Our studies have revealed that the beneficial effects of conivaptan are dependent on the method of delivery after experimental stroke in mice. We have developed a research protocol for delivery of the receptor blocker via IV catheter on stroke-evoked brain edema formation in mice.
Stroke is one of the major causes of morbidity and mortality in the world. Stroke is complicated by brain edema and other pathophysiological events. Among the most important players in the development and evolution of stroke-evoked brain edema is the hormone arginine-vasopressin and its receptors, V1a and V2. Recently, the V1a and V2 receptor blocker conivaptan has been attracting attention as a potential drug to reduce brain edema after stroke. However, animal models which involve conivaptan applications in stroke research need to be modified based on feasible routes of administration. Here the outcomes of 48 hr continuous intravenous (IV) are compared with intraperitoneal (IP) conivaptan treatments after experimental stroke in mice. We developed a protocol in which middle cerebral artery occlusion was combined with catheter installation into the jugular vein for IV treatment of conivaptan (0.2 mg) or vehicle. Different cohorts of animals were treated with 0.2 mg bolus of conivaptan or vehicle IP daily. Experimental stroke-evoked brain edema was evaluated in mice after continuous IV and IP treatments. Comparison of the results revealed that the continuous IV administration of conivaptan alleviates post-ischemic brain edema in mice, unlike the IP administration of conivaptan. We conclude that our model can be used for future studies of conivaptan applications in the context of stroke and brain edema.
Stroke continues to be an enormous burden for patients and clinicians. Animal stroke models have been used in the laboratory setting for nearly two decades.1 Nevertheless, experimental treatments that work in animals often fail in humans.2 This discrepancy in treatment outcomes may be due to various factors, such as administration routes for drugs used in animal research, drug metabolism and elimination rate, and many other aspects. One of the major complications of stroke, brain edema, is a focus of current research in neuroscience. Mechanisms of brain edema formation involve disturbances in water and electrolyte balance triggered by the arginine-vasopressin (AVP) response to ischemic brain injury.3 Therefore, AVP and its receptors (V1a and V2) are a major focus of research studies of post-ischemic brain edema formation.3
We have developed a methodology to study the effects of mixed arginine-vasopressin (V1a and V2) receptor blocker conivaptan on post-ischemic brain edema in mice.4 Molecular targets of conivaptan5 make the drug a suitable candidate for exploration of its properties in alleviation of brain edema. Furthermore, conivaptan needs to be studied in the context of pathophysiological events of stroke.6 In designing this study, we considered comparing treatment outcomes using two different routes of administration for conivaptan: intravenous (IV)4 and intraperitoneal (IP).7 Effects of the treatments on stroke-induced brain edema were evaluated. Here detailed protocols are described for surgical induction of experimental stroke by middle cerebral artery occlusion (MCAO), and followed by continuous conivaptan treatment using the installation of a jugular IV catheter. After induction of stroke, animals were randomly allocated into the following groups: vehicle or conivaptan (0.2 mg/day) treated IV or IP.
Experiments were carried out in accordance with the guidelines of the National Institutes of Health for the care and use of animals in research and were approved by the Swedish Medical Center Animal Care and Use Committee. All procedures were performed with appropriate aseptic techniques. Experimental animals utilized for the study were male, 3 months old, wild type C57 mice with body weight from 25 to 27 g.
1. In Vivo Stroke Induction
2. Installation of IV Catheter into the Jugular Vein for Continuous 48 hr Treatment
Note: Proceed to installation of the catheter immediately after the step 1.16.3 without awakening of the mouse.
3. Evaluation of Stroke-evoked Brain Edema at the end Point
Body temperature of the animals was within the physiological range and stable throughout the surgical procedure of stroke induction. Two mice that exhibited NDS lower than 2 immediately after MCAO were excluded from the study.
MCAO in mice produces infarct volume in the ipsilateral hemisphere at 48 hr. Evaluation of the TTC-stained slices shows that about 50% of the hemisphere is affected by infarct after MCAO (Figure 1D), as published by Zeynalov, E. and Dore, S., 2009.10 The onset of brain ischemic stroke causes severe deprivation of brain tissue in oxygen and nutrients. As a result of this local brain tissue hypoxia, neurons and glial cells die, which form the infarcted part of the brain. Figure 1D shows representative mouse brain slices affected by MCAO-induced infarct, and gives an estimation of the size of an injury.10
Evaluation of brain water content (BWC) at 48 hr after 60 min MCAO induction revealed that conivaptan administered IV (0.2 mg/day) significantly reduces brain edema in both ipsilateral and contralateral hemispheres, (Figure 2A). In contrast, IP-treatment of conivaptan by 0.2 mg bolus daily failed to produce similar positive effects on stroke-evoked brain edema (Figure 2B).
