Novel heat shock protein 90 inhibitor improves cardiac recovery in a rodent model of donation after circulatory death.

OBJECTIVE: Organ donation after circulatory death (DCD) is a potential solution for the shortage of suitable organs for transplant. Heart transplantation using DCD donors is not frequently performed due to the potential myocardial damage following warm ischemia. Heat shock protein (HSP) 90 has recently been investigated as a novel target to reduce ischemia/reperfusion injury. The objective of this study is to evaluate an innovative HSP90 inhibitor (HSP90i) as a cardioprotective agent in a model of DCD heart. METHODS: A DCD protocol was initiated in anesthetized Lewis rats by discontinuation of ventilation and confirmation of circulatory death by invasive monitoring. Following 15 minutes of warm ischemia, cardioplegia was perfused for 5 minutes at physiological pressure. DCD hearts were mounted on a Langendorff ex vivo heart perfusion system for reconditioning and functional assessment (60 minutes). HSP90i (0.01 µmol/L) or vehicle was perfused in the cardioplegia and during the first 10 minutes of ex vivo heart perfusion reperfusion. Following assessment, pro-survival pathway signaling was evaluated by western blot or polymerase chain reaction. RESULTS: Treatment with HSP90i preserved left ventricular contractility (maximum + dP/dt, 2385 ± 249 vs 1745 ± 150 mm Hg/s), relaxation (minimum -dP/dt, -1437 ± 97 vs 1125 ± 85 mm Hg/s), and developed pressure (60.7 ± 5.6 vs 43.9 ± 4.0 mm Hg), when compared with control DCD hearts (All P = .001). Treatment abrogates ischemic injury as demonstrated by a significant reduction of infarct size (2,3,5-triphenyl-tetrazolium chloride staining) of 7 ± 3% versus 19 ± 4% (P = .03), troponin T release, and mRNA expression of Bax/Bcl-2 (P < .05). CONCLUSIONS: The cardioprotective effects of HSP90i when used following circulatory death might improve transplant organ availability by expanding the use of DCD hearts.

HSP90 Inhibitor Improves Lung Protection in Porcine Model of Donation After Circulatory Arrest.

BACKGROUND: Ischemia-reperfusion associated with prolonged warm ischemia during donation after circulatory death (DCD) induces acute lung injury. The objective of this study was to combine ex vivo lung perfusion (EVLP) and a heat shock protein-90 inhibitor (HSP90i) to recondition DCD organs and prevent primary graft dysfunction. METHODS: Pigs (55 to 65 kg) were anesthetized, ventilated, and hemodynamically monitored. Cardiac arrest was induced with potassium chloride, and animals were left nonventilated for 2 hours. Lungs were procured and perfused in an EVLP platform for 4 hours by using a cellular perfusate. In the study group, the perfusate contained HSP90i and its transport vehicle (n = 4). In the control group, the perfusate contained only the transport vehicle (n = 4). Gas exchange, airway pressures, and compliance were measured. Pulmonary edema was assessed by bronchoscopy and weight measurement. Lung biopsy samples were obtained for histologic analyses and protein expression measurements. RESULTS: The use of HSP90i reduced lung weight gain to 8.4 ± 3.4% vs 26.6 ± 6.2% in the control group (P < .05). There was reduced edema formation. The ratio of the partial pressure of arterial oxygen to the fraction of inspired oxygen at the end of EVLP was 423 ± 65 in the study group vs 339 ± 25 mm Hg in the control group, but this difference was not statistically significant. Lactate metabolism, pulmonary vascular resistance, and pulmonary arterial pressure improved during EVLP with the use of the HSP90i. CONCLUSIONS: The use of HSP90i with EVLP improves the lung reconditioning process. Further research is required to confirm whether these findings translate to benefit once transplanted and observed in vivo. Successful pharmacologic inhibitors may expand the donor pool in the context of DCD donors.

Heat shock protein 90 inhibition and multi-target approach to maximize cardioprotection in ischaemic injury.

Despite several advances in medicine, ischaemic heart disease remains a major cause of morbidity and mortality. The unravelling of molecular mechanisms underlying disease pathophysiology has revealed targets for pharmacological interventions. However, transfer of these pharmcological possibilities to clinical use has been disappointing. Considering the complexity of ischaemic disease at the cellular and molecular levels, an equally multifaceted treatment approach may be envisioned. The pharmacological principle of 'one target, one key' may fall short in such contexts, and optimal treatment may involve one or many agents directed against complementary targets. Here, we introduce a 'multi-target approach to cardioprotection' and propose heat shock protein 90 (HSP90) as a target of interest. We report on a member of a distinct class of HSP90 inhibitor possessing pleiotropic activity, which we found to exhibit potent infarct-sparing effects.

