¿Cómo influye el tratamiento intensivo de los factores de riesgo cardiovascular en la calidad de vida relacionada con la salud de los pacientes diabéticos?

ObjetivosValorar la calidad de vida relacionada con la salud (CVRS) de los diabéticos tras la aplicación de un protocolo de tratamiento intensivo para control de los factores de riesgo cardiovascular (FRCV).DiseñoEnsayo clínico aleatorizado por agrupaciones. Muestreo de conveniencia de 65 médicos de atención primaria (AP), asignación aleatoria al grupo control e intervención. Muestreo aleatorio sistemático de los diabéticos de cada médico.El seguimiento de los pacientes del grupo control se realizó mediante la práctica habitual y del grupo intervención a través del protocolo de tratamiento intensivo para el control de los FRCV.EmplazamientoEl estudio se realizó en 17 centros de salud de la Comunidad Valenciana.ParticipantesSe incluyó a 184 pacientes, 93 en el grupo control y 91 en el grupo de intervención. Los criterios de inclusión fueron: diabéticos tipo 2 entre 45 y 70 años, diabetes de 2 a 20 años de evolución y riesgo cardiovascular mayor del 20% a los 10 años (ecuación de Framingham). Los criterios de exclusión fueron: antecedentes de cardiopatía isquémica, enfermedad terminal, cirrosis hepática, insuficiencia renal, insuficiencia cardíaca de grados III-IV y alteraciones mentales.Los pacientes autocumplimentaron los cuestionarios de calidad de vida relacionada con la salud: COOP/WONCA y ADDQoL al inicio y a los 6 y 12 meses.Mediciones principalesValores medios de viñetas COOP/WONCA y ADDQoL. Comparación entre grupos mediante el test de la U de Mann-Whitney. El seguimiento de cada grupo se realizó con la prueba de Wilcoxon.ResultadosNo encontramos diferencias significativas en las viñetas COOP/WONCA. A los 12 meses sólo encontramos diferencias significativas en la viñeta sentimientos (p=0,024; grupo control 1,86±1,03; grupo intervención 2,23±1,11). Se observa un impacto negativo de la diabetes en todas las dimensiones del ADDQoL. No se han encontrado diferencias en el ADDQoL entre los grupos ni a lo largo del estudio. El impacto más negativo se obtiene en las dimensiones relacionadas con la dieta.ConclusionesLa CVRS en pacientes con diabetes tipo 2 no resulta afectada por el tratamiento intensivo de los FRCV. La diabetes tiene un impacto negativo en la CVRS de los individuos del estudio.ObjectiveTo assess the health-related quality of life (HRQoL) in diabetic patients who have followed a protocol of intensive treatment of cardiovascular risks (CVR).DesignClinical trial randomised by cluster. A convenience sample of 65 primary care practitioners, randomly assigned to a control or intervention group. Patients were selected by systematic sampling from diabetic lists. The followup for the control group was by normal practice and the intervention group by using the intensive control of cardiovascular risk factors (CVRF) protocol.SettingSeventeen health-centres in the Valencia Community, Spain.ParticipantsOne hundred and eighty-four patients, 93 in the control group and 91 in the intervention group. Inclusion criteria: patients diagnosed with diabetes mellitus (DM) type 2, aged between 45-75 years, DM for more than 2 years and less than 20 years and a cardiovascular risk (CVR) >20% after 10 years (Framingham equation). The exclusion criteria were: history of ischaemic heart disease, terminal illness, hepatic cirrhosis, renal failure, grade III-IV cardiac failure, and mental disorders.The patients self-completed the Spanish versions of the COOP/WONCA charts and a diabetes-specific tool (ADDQol questionnaire) at the start, and after 6 months and 12 months.Main measurementsMeans of COOP/WONCA charts and ADDQol. Comparison between groups using Mann-Whitney U test, and the group follow ups using the Wilcoxon test.ResultsNo significant differences were found in the COOP/WONCA charts. At 12 months the only significant difference was in the feelings chart (P=. 024; control group 1.86±1.03: intervention group 2.23±1.11). A negative impact of diabetes was seen in all the dimensions of ADDQoL. The most negative impact of diabetes was related to diet. There were no significant differences between groups in the ADDQoL throughout the study.Conclusions The HRQoL in diabetic patients is not affected by intensive therapy of cardiovascular risk factors. Diabetes has a negative impact on HRQoL in the patients studied

