1 6357 114 THE ROLE OF HYPERGLYCAEMIA IN THE DEVELOPMENT OF DIABETIC CARDIOMYOPATHY. DIABETES MELLITUS IS A METABOLIC DISORDER WITH A CHRONIC HYPERGLYCAEMIC STATE. CARDIOVASCULAR DISEASES ARE THE PRIMARY CAUSE OF MORTALITY IN PATIENTS WITH DIABETES. INCREASING EVIDENCE SUPPORTS THE EXISTENCE OF DIABETIC CARDIOMYOPATHY, A CARDIAC DYSFUNCTION WITH IMPAIRED CARDIAC CONTRACTION AND RELAXATION, INDEPENDENT OF CORONARY AND/OR VALVULAR COMPLICATIONS. DIABETIC CARDIOMYOPATHY CAN LEAD TO HEART FAILURE. SEVERAL PRECLINICAL AND CLINICAL STUDIES HAVE AIMED TO DECIPHER THE UNDERLYING MECHANISMS OF DIABETIC CARDIOMYOPATHY. AMONG ALL THE CO-FACTORS, HYPERGLYCAEMIA SEEMS TO PLAY AN IMPORTANT ROLE IN THIS PATHOLOGY. HYPERGLYCAEMIA HAS BEEN SHOWN TO ALTER CARDIAC METABOLISM AND FUNCTION THROUGH SEVERAL DELETERIOUS MECHANISMS, SUCH AS OXIDATIVE STRESS, INFLAMMATION, ACCUMULATION OF ADVANCED GLYCATED END-PRODUCTS AND UPREGULATION OF THE HEXOSAMINE BIOSYNTHESIS PATHWAY. THESE MECHANISMS ARE RESPONSIBLE FOR THE ACTIVATION OF HYPERTROPHIC PATHWAYS, EPIGENETIC MODIFICATIONS, MITOCHONDRIAL DYSFUNCTION, CELL APOPTOSIS, FIBROSIS AND CALCIUM MISHANDLING, LEADING TO CARDIAC STIFFNESS, AS WELL AS CONTRACTILE AND RELAXATION DYSFUNCTION. THIS REVIEW AIMS TO DESCRIBE THE HYPERGLYCAEMIC-INDUCED ALTERATIONS THAT PARTICIPATE IN DIABETIC CARDIOMYOPATHY, AND THEIR CORRELATION WITH THE SEVERITY OF THE DISEASE AND PATIENT MORTALITY, AND TO PROVIDE AN OVERVIEW OF CARDIAC OUTCOMES OF GLUCOSE-LOWERING THERAPY. 2021 2 4459 48 MOLECULAR MECHANISMS OF DIABETIC VASCULAR COMPLICATIONS. DIABETIC COMPLICATIONS ARE THE MAJOR CAUSES OF MORBIDITY AND MORTALITY IN PATIENTS WITH DIABETES. MICROVASCULAR COMPLICATIONS INCLUDE RETINOPATHY, NEPHROPATHY AND NEUROPATHY, WHICH ARE LEADING CAUSES OF BLINDNESS, END-STAGE RENAL DISEASE AND VARIOUS PAINFUL NEUROPATHIES; WHEREAS MACROVASCULAR COMPLICATIONS INVOLVE ATHEROSCLEROSIS RELATED DISEASES, SUCH AS CORONARY ARTERY DISEASE, PERIPHERAL VASCULAR DISEASE AND STROKE. DIABETIC COMPLICATIONS ARE THE RESULT OF INTERACTIONS AMONG SYSTEMIC METABOLIC CHANGES, SUCH AS HYPERGLYCEMIA, LOCAL TISSUE RESPONSES TO TOXIC METABOLITES FROM GLUCOSE METABOLISM, AND GENETIC AND EPIGENETIC MODULATORS. CHRONIC HYPERGLYCEMIA IS RECOGNIZED AS A MAJOR INITIATOR OF DIABETIC COMPLICATIONS. MULTIPLE MOLECULAR MECHANISMS HAVE BEEN PROPOSED TO MEDIATE HYPERGLYCEMIA'S ADVERSE EFFECTS ON VASCULAR TISSUES. THESE INCLUDE INCREASED POLYOL PATHWAY, ACTIVATION OF THE DIACYLGLYCEROL/PROTEIN KINASE C PATHWAY, INCREASED OXIDATIVE STRESS, OVERPRODUCTION AND ACTION OF ADVANCED GLYCATION END PRODUCTS, AND INCREASED HEXOSAMINE PATHWAY. IN ADDITION, THE ALTERATIONS OF SIGNAL TRANSDUCTION PATHWAYS INDUCED BY HYPERGLYCEMIA OR TOXIC METABOLITES CAN ALSO LEAD TO CELLULAR DYSFUNCTIONS AND DAMAGE VASCULAR TISSUES BY ALTERING GENE EXPRESSION AND PROTEIN FUNCTION. LESS STUDIED THAN THE TOXIC MECHANISMS, HYPERGLYCEMIA MIGHT ALSO INHIBIT THE ENDOGENOUS VASCULAR PROTECTIVE FACTORS SUCH AS INSULIN, VASCULAR ENDOTHELIAL GROWTH FACTOR, PLATELET-DERIVED GROWTH FACTOR AND ACTIVATED PROTEIN C, WHICH PLAY IMPORTANT ROLES IN MAINTAINING VASCULAR HOMEOSTASIS. THUS, EFFECTIVE THERAPIES FOR DIABETIC COMPLICATIONS NEED TO INHIBIT MECHANISMS INDUCED BY HYPERGLYCEMIA'S TOXIC EFFECTS AND ALSO ENHANCE THE ENDOGENOUS PROTECTIVE FACTORS. THE PRESENT REVIEW SUMMARIZES THESE MULTIPLE BIOCHEMICAL PATHWAYS ACTIVATED BY HYPERGLYCEMIA AND THE POTENTIAL THERAPEUTIC INTERVENTIONS THAT MIGHT PREVENT DIABETIC COMPLICATIONS. (J DIABETES INVEST, DOI: 10.1111/J.2040-1124.2010.00018.X, 2010). 