Pre-clinical Model of Cardiac Donation after Circulatory Death.

Cardiac transplantation demand is on the rise; nevertheless, organ availability is limited due to a paucity of suitable donors. Organ donation after circulatory death (DCD) is a solution to address this limited availability, but due to a period of prolonged warm ischemia and the risk of tissue injury, its routine use in cardiac transplantation is seldom seen. In this manuscript we provide a detailed protocol closely mimicking current clinical practices in the context of DCD with continuous monitoring of heart function, allowing for the evaluation of novel cardioprotective strategies and interventions to decrease ischemia-reperfusion injury. In this model, the DCD protocol is initiated in anesthetized Lewis rats by stopping ventilation to induce circulatory death. When systolic blood pressure drops below 30 mmHg, the warm ischemic time is initiated. After a pre-set warm ischemic period, hearts are flushed with a normothermic cardioplegic solution, procured, and mounted onto a Langendorff ex vivo heart perfusion system. Following 10 min of initial reperfusion and stabilization, cardiac reconditioning is continuously evaluated for 60 min using intraventricular pressure monitoring. A heart injury is assessed by measuring cardiac troponin T and the infarct size is quantified by histological staining. The warm ischemic time can be modulated and tailored to develop the desired amount of structural and functional damage. This simple protocol allows for the evaluation of different cardioprotective conditioning strategies introduced at the moment of cardioplegia, initial reperfusion and/or during ex vivo perfusion. Findings obtained from this protocol can be reproduced in large models, facilitating clinical translation.

Celastrol-type HSP90 modulators allow for potent cardioprotective effects.

AIMS: Cardiac ischemic conditioning has been shown to decrease ischemic injury in experimental models and clinically. Activation of survival pathways leading to heat shock proteins (HSP) modulation is an important contributor to this effect. We have previously shown that celastrol, an HSP90 modulator, achieves cardioprotection through activation of cytoprotective HSP's and heme-oxygenase-1 (HO-1). This is the first comparative evaluation of several modulators of HSP90 activity for cardioprotection. Furthermore, basic celastrol structure-activity relationship was characterized in order to develop novel potent infarct sparing agents suitable for clinical development. MAIN METHODS: Combining in vitro cell culture using rat myocardial cell line exposed to ischemic and ischemia/reperfusion (I/R) stresses, and ex vivo Langendorff rat heart perfusion I/R model, we evaluated cardioprotective effects of various compounds. Selected signalling pathways were evaluated by western blot and reporter gene activation. KEY FINDINGS: From a variety of HSP90 modulator chemotypes, the celastrol family was most efficient in inducing cytoprotective HSP70 and HO-1 protein overexpression and cell survival in vitro. Celastrol and two synthetic analogs were protective against ischemia and prevented ischemia/reperfusion (I/R) injury when given as pre-treatment or at time of reperfusion, increasing viability and reducing mitochondrial permeability transition pore opening. Ex vivo experiments demonstrated that the two synthetic analogs show cardioprotective activity at lower concentrations compared to celastrol, with activation of multiple survival pathways. SIGNIFICANCE: Celastrol backbone is essential for cardioprotection through HSP90 activity modulation. These compounds hold promise as novel adjunct treatment to improve outcome in the clinical management of I/R injury.

Moxonidine modulates cytokine signalling and effects on cardiac cell viability.

Regression of left ventricular hypertrophy and improved cardiac function in SHR by the centrally acting imidazoline I1-receptor agonist, moxonidine, are associated with differential actions on circulating and cardiac cytokines. Herein, we investigated cell-type specific I1-receptor (also known as nischarin) signalling and the mechanisms through which moxonidine may interfere with cytokines to affect cardiac cell viability. Studies were performed on neonatal rat cardiomyocytes and fibroblasts incubated with interleukin (IL)-1ß (5 ng/ml), tumor necrosis factor (TNF)-α (10 ng/ml), and moxonidine (10(-7) and 10(-5) M), separately and in combination, for 15 min, and 24 and 48 h for the measurement of MAPKs (ERK1/2, JNK, and p38) and Akt activation and inducible NOS (iNOS) expression, by Western blotting, and cardiac cell viability/proliferation and apoptosis by flow cytometry, MTT assay, and Live/Dead assay. Participation of imidazoline I1-receptors and the signalling proteins in the detected effects was identified using imidazoline I1-receptor antagonist and signalling protein inhibitors. The results show that IL-1ß, and to a lower extent, TNF-α, causes cell death and that moxonidine protects against starvation- as well as IL-1ß -induced mortality, mainly by maintaining membrane integrity, and in part, by improving mitochondrial activity. The protection involves activation of Akt, ERK1/2, p38, JNK, and iNOS. In contrast, moxonidine stimulates basal and IL-1ß-induced fibroblast mortality by mechanisms that include inhibition of JNK and iNOS. Thus, apart from their actions on the central nervous system, imidazoline I1-receptors are directly involved in cardiac cell growth and death, and may play an important role in cardiovascular diseases associated with inflammation.

