. Thus, therapeutic hypothermia for ischemic stroke remains a promising but fiercely debated therapeutic modality. This review summarizes the animal model studies that have led to clinical trials in acute ischemic stroke. The existing techniques for inducing brain cooling, the mechanisms of neuroprotection, the complications of therapeutic hypothermia, and the future perspective of the field are also discussed.

Heat transfer model of hyporthermic intracarotid infusion of cold saline for stroke therapy.

A 3-dimensional hemispheric computational brain model is developed to simulate infusion of cold saline in the carotid arteries in terms of brain cooling for stroke therapy. The model is based on the Pennes bioheat equation, with four tissue layers: white matter, gray matter, skull, and scalp. The stroke lesion is simulated by reducing blood flow to a selected volume of the brain by a factor of one-third, and brain metabolism by 50%. A stroke penumbra was also generated surrounding the core lesion (blood volume reduction 25%, metabolism reduction 20%). The finite difference method was employed to solve the system of partial differential equations. This model demonstrated a reduction in brain temperature, at the stroke lesion, to 32 degrees C in less than 10 minutes.

Extracellular Na+ removal attenuates rundown of the epithelial Na+-channel (ENaC) by reducing the rate of channel retrieval.

Regulation of the epithelial sodium channel (ENaC) is important for the long-term control of arterial blood pressure as evidenced by gain of function mutations of ENaC causing Liddle's syndrome, a rare form of hereditary arterial hypertension. In Xenopus laevis oocytes expressing ENaC a spontaneous decline of ENaC currents over time, so-called rundown, is commonly observed. Mechanisms involved in rundown may be physiologically relevant and may be related to feedback regulation of ENaC by intra- or extracellular Na+. We tested the effect of extracellular Na+ removal on ENaC rundown. Spontaneous rundown of ENaC was largely prevented by extracellular Na+ removal and was partially prevented by primaquine suggesting that it is due to endocytic channel retrieval. Liddle's syndrome mutation caused a reduced rate of rundown, and in oocytes expressing the mutated channel extracellular Na+ removal not only prevented rundown but even increased the ENaC currents (runup). Acute exposure to high extracellular Na+ drastically reduced whole-cell currents and surface expression of wild-type ENaC, while these effects were much smaller in ENaC with Liddle's syndrome mutation consistent with a stabilization of the mutated channel in the plasma membrane. Interestingly, the apparent intracellular Na+ concentration [Na+](i-app) was high (>60 mM) in ENaC-expressing oocytes but rundown was not associated with a further increase in [Na+](i-app). We conclude that the inhibitory effect of extracellular Na+ removal on rundown is due to an inhibition of endocytic ENaC retrieval.

The gamma-subunit of ENaC is more important for channel surface expression than the beta-subunit.

The amiloride-sensitive epithelial sodium channel (ENaC) plays a critical role in fluid and electrolyte homeostasis and is composed of three homologous subunits: alpha, beta, and gamma. Only heteromultimeric channels made of alphabetagammaENaC are efficiently expressed at the cell surface, resulting in maximally amiloride-sensitive currents. To study the relative importance of various regions of the beta- and gamma-subunits for the expression of functional ENaC channels at the cell surface, we constructed hemagglutinin (HA)-tagged beta-gamma-chimeric subunits composed of beta- and gamma-subunit regions and coexpressed them with HA-tagged alphabeta- and alphagamma-subunits in Xenopus laevis oocytes. The whole cell amiloride-sensitive sodium current (DeltaI(ami)) and surface expression of channels were assessed in parallel using the two-electrode voltage-clamp technique and a chemiluminescence assay. Because coexpression of alphagammaENaC resulted in larger DeltaI(ami) and surface expression compared with coexpression of alphabetaENaC, we hypothesized that the gamma-subunit is more important for ENaC trafficking than the beta-subunit. Using chimeras, we demonstrated that channel activity is largely preserved when the highly conserved second cysteine rich domains (CRD2) of the beta- and gamma-subunits are exchanged. In contrast, exchanging the whole extracellular loops of the beta- and the gamma-subunits largely reduced ENaC currents and ENaC expression in the membrane. This indicates that there is limited interchangeability between molecular regions of the two subunits. Interestingly, our chimera studies demonstrated that the intracellular termini and the two transmembrane domains of gammaENaC are more important for the expression of functional channels at the cell surface than the corresponding regions of betaENaC.

cAMP-dependent activation of CFTR inhibits the epithelial sodium channel (ENaC) without affecting its surface expression.

The cystic fibrosis transmembrane conductance regulator (CFTR) is thought to modulate epithelial sodium channel (ENaC) function in various preparations. However, the molecular nature and (patho-)physiological significance of the CFTR/ENaC interaction is still unclear and may vary in different tissues. Co-expression experiments in Xenopus laevis oocytes are a popular approach to investigate a possible functional interaction of CFTR and ENaC but have revealed controversial results. We could confirm previous reports that in oocytes co-expressing ENaC and CFTR the amiloride-sensitive current was reduced during cAMP-mediated stimulation of CFTR. In contrast, co-expression of CFTR per se had no effect on baseline ENaC currents. ENaC with Liddle's syndrome mutation is also inhibited during activation of CFTR, suggesting that the C-terminus of the ENaC beta-subunit is not important for this functional interrelation. Single-channel patch-clamp recordings demonstrated that co-expression of CFTR does not alter the single-channel conductance of ENaC. Using a chemiluminescence assay we demonstrated that the inhibition of ENaC during cAMP-dependent activation of CFTR was not associated with a decrease in ENaC surface expression. We conclude that the inhibitory effect of cAMP-activated CFTR on ENaC is due to a decrease in channel open probability.