2010 3 4433 36 MOLECULAR COMPLEXITIES UNDERLYING THE VASCULAR COMPLICATIONS OF DIABETES MELLITUS - A COMPREHENSIVE REVIEW. DIABETES IS A CHRONIC DISEASE, CHARACTERIZED BY HYPERGLYCEMIA, WHICH REFERS TO THE ELEVATED LEVELS OF GLUCOSE IN THE BLOOD, DUE TO THE INABILITY OF THE BODY TO PRODUCE OR USE INSULIN EFFECTIVELY. CHRONIC HYPERGLYCEMIA LEVELS LEAD TO MACROVASCULAR AND MICROVASCULAR COMPLICATIONS. THE MACROVASCULAR COMPLICATIONS CONSIST OF PERIPHERAL ARTERY DISEASE (PAD), CARDIOVASCULAR DISEASES (CVD) AND CEREBROVASCULAR DISEASES, WHILE THE MICROVASCULAR COMPLICATIONS COMPRISE OF DIABETIC MICROANGIOPATHY, DIABETIC NEPHROPATHY, DIABETIC RETINOPATHY AND DIABETIC NEUROPATHY. VASCULAR ENDOTHELIAL DYSFUNCTION PLAYS A CRUCIAL ROLE IN MEDIATING BOTH MACROVASCULAR AND MICROVASCULAR COMPLICATIONS UNDER HYPERGLYCEMIC CONDITIONS. IN DIABETIC MICROVASCULATURE, THE INTRACELLULAR HYPERGLYCEMIA CAUSES DAMAGE TO THE VASCULAR ENDOTHELIUM THROUGH - (I) ACTIVATION OF FOUR BIOCHEMICAL PATHWAYS, NAMELY THE POLYOL PATHWAY, PROTEIN KINASE C (PKC) PATHWAY, ADVANCED GLYCATION END PRODUCTS (AGE) PATHWAY AND HEXOSAMINE PATHWAY, ALL OF WHICH COMMUTES GLUCOSE AND ITS INTERMEDIATES LEADING TO OVERPRODUCTION OF REACTIVE OXYGEN SPECIES, (II) DYSREGULATION OF GROWTH FACTORS AND CYTOKINES, (III) EPIGENETIC CHANGES WHICH CONCERN THE CHANGES IN DNA AS A RESPONSE TO INTRACELLULAR CHANGES, AND (IV) ABNORMALITIES IN NON-CODING RNAS, SPECIFICALLY MICRORNAS. THIS REVIEW WILL FOCUS ON GAINING AN UNDERSTANDING OF THE MOLECULAR COMPLEXITIES UNDERLYING THE VASCULAR COMPLICATIONS IN DIABETES MELLITUS, TO INCREASE OUR UNDERSTANDING TOWARDS THE DEVELOPMENT OF NEW MECHANISTIC THERAPEUTIC STRATEGIES TO PREVENT OR TREAT DIABETES-INDUCED VASCULAR COMPLICATIONS. 2020 4 2491 34 EPIGENETICS AND CARDIOVASCULAR DISEASE IN DIABETES. TYPE 2 DIABETES HAS BECOME A MAJOR HEALTH ISSUE WORLDWIDE. CHRONIC HYPERGLYCEMIA INDUCES A LOW-GRADE INFLAMMATION THAT, ON TOP OF OTHER MECHANISMS, LEADS TO ENDOTHELIAL DYSFUNCTION. MOUNTING EVIDENCE SUGGESTS THAT DNA METHYLATION, POST-TRANSLATIONAL MODIFICATIONS OF HISTONES, AND LONG NON-CODING RNAS PLAY AN IMPORTANT ROLE IN THE INITIATION, MAINTENANCE, AND PROGRESSION OF BOTH MACRO- AND MICRO-VASCULAR COMPLICATIONS OF DIABETES. LONG-TERM EXPOSURE TO HYPERGLYCEMIA INDUCES EPIGENETIC CHANGES THAT COULD BECOME IRREVERSIBLE, A PHENOMENON KNOWN AS THE 'METABOLIC MEMORY.' WHETHER EPIGENETIC-BASED THERAPIES COULD BE USED TO SLOW OR LIMIT THE PROGRESSION OF CARDIOVASCULAR DISEASE REMAINS UNCLEAR. WHILE NON-CODING RNAS ARE CURRENTLY INVESTIGATED AS POTENTIAL BIOMARKERS THAT PREDICT DIABETIC CARDIOVASCULAR DISEASE INCIDENCE AND PROGRESSION, THEIR THERAPEUTIC ROLE IS ONLY HYPOTHETICAL. IN THIS REVIEW, WE HIGHLIGHT THE LATEST FINDINGS IN EXPERIMENTAL AND CLINICAL STUDIES RELEVANT TO EPIGENETICS AND CARDIOVASCULAR DISEASE IN DIABETES. 2015 5 6341 34 THE ROLE OF EPIGENETIC MODIFICATIONS IN LATE COMPLICATIONS IN TYPE 1 DIABETES. TYPE 1 DIABETES IS A CHRONIC AUTOIMMUNE DISEASE IN WHICH THE DESTRUCTION OF PANCREATIC BETA CELLS LEADS TO HYPERGLYCEMIA. THE PREVENTION OF HYPERGLYCEMIA IS VERY IMPORTANT TO AVOID OR AT LEAST POSTPONE THE DEVELOPMENT OF MICRO- AND MACROVASCULAR COMPLICATIONS, ALSO KNOWN AS LATE COMPLICATIONS. THESE INCLUDE DIABETIC RETINOPATHY, CHRONIC RENAL FAILURE, DIABETIC NEUROPATHY, AND CARDIOVASCULAR DISEASES. THE IMPACT OF LONG-TERM HYPERGLYCEMIA HAS BEEN SHOWN TO PERSIST LONG AFTER THE NORMALIZATION OF BLOOD GLUCOSE LEVELS, A PHENOMENON KNOWN AS METABOLIC MEMORY. IT IS BELIEVED THAT EPIGENETIC MECHANISMS SUCH AS DNA METHYLATION, HISTONE MODIFICATIONS, AND MICRORNAS, PLAY AN IMPORTANT ROLE IN METABOLIC MEMORY. THE AIM OF THIS REVIEW IS TO ADDRESS THE IMPACT OF LONG-TERM HYPERGLYCEMIA ON EPIGENETIC MARKS IN LATE COMPLICATIONS OF TYPE 1 DIABETES. 