Functional and molecular effects of imidazoline receptor activation in heart failure.

AIMS: Heart failure is a progressive deterioration in heart function associated with overactivity of the sympathetic nervous system. The benefit of inhibition of sympathetic activity by moxonidine, a centrally acting imidazoline receptor agonist, was questioned based on the outcome of a failing clinical trial. The following studies measured cardiac structure and hemodynamics and mechanisms underlying moxonidine-induced changes, in cardiomyopathic hamsters, where the stage of the disease, dose, and compliance were controlled. MAIN METHODS: Male BIO 14.6 hamsters (6 and 10 months old, with moderate and advanced heart failure, respectively) received moxonidine at 2 concentrations: low (2.4 mg/kg/day) and high (9.6 mg/kg/day), or vehicle, subcutaneously, for 1month. Cardiac function was measured by echocardiography, plasma and hearts were collected for histological determination of fibrosis and apoptosis, as well as for measurement cytokines by Elisa and cardiac proteins by Western blotting. KEY FINDINGS: Compared to age-matched vehicle-treated BIO 14.6, moxonidine did not reduce blood pressure but significantly reduced heart rate and improved cardiac performance. Moxonidine exerted anti-apoptotic effect with differential inflammatory/anti-inflammatory responses that culminate in attenuated cardiac apoptosis and fibrosis and altered protein expression of collagen types. Some effects were observed regardless of treatment onset, although the changes were more significant in the younger group. Interestingly, moxonidine resulted in upregulation of cardiac imidazoline receptors. SIGNIFICANCE: These studies imply that in addition to centrally mediated sympathetic inhibition, the effects of moxonidine may, at least in part, be mediated by direct actions on the heart. Further investigation of imidazolines/imidazoline receptors in cardiovascular diseases is warranted.

Aplicación del Laerdal SimMan Universal Patient Simulator en la enseñanza del uso racional de medicamentos: manejo inicial del choque / Implementing the Laerdal SimMan Universal Patient Simulator when teaching the rational use of medication: dealing with initial shock

Tradicionalmente, la enseñanza se ha basado en la transmisi ón de conceptos, pero es necesario fomentar el aná- lisis crítico de situaciones clínicas particulares en la definición de la conducta para un paciente. Una elevada proporción de prescripciones se realiza inadecuadamente, sin un proceso de análisis de la situación individual del paciente. El desarrollo de ejercicios de aprendizaje basados en la solución de problemas para la definición de la terapéutica farmacológica desde la universidad fomenta el pensamiento crítico y conduce a un mejor ejercicio profesional. Objetivos: 1) diseñar una estrategia para la enseñanza de farmacoterapia basada en la solución de problemas con el Laerdal SimMan Universal Patient Simulator; 2) fomentar el proceso racional de prescripción en la solución de una situación clínica (choque); 3) integrar conceptos de ciencias básicas y clínicas. Metodología: 1) diseño de la práctica: revisión bibliográfica, diseño de algoritmos de tratamiento-respuesta y programación del Laerdal SimMan Universal Patient Simulator para reproducir dichas respuestas, diseño de guías de estudio y práctica; 2) actividades con los estudiantes: sesión magistral sobre fisiopatología y manejo de choque; taller de solución de problemas (paciente en choque); práctica con el simulador en pequeños grupos durante 15 minutos; el docente plantea una breve historia clínica, los estudiantes la discuten, definen el problema del paciente y el objetivo terapéutico e instauran el tratamiento; el simulador es activado para modificar las variables clínicas de acuerdo con el tratamiento instaurado; deben evaluar nuevamente el paciente, verificar el cumplimiento del objetivo, replantear el objetivo y el tratamiento si es necesario y observar el desenlace; 3) evaluación: fueron evaluados antes y durante la práctica; se realizó una retroalimentación posterior de la práctica que evidenció el desenlace como consecuencia de la adecuada o inadecuada definición del problema, del...

Fundamentos del oxido nitrico como agente vasodilatador / Basis and mechanism by nitric oxide leads vascular relaxation

El óxido nítrico es producido en las células endoteliales y de allí migra hacia las células del músculo liso vascular adyacente en donde, a través de segundos mensajeros, produce relajación de la vasculatura. Este artículo pretende revisar los fundamentos de la acción vasodilatadora del óxido nítrico así como su producción y regulación endógenas