Epigenetic Biomarkers in Cardiovascular Diseases

Altres ajuts: Fundació La Marató de TV3 (201516-10, 201502-20)Cardiovascular diseases are the number one cause of death worldwide and greatly impact quality of life and medical costs. Enormous effort has been made in research to obtain new tools for efficient and quick diagnosis and predicting the prognosis of these diseases. Discoveries of epigenetic mechanisms have related several pathologies, including cardiovascular diseases, to epigenetic dysregulation. This has implications on disease progression and is the basis for new preventive strategies. Advances in methodology and big data analysis have identified novel mechanisms and targets involved in numerous diseases, allowing more individualized epigenetic maps for personalized diagnosis and treatment. This paves the way for what is called pharmacoepigenetics, which predicts the drug response and develops a tailored therapy based on differences in the epigenetic basis of each patient. Similarly, epigenetic biomarkers have emerged as a promising instrument for the consistent diagnosis and prognosis of cardiovascular diseases. Their good accessibility and feasible methods of detection make them suitable for use in clinical practice. However, multicenter studies with a large sample population are required to determine with certainty which epigenetic biomarkers are reliable for clinical routine. Therefore, this review focuses on current discoveries regarding epigenetic biomarkers and its controversy aiming to improve the diagnosis, prognosis, and therapy in cardiovascular patients

Mechanisms governing the therapeutic effect of mesenchymal stromal cell-derived extracellular vesicles: A scoping review of preclinical evidence

Compelling evidence supports the therapeutic benefit of extracellular vesicles (EVs). EVs are nanostructures with a lipid bilayer membrane that are secreted by multiple cells, including mesenchymal stromal cells (MSCs), as means of cellular communication. MSC-EVs, resembling their MSC origin, carry protected immunomodulatory and pro-regenerative cargoes to targeted neighboring or distant cells and tissues. Though treatments focused on MSC-EVs have emerged as greatly versatile approaches to modulate multiple inflammatory-related conditions, crucial concerns, including the possibility of increasing therapeutic outcomes by pre-conditioning parental MSCs or engineering derived EVs and clarification of the most relevant mechanisms of action, remain. Here, we summarize the large amount of preclinical research surrounding the modulation of beneficial effects by MSC-EVs

Noninvasive assessment of an engineered bioactive graft in myocardial infarction: impact on cardiac function and scar healing

Cardiac tissue engineering, which combines cells and biomaterials, is promising for limiting the sequelae of myocardial infarction (MI). We assessed myocardial function and scar evolution after implanting an engineered bioactive impedance graft (EBIG) in a swine MI model. The EBIG comprises a scaffold of decellularized human pericardium, green fluorescent protein-labeled porcine adipose tissue-derived progenitor cells (pATPCs), and a customized-design electrical impedance spectroscopy (EIS) monitoring system. Cardiac function was evaluated noninvasively by using magnetic resonance imaging (MRI). Scar healing was evaluated by using the EIS system within the implanted graft. Additionally, infarct size, fibrosis, and inflammation were explored by histopathology. Upon sacrifice 1 month after the intervention, MRI detected a significant improvement in left ventricular ejection fraction (7.5%64.9% vs. 1.4%63.7%; p = .038) and stroke volume (11.565.9 ml vs. 364.5 ml; p = .019) in EBIG-treated animals. Noninvasive EIS data analysis showed differences in both impedance magnitude ratio (20.02 6 0.04 per day vs. 20.48 6 0.07 per day; p = .002) and phase angle slope (20.18°60.24° per day vs.23.52°60.84° per day; p = .004) in EBIG compared with control animals. Moreover, in EBIG-treated animals, the infarct size was 48% smaller (3.4%60.6% vs. 6.5%61%; p = .015), less inflammation was found by means of CD25+ lymphocytes (0.65 6 0.12 vs. 1.26 6 0.2; p = .006), and a lower collagen I/III ratio was detected (0.4960.06 vs. 1.6660.5; p = .019). An EBIG composed of acellular pericardium refilled with pATPCs significantly reduced infarct size and improved cardiac function in a preclinical model of MI. Noninvasive EIS monitoring was useful for tracking differential scar healing in EBIG-treated animals, which was confirmed by less inflammation and altered collagen deposit.Peer ReviewedPostprint (published version