2022 6 6067 41 THE DIABETES MELLITUS-ATHEROSCLEROSIS CONNECTION: THE ROLE OF LIPID AND GLUCOSE METABOLISM AND CHRONIC INFLAMMATION. DIABETES MELLITUS COMPRISES A GROUP OF CARBOHYDRATE METABOLISM DISORDERS THAT SHARE A COMMON MAIN FEATURE OF CHRONIC HYPERGLYCEMIA THAT RESULTS FROM DEFECTS OF INSULIN SECRETION, INSULIN ACTION, OR BOTH. INSULIN IS AN IMPORTANT ANABOLIC HORMONE, AND ITS DEFICIENCY LEADS TO VARIOUS METABOLIC ABNORMALITIES IN PROTEINS, LIPIDS, AND CARBOHYDRATES. ATHEROSCLEROSIS DEVELOPS AS A RESULT OF A MULTISTEP PROCESS ULTIMATELY LEADING TO CARDIOVASCULAR DISEASE ASSOCIATED WITH HIGH MORBIDITY AND MORTALITY. ALTERATION OF LIPID METABOLISM IS A RISK FACTOR AND CHARACTERISTIC FEATURE OF ATHEROSCLEROSIS. POSSIBLE LINKS BETWEEN THE TWO CHRONIC DISORDERS DEPENDING ON ALTERED METABOLIC PATHWAYS HAVE BEEN INVESTIGATED IN NUMEROUS STUDIES. IT WAS SHOWN THAT BOTH TYPES OF DIABETES MELLITUS CAN ACTUALLY INDUCE ATHEROSCLEROSIS DEVELOPMENT OR FURTHER ACCELERATE ITS PROGRESSION. ELEVATED GLUCOSE LEVEL, DYSLIPIDEMIA, AND OTHER METABOLIC ALTERATIONS THAT ACCOMPANY THE DISEASE DEVELOPMENT ARE TIGHTLY INVOLVED IN THE PATHOGENESIS OF ATHEROSCLEROSIS AT ALMOST EVERY STEP OF THE ATHEROGENIC PROCESS. CHRONIC INFLAMMATION IS CURRENTLY CONSIDERED AS ONE OF THE KEY FACTORS IN ATHEROSCLEROSIS DEVELOPMENT AND IS PRESENT STARTING FROM THE EARLIEST STAGES OF THE PATHOLOGY INITIATION. IT MAY ALSO BE REGARDED AS ONE OF THE POSSIBLE LINKS BETWEEN ATHEROSCLEROSIS AND DIABETES MELLITUS. HOWEVER, THE DATA AVAILABLE SO FAR DO NOT ALLOW FOR DEVELOPING EFFECTIVE ANTI-INFLAMMATORY THERAPEUTIC STRATEGIES THAT WOULD STOP ATHEROSCLEROTIC LESION PROGRESSION OR INDUCE LESION REDUCTION. IN THIS REVIEW, WE SUMMARIZE THE MAIN ASPECTS OF DIABETES MELLITUS THAT POSSIBLY AFFECT THE ATHEROGENIC PROCESS AND ITS RELATIONSHIP WITH CHRONIC INFLAMMATION. WE ALSO DISCUSS THE ESTABLISHED PATHOPHYSIOLOGICAL FEATURES THAT LINK ATHEROSCLEROSIS AND DIABETES MELLITUS, SUCH AS OXIDATIVE STRESS, ALTERED PROTEIN KINASE SIGNALING, AND THE ROLE OF CERTAIN MIRNA AND EPIGENETIC MODIFICATIONS. 2020 7 2163 41 EPIGENETIC MECHANISMS IN DIABETIC VASCULAR COMPLICATIONS. THERE HAS BEEN A RAPID INCREASE IN THE INCIDENCE OF DIABETES AS WELL THE ASSOCIATED VASCULAR COMPLICATIONS. BOTH GENETIC AND ENVIRONMENTAL FACTORS HAVE BEEN IMPLICATED IN THESE PATHOLOGIES. INCREASING EVIDENCE SUGGESTS THAT EPIGENETIC FACTORS PLAY A KEY ROLE IN THE COMPLEX INTERPLAY BETWEEN GENES AND THE ENVIRONMENT. ACTIONS OF MAJOR PATHOLOGICAL MEDIATORS OF DIABETES AND ITS COMPLICATIONS SUCH AS HYPERGLYCAEMIA, OXIDANT STRESS, AND INFLAMMATORY FACTORS CAN LEAD TO DYSREGULATED EPIGENETIC MECHANISMS THAT AFFECT CHROMATIN STRUCTURE AND GENE EXPRESSION. FURTHERMORE, PERSISTENCE OF THIS ALTERED STATE OF THE EPIGENOME MAY BE THE UNDERLYING MECHANISM CONTRIBUTING TO A 'METABOLIC MEMORY' THAT RESULTS IN CHRONIC INFLAMMATION AND VASCULAR DYSFUNCTION IN DIABETES EVEN AFTER ACHIEVING GLYCAEMIC CONTROL. FURTHER EXAMINATION OF EPIGENETIC MECHANISMS BY ALSO TAKING ADVANTAGE OF RECENTLY DEVELOPED NEXT-GENERATION SEQUENCING TECHNOLOGIES CAN PROVIDE NOVEL INSIGHTS INTO THE PATHOLOGY OF DIABETES AND ITS COMPLICATIONS AND LEAD TO THE DISCOVERY OF MUCH NEEDED NEW DRUG TARGETS FOR THESE DISEASES. IN THIS REVIEW, WE HIGHLIGHT THE ROLE OF EPIGENETICS IN DIABETES AND ITS VASCULAR COMPLICATIONS, AND RECENT TECHNOLOGICAL ADVANCES THAT HAVE SIGNIFICANTLY ACCELERATED THE FIELD. 