Confirmation of conivaptan effect on plasma and urine osmolality was achieved in all experimental animals at the end point of the experiment. Conivaptan treated IV or IP increased plasma and decreased urine osmolality in all mice.4 Plasma osmolality values in mice were as follows: 313 ± 4.4 mOsm/kg (vehicle, IV) vs. 355 ± 7.5* mOsm/kg (conivaptan, IV),as previously published,4 and 340 ± 7.7 mOsm/kg (vehicle, IP) vs. 383 ± 8.8* mOsm/kg (conivaptan, IP). Urine osmolality values in mice were as follows: 1210.6 ± 13.4 mOsm/kg (vehicle, IV) vs. 595.0 ± 57.4* mOsm/kg (conivaptan, IV), as previously published,4 and 1535.0 ± 80.9 mOsm/kg (vehicle, IP) vs. 242.0 ± 23.2* mOsm/kg (conivaptan, IP). All data presented as mean ± SEM, *p ≤0.05 vs. corresponding control.
Figure 1: Diagram of the experimental stroke model, IV catheter installation, and representative infarct volume at 48 hr after stroke. Position of the filament (shown in blue) pre-coated with resin (green) in the left internal carotid artery (ICA) during the occlusion (A) and the reperfusion time (B). Correct position of the flexible tubing tip in the left jugular vein (C). Experimental stroke in mice produces infarct volume in the ipsilateral hemisphere at 48 hr. Mice were sacrificed at 48 hr after MCAO, and brains were removed, as described in the protocol (steps 3.1-3.3). Brains were cut in 2 mm thick sections, and stained with TTC (D). Figure 1D has been modified from the original article by Zeynalov, E. and Dore, S., 2009.10 Please click here to view a larger version of this figure.
Figure 2: Effects of continuous intravenous (IV) and intraperitoneal (IP) conivaptan (0.2 mg/day) treatments on stroke-evoked brain edema. Conivaptan IV treatment was administered for 48 hr. Conivaptan treatment administered IV reduced post-ischemic brain edema in the ipsilateral and contralateral hemisphere (A). Figure 2A has been modified from the original article by Zeynalov et al., 2015.4 Conivaptan IP treatment for 48 hr failed to reduce brain edema caused by experimental stroke, n = 10 in each group. Mice underwent MCAO with reperfusion as described in the protocol above (steps 1.1.1-1.15.3). Then IP injections of conivaptan (0.2 mg) were administered immediately, at 22 hr and 46 hr of reperfusion. Mice were sacrificed; the brains were removed and dried in the oven, as described in the protocol (steps 3.1-3.4). (B) All data is presented as mean ± SEM, *p <0.05 vs corresponding control. Please click here to view a larger version of this figure.
This study has important value for preclinical stroke research. This study reveals that continuous IV infusion of conivaptan (0.2 mg/day) after experimental stroke in mice efficiently reduces brain edema after 48 hr of treatment. The effect of IP injection of the same dose of conivaptan on brain edema was also investigated. Conivaptan treatment by both IV and IP routes produces aquaresis in mice as indicated by: 1) increase in plasma osmolality slightly above physiological levels; and 2) decrease in urine osmolality due to blockage of water reabsorption in the kidney. Therefore, based on the treatment outcomes, we report that the IV delivery method has additional important beneficial effects on stroke-evoked edema formation.
Our major finding is that IV treatment produced better effect on brain edema alleviation than the IP route for conivaptan. Conivaptan is a combined V1a and V2 receptor antagonist, available for clinical use to correct hyponatremia, blood volume and osmolality.16 Conivaptan has been shown to correct hyponatremia in patients with various conditions.17 Clinical availability of conivaptan suggests that its exploration in the context of brain edema can result in fast bench-to-bedside translation. Use of experimental selective V1a receptor blockers delivered intracerebroventricularly has been proven to reduce post-ischemic brain edema formation described by other researchers.3,18 However, neither the drug used in those studies nor the treatment route for the drugs suggests possible clinical application in the near future.
Mechanisms by which brain ischemia and AVP cause brain edema are complex. However, some important molecular players are sodium and chloride co-transporters19,20 and V1a receptors which are localized in vascular walls at the BBB interface. The V2 blocking effect of conivaptan is responsible for excretion of excess water by the kidney and elevation of blood osmolality, which may also help prevent development of brain edema.21 These mechanisms may still be in play when conivaptan is delivered directly into the circulation to avoid tissue barriers that may reduce conivaptan availability. However, justification of the dose and the treatment duration was based on previously published observations.4 It remains to be determined whether conivaptan reaches the ischemic site of the brain after injury-induced decreases of regional blood flow. It also needs to be investigated whether the brain receives sufficient amount of conivaptan to produce the desirable local effects, such as prevention of vasoconstriction by blocking V1a receptors in cerebral arteries.