Mechanisms of action of sacubitril/valsartan on cardiac remodeling : a systems biology approach

Sacubitril/Valsartan, proved superiority over other conventional heart failure management treatments, but its mechanisms of action remains obscure. In this study, we sought to explore the mechanistic details for Sacubitril/Valsartan in heart failure and post-myocardial infarction remodeling, using an in silico, systems biology approach. Myocardial transcriptome obtained in response to myocardial infarction in swine was analyzed to address post-infarction ventricular remodeling. Swine transcriptome hits were mapped to their human equivalents using Reciprocal Best (blast) Hits, Gene Name Correspondence, and InParanoid database. Heart failure remodeling was studied using public data available in gene expression omnibus (accession GSE57345, subseries GSE57338), processed using the GEO2R tool. Using the Therapeutic Performance Mapping System technology, dedicated mathematical models trained to fit a set of molecular criteria, defining both pathologies and including all the information available on Sacubitril/Valsartan, were generated. All relationships incorporated into the biological network were drawn from public resources (including KEGG, REACTOME, INTACT, BIOGRID, and MINT). An artificial neural network analysis revealed that Sacubitril/Valsartan acts synergistically against cardiomyocyte cell death and left ventricular extracellular matrix remodeling via eight principal synergistic nodes. When studying each pathway independently, Valsartan was found to improve cardiac remodeling by inhibiting members of the guanine nucleotide-binding protein family, while Sacubitril attenuated cardiomyocyte cell death, hypertrophy, and impaired myocyte contractility by inhibiting PTEN. The complex molecular mechanisms of action of Sacubitril/Valsartan upon post-myocardial infarction and heart failure cardiac remodeling were delineated using a systems biology approach. Further, this dataset provides pathophysiological rationale for the use of Sacubitril/Valsartan to prevent post-infarct remodeling. The new wonder drug in heart failure management, Sacubitril/Valsartan, rejuvenates the heart by preventing its dilation. Using data from myocardial infarction and heart failure samples, we generated a mathematical model to better understand how Sacubitril/Valsartan modulates pathological heart resize and the combined effect of the drug. Our analysis revealed that Sacubitril/Valsartan mainly acts by blocking both, cell death and the pathological makeover of the outer-membrane of the cardiac cells. These two major processes occur after a heart attack. Most importantly, we discovered a core of 8 proteins that emerge as key players in this process. A better understanding of the mechanism of novel cardiovascular drugs at the most basic level may help decipher future therapies and indications

Conformational and thermal characterization of left ventricle remodeling post-myocardial infarction

Adverse cardiac remodeling after myocardial infarction (MI) causes impaired ventricular function and heart failure. Histopathological characterization is commonly used to detect the location, size and shape of MI sites. However, the information about chemical composition, physical structure and molecular mobility of peri- and infarct zones post-MI is rather limited. The main objective of this work was to explore the spatiotemporal biochemical and biophysical alterations of key cardiac components post-MI. The FTIR spectra of healthy and remote myocardial tissue shows amides A, I, II and III associated with proteins in freeze-died tissue as major absorptions bands. In infarcted myocardium, the spectrum of these main absorptions was deeply altered. FITR evidenced an increase of the amide A band and the distinct feature of the collagen specific absorption band at 1338cm-1 in the infarct area at 21days post-MI. At 21days post-MI, it also appears an important shift of amide I from 1646cm-1 to 1637cm-1 that suggests the predominance of the triple helical conformation in the proteins. The new spectra bands also indicate an increase in proteoglycans, residues of carbohydrates in proteins and polysaccharides in ischemic areas. Thermal analysis indicates a deep increase of unfreezable water/freezable water in peri- and infarcted tissues. In infarcted tissue is evidenced the impairment of myofibrillar proteins thermal profile and the emergence of a new structure. In conclusion, our results indicate a profound evolution of protein secondary structures in association with collagen deposition and reorganization of water involved in the scar maturation of peri- and infarct zones post-MI

Ex vivo assessment and in vivo validation of non-invasive stent monitoring techniques based on microwave spectrometry