2011 8 4195 37 METABOLIC MEMORY: MECHANISMS AND IMPLICATIONS FOR DIABETIC RETINOPATHY. CHRONIC HYPERGLYCEMIA OF DIABETES LEADS TO MICROVASCULAR COMPLICATIONS THAT SEVERELY IMPACT QUALITY OF LIFE. DIABETIC RETINOPATHY (DR) MAY BE THE MOST COMMON OF THESE AND IS A LEADING CAUSE OF VISUAL IMPAIRMENT AND BLINDNESS AMONG WORKING AGE ADULTS IN DEVELOPED NATIONS. MANY LARGE-SCALE TYPE 1 AND TYPE 2 DIABETES CLINICAL TRIALS HAVE DEMONSTRATED THAT EARLY INTENSIVE GLYCEMIC CONTROL CAN REDUCE THE INCIDENCE AND PROGRESSION OF MICRO AND MACROVASCULAR COMPLICATIONS. ON THE OTHER HAND, EPIDEMIOLOGICAL AND PROSPECTIVE DATA HAVE REVEALED THAT THE STRESSORS OF DIABETIC VASCULATURE PERSIST BEYOND THE POINT WHEN GLYCEMIC CONTROL HAS BEEN ACHIEVED. THESE KINDS OF PERSISTENT ADVERSE EFFECTS OF HYPERGLYCEMIA ON THE DEVELOPMENT AND PROGRESSION OF COMPLICATIONS HAS BEEN DEFINED AS "METABOLIC MEMORY", AND OXIDATIVE STRESS, ADVANCED GLYCATION END PRODUCTS AND EPIGENETIC CHANGES HAVE BEEN IMPLICATED IN THE PROCESS. RECENT STUDIES HAVE INDICATED THAT SUCH "HYPERGLYCEMIC MEMORY" MAY ALSO INFLUENCE DR, SUGGESTING THAT MANIPULATION OF HYPERGLYCEMIC MEMORY MAY PROVE A BENEFICIAL APPROACH TO PREVENTION AND TREATMENT. THIS REVIEW SUMMARIZES THE EVIDENCE FROM DR-RELATED CLINICAL TRIALS AND MECHANISTIC STUDIES TO INVESTIGATE THE SIGNIFICANCE OF METABOLIC MEMORY IN DR AND UNDERSTAND ITS POTENTIAL AS A TARGET OF MOLECULAR THERAPEUTICS AIMED AT REVERSING HYPERGLYCEMIC MEMORY. 2012 9 1896 25 ENDOTHELIAL-TO-MESENCHYMAL TRANSITION: AN UNDERAPPRECIATED MEDIATOR OF DIABETIC COMPLICATIONS. DIABETES AND ITS COMPLICATIONS REPRESENT A GREAT BURDEN ON THE GLOBAL HEALTHCARE SYSTEM. DIABETIC COMPLICATIONS ARE FUNDAMENTALLY DISEASES OF THE VASCULATURE, WITH ENDOTHELIAL CELLS BEING THE CENTERPIECE OF EARLY HYPERGLYCEMIA-INDUCED CHANGES. ENDOTHELIAL-TO-MESENCHYMAL TRANSITION IS A TIGHTLY REGULATED PROCESS THAT RESULTS IN ENDOTHELIAL CELLS LOSING ENDOTHELIAL CHARACTERISTICS AND DEVELOPING MESENCHYMAL TRAITS. ALTHOUGH ENDOTHELIAL-TO-MESENCHYMAL TRANSITION HAS BEEN FOUND TO OCCUR WITHIN MOST OF THE MAJOR COMPLICATIONS OF DIABETES, IT HAS NOT BEEN A MAJOR FOCUS OF STUDY OR A COMMON TARGET IN THE TREATMENT OR PREVENTION OF DIABETIC COMPLICATIONS. IN THIS REVIEW WE SUMMARIZE THE IMPORTANCE OF ENDOTHELIAL-TO-MESENCHYMAL TRANSITION IN EACH MAJOR DIABETIC COMPLICATION, EXAMINE SPECIFIC MECHANISMS AT PLAY, AND HIGHLIGHT POTENTIAL MECHANISMS TO PREVENT ENDOTHELIAL-TO-MESENCHYMAL TRANSITION IN EACH OF THE MAJOR CHRONIC COMPLICATIONS OF DIABETES. 2023 10 2965 41 GENETIC AND EPIGENETIC MODIFICATIONS IN THE PATHOGENESIS OF DIABETIC RETINOPATHY: A MOLECULAR LINK TO REGULATE GENE EXPRESSION. INTENSIFICATION IN THE FREQUENCY OF DIABETES AND THE ASSOCIATED VASCULAR COMPLICATIONS HAS BEEN A ROOT CAUSE OF BLINDNESS AND VISUAL IMPAIRMENT WORLDWIDE. ONE SUCH VASCULAR COMPLICATION WHICH HAS BEEN THE PROMINENT CAUSE OF BLINDNESS; RETINAL VASCULATURE, NEURONAL AND GLIAL ABNORMALITIES IS DIABETIC RETINOPATHY (DR), A CHRONIC COMPLICATED OUTCOME OF TYPE 1 AND TYPE 2 DIABETES. IT HAS ALSO BECOME CLEAR THAT "GENETIC" VARIATIONS IN POPULATION ALONE CAN'T EXPLAIN THE DEVELOPMENT AND PROGRESSION OF DIABETES AND ITS COMPLICATIONS INCLUDING DR. DR EXPERIENCES ENGAGEMENT OF FOREMOST MEDIATORS OF DIABETES SUCH AS HYPERGLYCEMIA, OXIDANT STRESS, AND INFLAMMATORY FACTORS THAT LEAD TO THE DYSREGULATION OF "EPIGENETIC" MECHANISMS INVOLVING HISTONE ACETYLATION AND HISTONE AND DNA METHYLATION, CHROMATIN REMODELING AND EXPRESSION OF A COMPLEX SET OF STRESS-REGULATED AND DISEASE-ASSOCIATED GENES. IN ADDITION, BOTH ELEVATED GLUCOSE CONCENTRATION AND INSULIN RESISTANCE LEAVE A ROBUST EFFECT ON EPIGENETIC REPROGRAMMING OF THE ENDOTHELIAL CELLS TOO, SINCE ENDOTHELIUM ASSOCIATED WITH THE EYE AIDS IN MAINTAINING THE VASCULAR HOMEOSTASIS. FURTHERMORE, SEVERAL STUDIES CONDUCTED ON THE DISEASE SUGGEST THAT THE MODIFICATIONS OF THE EPIGENOME MIGHT BE THE FUNDAMENTAL MECHANISM(S) FOR THE PROPOSED METABOLIC MEMORY' RESULTING INTO PROLONGED GENE EXPRESSION FOR INFLAMMATION AND CELLULAR DYSFUNCTION EVEN AFTER ATTAINING THE GLYCEMIC CONTROL IN DIABETICS. HENCEFORTH, THE PRESENT REVIEW FOCUSES ON THE ASPECTS OF GENETIC AND EPIGENETIC ALTERATIONS IN GENES SUCH AS VASCULAR ENDOTHELIAL GROWTH FACTOR AND ALDOSE REDUCTASE CONSIDERED BEING ASSOCIATED WITH DR. IN ADDITION, WE