Identification of domains that control the heteromeric assembly of Kir5.1/Kir4.0 potassium channels.

Heteromultimerization between different inwardly rectifying (Kir) potassium channel subunits is an important mechanism for the generation of functional diversity. However, little is known about the mechanisms that control this process and that prevent promiscuous interactions in cells that express many different Kir subunits. In this study, we have examined the heteromeric assembly of Kir5.1 with other Kir subunits and have shown that this subunit exhibits a highly selective interaction with members of the Kir4.0 subfamily and does not physically associate with other Kir subunits such as Kir1.1, Kir2.1, and Kir6.2. Furthermore, we have identified regions within the Kir4.1 subunit that appear to govern the specificity of this interaction. These results help us to understand the mechanisms that control Kir subunit recognition and assembly and how cells can express many different Kir channels while maintaining distinct subpopulations of homo- and heteromeric channels within the cell.

Regulation of the epithelial sodium channel by N4WBP5A, a novel Nedd4/Nedd4-2-interacting protein.

The amiloride-sensitive epithelial sodium channel (ENaC) plays a critical role in fluid and electrolyte homeostasis and consists of alpha, beta, and gamma subunits. The carboxyl terminus of each ENaC subunit contains a PPXY motif that is believed to be important for interaction with the WW domains of the ubiquitin-protein ligases, Nedd4 and Nedd4-2. Disruption of this interaction, as in Liddle's syndrome where mutations delete or alter the PPXY motif of either the beta or gamma subunits, has been shown to result in increased ENaC activity and arterial hypertension. Here we present evidence that N4WBP5A, a novel Nedd4/Nedd4-2-binding protein, is a potential regulator of ENaC. In Xenopus laevis oocytes N4WBP5A increases surface expression of ENaC by reducing the rate of ENaC retrieval. We further demonstrate that N4WBP5A prevents sodium feedback inhibition of ENaC possibly by interfering with the xNedd4-2-mediated regulation of ENaC. As N4WBP5A binds Nedd4/Nedd4-2 via PPXY motif/WW domain interactions and appears to be associated with specific intracellular vesicles, we propose that N4WBP5A functions by regulating Nedd4/Nedd4-2 availability and trafficking. Because N4WBP5A is highly expressed in native renal collecting duct and other tissues that express ENaC, it is a likely candidate to modulate ENaC function in vivo.

Cystic fibrosis transmembrane conductance regulator-dependent up-regulation of Kir1.1 (ROMK) renal K+ channels by the epithelial sodium channel.

The epithelial sodium channel (ENaC) and the secretory potassium channel (Kir1.1/ROMK) are expressed in the apical membrane of renal collecting duct principal cells where they provide the rate-limiting steps for Na(+) absorption and K(+) secretion. The cystic fibrosis transmembrane conductance regulator (CFTR) is thought to regulate the function of both ENaC and Kir1.1. We hypothesized that CFTR may provide a regulatory link between ENaC and Kir1.1. In Xenopus laevis oocytes co-expressing both ENaC and CFTR, the CFTR currents were 3-fold larger than those in oocytes expressing CFTR alone due to an increased expression of CFTR in the plasma membrane. ENaC was also able to increase Kir1.1 currents through an increase in surface expression, but only in the presence of CFTR. In the absence of CFTR, co-expression of ENaC was without effect on Kir1.1. ENaC-mediated CFTR-dependent up-regulation of Kir1.1 was reduced with a Liddle's syndrome mutant of ENaC. Furthermore, ENaC co-expressed with CFTR was without effect on the closely related K(+) channel, Kir4.1. We conclude that ENaC up-regulates Kir1.1 in a CFTR-dependent manner. CFTR may therefore provide the mechanistic link that mediates the coordinated up-regulation of Kir1.1 during the stimulation of ENaC by hormones such as aldosterone or antidiuretic hormone.

Intrinsic sensitivity of Kir1.1 (ROMK) to glibenclamide in the absence of SUR2B. Implications for the identity of the renal ATP-regulated secretory K+ channel.

The precise molecular identity of the renal ATP-regulated secretory K+ channel is still a matter of some controversy. The inwardly rectifying K+ channel, Kir1.1 (ROMK) appears to form the pore of the channel, and mutations in Kir1.1 are responsible for Bartter syndrome. The native channel is sensitive to inhibition by the sulfonylurea glibenclamide, and it has been proposed that an accessory protein is required to confer glibenclamide sensitivity to Kir1.1. Several recent studies have suggested that the native channel is composed of the splice variant Kir1.1b (ROMK2) and the sulfonylurea receptor isoform SUR2B and that there is a direct physical interaction between these subunits. In this study, we have monitored the interaction between Kir1.1b and SUR2B. We find that SUR2B reaches the plasma membrane when coexpressed with Kir6.1 or Kir6.2 but not when coexpressed with Kir1.1b. Furthermore, we find that Kir1.1b exhibits an intrinsic sensitivity to inhibition by glibenclamide with an affinity similar to the native channel. These results demonstrate that SUR2B does not traffic to the membrane in the presence of Kir1.1b and is not required to confer glibenclamide sensitivity to Kir1.1b. This has important implications for the presumed structure of the renal ATP-regulated secretory K+ channel.