Some conditions are well known to be directly associated with stent failure, including in-stent re-occlusion and stent fracture. Currently, identification of these high-risk conditions requires invasive and complex procedures. This study aims to assess microwave spectrometry (MWS) for monitoring stents non-invasively. Preliminary ex vivo data are presented to move to in vivo validation. Fifteen mice were assigned to receive subcutaneous stent implantations (n¿=¿10) or sham operations (n¿=¿5). MWS measurements were carried out at 0, 2, 4, 7, 14, 22, and 29 days of follow-up. Additionally, 5 stented animals were summited to micro-CT analyses at the same time points. At 29 days, 3 animals were included into a stent fracture subgroup and underwent a last MWS and micro-CT analysis. MWS was able to identify stent position and in-stent stenosis over time, also discerning significant differences from baseline measures (P¿<¿0.001). Moreover, MWS identified fractured vs. non-fractured stents in vivo. Taken together, MWS emerges as a non-invasive, non-ionizing alternative for stent monitoring. MWS analysis clearly distinguished between in-stent stenosis and stent fracture phenomena.Peer ReviewedPostprint (published version

Physiological conditioning by electric field stimulation promotes cardiomyogenic gene expression in human cardiomyocyte progenitor cells

The optimal cell lineage for cardiac-regeneration approaches remains mysterious. Additionally, electrical stimulation promotes cardiomyogenic differentiation of stimulated cells. Therefore, we hypothesized that electrical conditioning of cardiomyocyte progenitor cells (CMPCs) might enrich their cardiovascular potential. CMPCs were isolated from human adult atrial appendages, characterized, and electrically stimulated for 7 and 14 days. Electrical stimulation modulated CMPCs gene and protein expression, increasing all cardiac markers. GATA-binding protein 4 (GATA4) early transcription factor was significantly overexpressed (P = 0.008), but also its coactivator myocyte enhancer factor 2A (MEF2A) was upregulated (P = 0.073) under electrical stimulation. Moreover, important structural proteins and calcium handling-related genes were enhanced. The cardioregeneration capability of CMPCs is improved by electrical field stimulation. Consequently, short-term electrical stimulation should be a valid biophysical approach to modify cardiac progenitor cells toward a cardiogenic phenotype, and can be incorporated into transdifferentiation protocols. Electrostimulated CMPCs may be best-equipped cells for myocardial integration after implantation.Peer ReviewedPostprint (published version

Noninvasive assessment of an engineered bioactive graft in myocardial infarction: impact on cardiac function and scar healing

Cardiac tissue engineering, which combines cells and biomaterials, is promising for limiting the sequelae of myocardial infarction (MI). We assessed myocardial function and scar evolution after implanting an engineered bioactive impedance graft (EBIG) in a swine MI model. The EBIG comprises a scaffold of decellularized human pericardium, green fluorescent protein-labeled porcine adipose tissue-derived progenitor cells (pATPCs), and a customized-design electrical impedance spectroscopy (EIS) monitoring system. Cardiac function was evaluated noninvasively by using magnetic resonance imaging (MRI). Scar healing was evaluated by using the EIS system within the implanted graft. Additionally, infarct size, fibrosis, and inflammation were explored by histopathology. Upon sacrifice 1 month after the intervention, MRI detected a significant improvement in left ventricular ejection fraction (7.5%64.9% vs. 1.4%63.7%; p = .038) and stroke volume (11.565.9 ml vs. 364.5 ml; p = .019) in EBIG-treated animals. Noninvasive EIS data analysis showed differences in both impedance magnitude ratio (20.02 6 0.04 per day vs. 20.48 6 0.07 per day; p = .002) and phase angle slope (20.18°60.24° per day vs.23.52°60.84° per day; p = .004) in EBIG compared with control animals. Moreover, in EBIG-treated animals, the infarct size was 48% smaller (3.4%60.6% vs. 6.5%61%; p = .015), less inflammation was found by means of CD25+ lymphocytes (0.65 6 0.12 vs. 1.26 6 0.2; p = .006), and a lower collagen I/III ratio was detected (0.4960.06 vs. 1.6660.5; p = .019). An EBIG composed of acellular pericardium refilled with pATPCs significantly reduced infarct size and improved cardiac function in a preclinical model of MI. Noninvasive EIS monitoring was useful for tracking differential scar healing in EBIG-treated animals, which was confirmed by less inflammation and altered collagen deposit.Peer ReviewedPostprint (published version