DISCUSS BRIEFLY THE ROLE OF THE THIOREDOXIN-INTERACTING PROTEIN TXNIP, WHICH IS STRONGLY INDUCED BY HIGH GLUCOSE AND DIABETES, IN CELLULAR OXIDATIVE STRESS AND MITOCHONDRIAL DYSFUNCTION POTENTIALLY LEADING TO CHROMATIN REMODELING AND OCULAR COMPLICATIONS OF DIABETES. THE IDENTIFICATION OF DISEASE-ASSOCIATED GENES AND THEIR EPIGENETIC REGULATIONS WILL LEAD TO POTENTIAL NEW DRUGS AND GENE THERAPIES AS WELL AS PERSONALIZED MEDICINE TO PREVENT OR SLOW DOWN THE PROGRESSION OF DR. 2016 11 2613 42 EPIGENETICS: DECIPHERING ITS ROLE IN DIABETES AND ITS CHRONIC COMPLICATIONS. 1. INCREASING EVIDENCE SUGGESTS THAT EPIGENETIC FACTORS MIGHT REGULATE THE COMPLEX INTERPLAY BETWEEN GENES AND THE ENVIRONMENT, AND AFFECT HUMAN DISEASES, SUCH AS DIABETES AND ITS COMPLICATIONS. 2. CLINICAL TRIALS HAVE UNDERSCORED THE LONG LASTING BENEFICIAL EFFECTS OF STRICT GLYCAEMIC CONTROL FOR REDUCING THE PROGRESSION OF DIABETIC COMPLICATIONS. THEY HAVE ALSO SHOWN THAT DIABETIC COMPLICATIONS, SUCH AS DIABETIC NEPHROPATHY, A CHRONIC KIDNEY DISORDER, CAN CONTINUE EVEN AFTER BLOOD GLUCOSE NORMALIZATION, SUGGESTING A METABOLIC MEMORY OF THE PRIOR GLYCAEMIC STATE. 3. DYSREGULATION OF EPIGENETIC POST-TRANSCRIPTIONAL MODIFICATIONS OF HISTONES IN CHROMATIN, INCLUDING HISTONE LYSINE METHYLATION, HAS BEEN IMPLICATED IN ABERRANT GENE REGULATION ASSOCIATED WITH THE PATHOLOGY OF DIABETES AND ITS COMPLICATIONS. GENOME-WIDE STUDIES HAVE SHOWN CELL-TYPE SPECIFIC CHANGES IN HISTONE METHYLATION PATTERNS UNDER DIABETIC CONDITIONS. IN ADDITION, STUDIES IN VASCULAR CELLS HAVE SHOWN LONG LASTING CHANGES IN EPIGENETIC MODIFICATIONS AT KEY INFLAMMATORY GENE PROMOTERS AFTER PRIOR EXPOSURE TO DIABETIC CONDITIONS, SUGGESTING A POSSIBLE MECHANISM FOR METABOLIC MEMORY. 4. RECENT STUDIES HAVE SHOWN ROLES FOR HISTONE METHYLATION, DNA METHYLATION, AS WELL AS MICRORNA IN DIABETIC NEPHROPATHY. WHETHER THESE EPIGENETIC FACTORS PLAY A ROLE IN METABOLIC MEMORY OF DIABETIC KIDNEY DISEASE IS LESS WELL UNDERSTOOD. 5. THE INCIDENCE OF DIABETES IS GROWING RAPIDLY, AS ALSO THE COST OF TREATING THE RESULTING COMPLICATIONS. A BETTER UNDERSTANDING OF METABOLIC MEMORY AND THE POTENTIAL INVOLVEMENT OF EPIGENETIC MECHANISMS IN THIS PHENOMENON COULD ENABLE THE DEVELOPMENT OF NEW THERAPEUTIC TARGETS FOR THE TREATMENT AND/OR PREVENTION OF SUSTAINED DIABETIC COMPLICATIONS. 2011 12 2208 42 EPIGENETIC MODIFICATIONS AND NON-CODING RNA IN DIABETES-MELLITUS-INDUCED CORONARY ARTERY DISEASE: PATHOPHYSIOLOGICAL LINK AND NEW THERAPEUTIC FRONTIERS. DIABETES MELLITUS (DM) IS A GLUCOSE METABOLISM DISORDER CHARACTERIZED BY CHRONIC HYPERGLYCEMIA RESULTING FROM A DEFICIT OF INSULIN PRODUCTION AND/OR ACTION. DM AFFECTS MORE THAN 1 IN 10 ADULTS, AND IT IS ASSOCIATED WITH AN INCREASED RISK OF CARDIOVASCULAR MORBIDITY AND MORTALITY. CARDIOVASCULAR DISEASE (CVD) ACCOUNTS FOR TWO THIRDS OF THE OVERALL DEATHS IN DIABETIC PATIENTS, WITH CORONARY ARTERY DISEASE (CAD) AND ISCHEMIC CARDIOMYOPATHY AS THE MAIN CONTRIBUTORS. HYPERGLYCEMIC DAMAGE ON VASCULAR ENDOTHELIAL CELLS LEADING TO ENDOTHELIAL DYSFUNCTION REPRESENTS THE MAIN INITIATING FACTOR IN THE PATHOGENESIS OF DIABETIC VASCULAR COMPLICATIONS; HOWEVER, THE UNDERLYING PATHOPHYSIOLOGICAL MECHANISMS ARE STILL NOT ENTIRELY UNDERSTOOD. THIS REVIEW ADDRESSES THE CURRENT KNOWLEDGE ON THE PATHOPHYSIOLOGICAL LINKS BETWEEN DM AND CAD WITH A FOCUS ON THE ROLE OF EPIGENETIC MODIFICATIONS, INCLUDING DNA METHYLATION, HISTONE MODIFICATIONS AND NONCODING RNA CONTROL. INCREASED KNOWLEDGE OF EPIGENETIC MECHANISMS HAS CONTRIBUTED TO THE DEVELOPMENT OF NEW PHARMACOLOGICAL TREATMENTS ("EPIDRUGS") WITH EPIGENETIC TARGETS, ALTHOUGH THESE APPROACHES PRESENT SEVERAL CHALLENGES. SPECIFIC EPIGENETIC BIOMARKERS MAY ALSO BE USED TO PREDICT OR DETECT THE DEVELOPMENT AND PROGRESSION OF DIABETES COMPLICATIONS. FURTHER STUDIES ON DIABETES AND CAD EPIGENETICS ARE NEEDED IN ORDER TO IDENTIFY POSSIBLE NEW THERAPEUTIC TARGETS AND ADVANCE PERSONALIZED MEDICINE WITH THE PREDICTION OF INDIVIDUAL DRUG RESPONSES AND MINIMIZATION OF ADVERSE EFFECTS. 