The experimental protocol was designed to address the question of choice for the treatment route of conivaptan. Based on the results, the study provides strong support for the IV route of conivaptan administration. However, most critical steps of protocol needed to be established and fine-tuned in order to detect significant differences in treatment outcomes after stroke in mice. Among those steps are: 1) the duration of the MCAO (60 min); 2) the daily dose (0.2 mg), and the infusion rate (1.5 ml/kg/hr); and 3) the length of the treatment (48 hr). Duration of MCAO determines the degree of the ischemic insult which is extremely crucial for the protocol because it irreversibly damages the brain tissue. Too severe of an injury would make it difficult for the animal to survive for 48 hr, or the animals could become less responsive to conivaptan treatment against brain edema. On the other hand, duration of MCAO less than 60 min may be insufficient to induce an ischemic insult in the mouse, and, therefore, would not produce brain edema. The dose and the length of the treatment were chosen based on the FDA recommendations for conivaptan use.16 However, it has been reported that the human dose for conivaptan was not efficient in mice to reduce brain edema after stroke. Therefore, the dose had to be increased 10 times for mice, which induced significant protection against post-ischemic brain edema.4 The importance of choosing the correct infusion rate is that it can affect the total blood volume, blood pressure and interstitial fluid accumulation if the rate greatly exceeds the suggested rate. However, measurements of total blood volume and blood pressure would be very informative.
Surgical induction of the MCAO is an invasive procedure, and requires precise attention to all the steps of the protocol, and it is important to know the troubleshooting tips for the technique. Some unexpected surgical complications, such as excessive arterial bleeding due to an accidentally torn artery reduce the success rate for the experiment and increase the mortality rate. However, venous bleeding can be stopped by applying light pressure with a sterile sponge.
This protocol describes a unilateral induction of brain ischemia, which implies that the MCA occlusion is produced either on the right or the left MCA. However, the protocol can be modified depending on the surgeon's preferred side of MCA occlusion and the IV catheter installation. Figure 1 diagram depicts a drawing of the most critical parts of the MCAO procedure, Figure 1A and B, the IV catheter installation protocol, Figure 1C, and the representative brain slices of MCAO-induced brain infarct at the end-point of the experiment (48 hr), as previously published,10 Figure 1D. Although the diagram and the representative brain slices imply that the MCAO was induced on the left side of the brain, we don't anticipate dramatic differences in results if MCAO was induced on the right side of the brain as long as consistency throughout the entire study is maintained.
During the recovery period after the surgery and anesthesia, the animals may experience distress due to post-operative pain and severe neurological deficits. In many cases, the postoperative pain management may be limited to using only local anesthetics such as 0.5% bupivacaine. Stroke due to cerebrovascular accident in humans as well as experimental stroke in mice involves pathophysiological factors such as inflammation, brain infarct, and brain edema.9 These pathophysiological events are engaged by key molecular players such as cyclooxygenases (COX)13 and G-protein related receptors.22 Interference with the molecular pathways that involve COX may be caused by the NSAID drugs,13 if they were used in these settings. Opioids act on their receptors which are linked to G-protein and second messengers12 and can alter pathophysiological outcomes of stroke,11 and the results of this study. These factors limit usage of pain medication in mice postoperatively.
In summary, our study explores the possibility of repurposing conivaptan as a far reaching goal. Our animal model of experimental stroke induction followed by continuous IV infusion of conivaptan has been shown to produce consistent results which suggest its potential use in stroke patients. More specifically, we have demonstrated that the model of continuous IV treatment of conivaptan after stroke to prevent secondary brain injury can be used for preclinical study in mice. This study was intended to offer an alternative application of conivaptan treatment as an additional tool to study brain edema in mice after stroke because fast translation into clinical settings may be lifesaving for ICU patients.
The authors have nothing to disclose.
We thank Swedish Medical Center for providing the funding and facilities. We also thank Craig Hospital for the generous use of laboratory space.
Heated Pad | K&H Manufacturing Inc | 1060 | |
Temperature Monitor with Rectal Probe | Physitemp | 7029 | |
Silk Suture Spool, 6-0 | Surgical Specialties Corporation | SP114 | |
Silk Suture on a Needle, 3-0 | Ethicon | 1684G | |
Nylon Suture, 7-0 | Ethicon | 1696G | |
Dental Resin Polysiloxane with Hardener | Heraeus Kulzer | 65817930 | |
Microinfusion IV Pump | Kent Scietific | GT0897 | |
Swivel 22GA | Instech | 375/22PS | |
Laboratory Tubing, 0.94 x 0.51 mm | Dow Corning | 508-002 | |
Laboratory Tubing, 3.18 x 1.98 mm | Dow Corning | 508-009 |