2022 13 5821 30 STRESS IN OBESITY AND ASSOCIATED METABOLIC AND CARDIOVASCULAR DISORDERS. OBESITY HAS SIGNIFICANT IMPLICATIONS FOR HEALTHCARE, SINCE IT IS A MAJOR RISK FACTOR FOR BOTH TYPE 2 DIABETES AND THE METABOLIC SYNDROME. THIS SYNDROME IS A COMMON AND COMPLEX DISORDER COMBINING OBESITY, DYSLIPIDEMIA, HYPERTENSION, AND INSULIN RESISTANCE. IT IS ASSOCIATED WITH HIGH ATHEROSCLEROTIC CARDIOVASCULAR RISK, WHICH CAN ONLY PARTIALLY BE EXPLAINED BY ITS COMPONENTS. THEREFORE, TO EXPLAIN HOW OBESITY CONTRIBUTES TO THE DEVELOPMENT OF METABOLIC AND CARDIOVASCULAR DISORDERS, MORE AND BETTER INSIGHT IS REQUIRED INTO THE EFFECTS OF PERSONAL AND ENVIRONMENTAL STRESS ON DISEASE PROCESSES. IN THIS PAPER, WE SHOW THAT OBESITY IS A CHRONIC INFLAMMATORY DISEASE, WHICH HAS MANY MOLECULAR MECHANISMS IN COMMON WITH ATHEROSCLEROSIS. FURTHERMORE, WE FOCUS ON THE ROLE OF OXIDATIVE STRESS ASSOCIATED WITH OBESITY IN THE DEVELOPMENT OF THE METABOLIC SYNDROME. WE DISCUSS HOW SEVERAL STRESS CONDITIONS ARE RELATED TO INFLAMMATION AND OXIDATIVE STRESS IN ASSOCIATION WITH OBESITY AND ITS COMPLICATIONS. WE ALSO EMPHASIZE THE RELATION BETWEEN STRESS CONDITIONS AND THE DEREGULATION OF EPIGENETIC CONTROL MECHANISMS BY MEANS OF MICRORNAS AND SHOW HOW THIS IMPAIRMENT FURTHER CONTRIBUTES TO THE DEVELOPMENT OF OBESITY, CLOSING THE VICIOUS CIRCLE. FINALLY, WE DISCUSS THE LIMITATIONS OF CURRENT ANTI-INFLAMMATION AND ANTIOXIDANT THERAPY TO TREAT OBESITY. 2012 14 2009 26 EPIGENETIC BASIS OF DIABETIC VASCULOPATHY. TYPE 2 DIABETES MELLITUS (T2DM) CAUSES PERIPHERAL VASCULAR DISEASE BECAUSE OF WHICH SEVERAL BLOOD-BORNE FACTORS, INCLUDING VITAL NUTRIENTS FAIL TO REACH THE AFFECTED TISSUE. TISSUE EPIGENOME IS SENSITIVE TO CHRONIC HYPERGLYCEMIA AND IS KNOWN TO CAUSE PATHOGENESIS OF MICRO- AND MACROVASCULAR COMPLICATIONS. THESE VASCULAR COMPLICATIONS OF T2DM MAY PERPETUATE THE ONSET OF ORGAN DYSFUNCTION. THE BURDEN OF DIABETES IS PRIMARILY BECAUSE OF A WIDE RANGE OF COMPLICATIONS OF WHICH NONHEALING DIABETIC ULCERS REPRESENT A MAJOR COMPONENT. THUS, IT IS IMPERATIVE THAT CURRENT RESEARCH HELP RECOGNIZE MORE EFFECTIVE METHODS FOR THE DIAGNOSIS AND MANAGEMENT OF EARLY VASCULAR INJURIES. THIS REVIEW ADDRESSES THE SIGNIFICANCE OF EPIGENETIC PROCESSES SUCH AS DNA METHYLATION AND HISTONE MODIFICATIONS IN THE EVOLUTION OF MACROVASCULAR AND MICROVASCULAR COMPLICATIONS OF T2DM. 2022 15 1254 32 CURRENT PROGRESS ON THE MECHANISMS OF HYPERHOMOCYSTEINEMIA-INDUCED VASCULAR INJURY AND USE OF NATURAL POLYPHENOL COMPOUNDS. CARDIOVASCULAR DISEASE IS ONE OF THE MOST COMMON DISEASES IN THE ELDERLY POPULATION, AND ITS INCIDENCE HAS RAPIDLY INCREASED WITH THE PROLONGATION OF LIFE EXPECTANCY. HYPERHOMOCYSTEINEMIA IS AN INDEPENDENT RISK FACTOR FOR VARIOUS CARDIOVASCULAR DISEASES, INCLUDING ATHEROSCLEROSIS, AND DAMAGE TO VASCULAR FUNCTION PLAYS AN INITIAL ROLE IN ITS PATHOGENESIS. THIS REVIEW PRESENTS THE LATEST KNOWLEDGE ON THE MECHANISMS OF VASCULAR INJURY CAUSED BY HYPERHOMOCYSTEINEMIA, INCLUDING OXIDATIVE STRESS, ENDOPLASMIC RETICULUM STRESS, PROTEIN N-HOMOCYSTEINIZATION, AND EPIGENETIC MODIFICATION, AND DISCUSSES THE THERAPEUTIC TARGETS OF NATURAL POLYPHENOLS. STUDIES HAVE SHOWN THAT NATURAL POLYPHENOLS IN PLANTS CAN REDUCE HOMOCYSTEINE LEVELS AND REGULATE DNA METHYLATION BY ACTING ON OXIDATIVE STRESS AND ENDOPLASMIC RETICULUM STRESS-RELATED SIGNALING PATHWAYS, THUS IMPROVING HYPERHOMOCYSTEINEMIA-INDUCED VASCULAR INJURY. NATURAL POLYPHENOLS OBTAINED VIA DAILY DIET ARE SAFER AND HAVE MORE PRACTICAL SIGNIFICANCE IN THE PREVENTION AND TREATMENT OF CHRONIC DISEASES THAN TRADITIONAL DRUGS. 2021 16 2171 36 EPIGENETIC MECHANISMS IN THE PATHOGENESIS OF DIABETIC FOOT ULCERS. THE INCIDENCE OF DIABETES MELLITUS, A CHRONIC METABOLIC DISEASE ASSOCIATED WITH BOTH PREDISPOSING GENETIC AND ENVIRONMENTAL FACTORS, IS INCREASING GLOBALLY. AS A RESULT, IT IS EXPECTED THAT THERE WILL ALSO BE AN INCREASING INCIDENCE OF DIABETIC COMPLICATIONS WHICH ARISE AS A RESULT OF POOR GLYCEMIC CONTROL. COMPLICATIONS INCLUDE CARDIOVASCULAR DISEASES, NEPHROPATHY, RETINOPATHY AND DIABETIC FOOT ULCERS. THE FINDINGS OF SEVERAL MAJOR CLINICAL TRIALS HAVE IDENTIFIED THAT DIABETIC COMPLICATIONS MAY ARISE EVEN AFTER MANY YEARS OF PROPER GLYCEMIC CONTROL. THIS HAS LED TO THE CONCEPT OF PERSISTENT EPIGENETIC CHANGES. VARIOUS EPIGENETIC MECHANISMS HAVE BEEN IDENTIFIED AS IMPORTANT CONTRIBUTORS TO THE PATHOGENESIS OF DIABETES AND DIABETIC COMPLICATIONS. THE AIM OF THIS REVIEW IS TO PROVIDE AN OVERVIEW OF THE PATHOBIOLOGY OF TYPE 2 DIABETES WITH AN EMPHASIS ON COMPLICATIONS, PARTICULARLY DIABETIC FOOT ULCERS. AN OVERVIEW OF EPIGENETIC MECHANISMS IS PROVIDED AND THE FOCUS IS ON THE EMERGING EVIDENCE FOR ABERRANT EPIGENETIC MECHANISMS IN DIABETIC FOOT ULCERS. 2012 17 3749 35 INSIGHTS INTO THE ROLE OF PLASMATIC AND EXOSOMAL MICRORNAS IN OXIDATIVE STRESS-RELATED METABOLIC DISEASES. A COMMON DENOMINATOR OF METABOLIC DISEASES, INCLUDING TYPE 2 DIABETES MELLITUS, DYSLIPIDEMIA, AND ATHEROSCLEROSIS, ARE ELEVATED OXIDATIVE STRESS AND CHRONIC INFLAMMATION. THESE COMPLEX, MULTI-FACTORIAL DISEASES ARE CAUSED BY THE DETRIMENTAL INTERACTION BETWEEN THE INDIVIDUAL GENETIC BACKGROUND AND MULTIPLE ENVIRONMENTAL STIMULI. THE CELLS, INCLUDING THE ENDOTHELIAL ONES, ACQUIRE A PREACTIVATED PHENOTYPE AND METABOLIC MEMORY, EXHIBITING INCREASED OXIDATIVE STRESS, INFLAMMATORY GENE EXPRESSION, ENDOTHELIAL VASCULAR ACTIVATION, AND PROTHROMBOTIC EVENTS, LEADING TO VASCULAR COMPLICATIONS. THERE ARE DIFFERENT PATHWAYS INVOLVED IN THE PATHOGENESIS OF METABOLIC DISEASES, AND INCREASED KNOWLEDGE SUGGESTS A ROLE OF THE ACTIVATION OF THE NF-KB PATHWAY AND NLRP3 INFLAMMASOME AS KEY MEDIATORS OF METABOLIC INFLAMMATION. EPIGENETIC-WIDE ASSOCIATED STUDIES PROVIDE NEW INSIGHT INTO THE ROLE OF MICRORNAS IN THE PHENOMENON OF METABOLIC MEMORY AND THE DEVELOPMENT CONSEQUENCES OF VESSEL DAMAGE. IN THIS REVIEW, WE WILL FOCUS ON THE MICRORNAS RELATED TO THE CONTROL OF ANTI-OXIDATIVE ENZYMES, AS WELL AS MICRORNAS RELATED TO THE CONTROL OF MITOCHONDRIAL FUNCTIONS AND INFLAMMATION. THE OBJECTIVE IS THE SEARCH FOR NEW THERAPEUTIC TARGETS TO IMPROVE THE FUNCTIONING OF MITOCHONDRIA AND REDUCE OXIDATIVE STRESS AND INFLAMMATION, DESPITE THE ACQUIRED METABOLIC MEMORY. 2023 18 4191 40 METABOLIC LANDSCAPE IN CARDIAC AGING: INSIGHTS INTO MOLECULAR BIOLOGY AND THERAPEUTIC IMPLICATIONS. CARDIAC AGING IS EVIDENT BY A REDUCTION IN FUNCTION WHICH SUBSEQUENTLY CONTRIBUTES TO HEART FAILURE. THE METABOLIC MICROENVIRONMENT HAS BEEN IDENTIFIED AS A HALLMARK OF MALIGNANCY, BUT RECENT STUDIES HAVE SHED LIGHT ON ITS ROLE IN CARDIOVASCULAR DISEASES (CVDS). VARIOUS METABOLIC PATHWAYS IN CARDIOMYOCYTES AND NONCARDIOMYOCYTES DETERMINE CELLULAR SENESCENCE IN THE AGING HEART. METABOLIC ALTERATION IS A COMMON PROCESS THROUGHOUT CARDIAC DEGENERATION. IMPORTANTLY, THE INVOLVEMENT OF CELLULAR SENESCENCE IN CARDIAC INJURIES, INCLUDING HEART FAILURE AND MYOCARDIAL ISCHEMIA AND INFARCTION, HAS BEEN REPORTED. HOWEVER, METABOLIC COMPLEXITY AMONG HUMAN AGING HEARTS HINDERS THE DEVELOPMENT OF STRATEGIES THAT TARGETS METABOLIC SUSCEPTIBILITY. ADVANCES OVER THE PAST DECADE HAVE LINKED CELLULAR SENESCENCE AND FUNCTION WITH THEIR METABOLIC REPROGRAMMING PATHWAY IN CARDIAC AGING, INCLUDING AUTOPHAGY, OXIDATIVE STRESS, EPIGENETIC MODIFICATIONS, CHRONIC INFLAMMATION, AND MYOCYTE SYSTOLIC PHENOTYPE REGULATION. IN ADDITION, METABOLIC STATUS IS INVOLVED IN CRUCIAL ASPECTS OF MYOCARDIAL BIOLOGY, FROM FIBROSIS TO HYPERTROPHY AND CHRONIC INFLAMMATION. HOWEVER, FURTHER ELUCIDATION OF THE METABOLISM INVOLVEMENT IN CARDIAC DEGENERATION IS STILL NEEDED. THUS, DECIPHERING THE MECHANISMS UNDERLYING HOW METABOLIC REPROGRAMMING IMPACTS CARDIAC AGING IS THOUGHT TO CONTRIBUTE TO THE NOVEL INTERVENTIONS TO PROTECT OR EVEN RESTORE CARDIAC FUNCTION IN AGING HEARTS. HERE, WE SUMMARIZE EMERGING CONCEPTS ABOUT METABOLIC LANDSCAPES OF CARDIAC AGING, WITH SPECIFIC FOCUSES ON WHY METABOLIC PROFILE ALTERS DURING CARDIAC DEGENERATION AND HOW WE COULD UTILIZE THE CURRENT KNOWLEDGE TO IMPROVE THE MANAGEMENT OF CARDIAC AGING. 2023 19 3156 34 GLYCEMIC MEMORIES AND THE EPIGENETIC COMPONENT OF DIABETIC NEPHROPATHY. A STRONG CASE FOR THE DEREGULATION OF EPIGENETIC CHROMATIN MODIFICATIONS IN THE DEVELOPMENT AND PROGRESSION OF VARIOUS CHRONIC COMPLICATIONS OF DIABETES HAS EMERGED FROM RECENT EXPERIMENTAL OBSERVATIONS. CLINICAL TRIALS OF TYPE 1 AND TYPE 2 DIABETES PATIENTS HIGHLIGHT THE IMPORTANCE OF EARLY AND INTENSIVE TREATMENT AND THE PROLONGED DAMAGE OF HYPERGLYCEMIA ON ORGANS SUCH AS THE KIDNEY. THE FUNCTIONAL RELATIONSHIP BETWEEN THE REGULATION OF CHROMATIN ARCHITECTURE AND PERSISTENT GENE EXPRESSION CHANGES CONFERRED BY PRIOR HYPERGLYCEMIA REPRESENTS AN IMPORTANT AVENUE OF INVESTIGATION FOR EXPLAINING DIABETIC NEPHROPATHY. WHILE SEVERAL STUDIES IMPLICATE EPIGENETIC CHANGES AT THE CHROMATIN TEMPLATE IN THE DEREGULATED GENE EXPRESSION ASSOCIATED WITH DIABETIC NEPHROPATHY, THE MOLECULAR DETERMINANTS OF METABOLIC MEMORY IN RENAL CELLS REMAIN POORLY UNDERSTOOD. THERE IS NOW STRONG EVIDENCE FROM EXPERIMENTAL ANIMALS AND CELL CULTURE OF PERSISTENT GLUCOSE-DRIVEN CHANGES IN VASCULAR ENDOTHELIAL GENE EXPRESSION THAT MAY ALSO HAVE RELEVANCE FOR THE MICROVASCULATURE OF THE KIDNEY. EXPLORATION OF EPIGENETIC MECHANISMS UNDERLYING THE HYPERGLYCEMIC CUE MEDIATING PERSISTENT TRANSCRIPTIONAL CHANGES IN RENAL CELLS HOLDS NOVEL THERAPEUTIC POTENTIAL FOR DIABETIC NEPHROPATHY. 2013 20 3748 41 INSIGHTS INTO THE ROLE OF DNA METHYLATION AND PROTEIN MISFOLDING IN DIABETES MELLITUS. BACKGROUND: DIABETES MELLITUS IS A METABOLIC DISORDER THAT IS CHARACTERIZED BY IMPAIRED GLUCOSE TOLERANCE RESULTING FROM DEFECTS IN INSULIN SECRETION, INSULIN ACTION, OR BOTH. EPIGENETIC MODIFICATIONS, WHICH ARE DEFINED AS INHERITED CHANGES IN GENE EXPRESSION THAT OCCUR WITHOUT CHANGES IN GENE SEQUENCE, ARE INVOLVED IN THE ETIOLOGY OF DIABETES. METHODS: IN THIS REVIEW, WE FOCUSED ON THE ROLE OF DNA METHYLATION AND PROTEIN MISFOLDING AND THEIR CONTRIBUTION TO THE DEVELOPMENT OF BOTH TYPE 1 AND TYPE 2 DIABETES MELLITUS. RESULTS: CHANGES IN DNA METHYLATION IN PARTICULAR ARE HIGHLY ASSOCIATED WITH THE DEVELOPMENT OF DIABETES. PROTEIN FUNCTION IS DEPENDENT ON THEIR PROPER FOLDING IN THE ENDOPLASMIC RETICULUM. DEFECTIVE PROTEIN FOLDING AND CONSEQUENTLY THEIR FUNCTIONS HAVE ALSO BEEN REPORTED TO PLAY A ROLE. EARLY TREATMENT OF DIABETES HAS PROVEN TO BE OF GREAT BENEFIT, AS EVEN TRANSIENT HYPERGLYCEMIA MAY LEAD TO PATHOLOGICAL EFFECTS AND COMPLICATIONS LATER ON. THIS HAS BEEN EXPLAINED BY THE THEORY OF THE DEVELOPMENT OF A METABOLIC MEMORY IN DIABETES. THE BASIS FOR THIS METABOLIC MEMORY WAS ATTRIBUTED TO OXIDATIVE STRESS, CHRONIC INFLAMMATION, NON-ENZYMATIC GLYCATION OF PROTEINS AND IMPORTANTLY, EPIGENETIC CHANGES. THIS HIGHLIGHTS THE IMPORTANCE OF LINKING NEW THERAPEUTICS TARGETING EPIGENETIC MECHANISMS WITH TRADITIONAL ANTIDIABETIC DRUGS. CONCLUSION: ALTHOUGH NEW DATA IS EVOLVING ON THE RELATION BETWEEN DNA METHYLATION, PROTEIN MISFOLDING, AND THE ETIOLOGY OF DIABETES, MORE STUDIES ARE REQUIRED FOR DEVELOPING NEW RELEVANT DIAGNOSTICS AND THERAPEUTICS. 2019