Exploratory study for identifying systemic biomarkers that correlate with pain response in patients with intervertebral disc disorders.

Molecular events that drive disc damage and low back pain (LBP) may precede clinical manifestation of disease onset and can cause detrimental long-term effects such as disability. Biomarkers serve as objective molecular indicators of pathological processes. The goal of this study is to identify systemic biochemical factors as predictors of response to treatment of LBP with epidural steroid injection (ESI). Since inflammation plays a pivotal role in LBP, this pilot study investigates the effect of ESI on systemic levels of 48 inflammatory biochemical factors (cytokines, chemokines, and growth factors) and examines the relationship between biochemical factor levels and pain or disability in patients with disc herniation (DH), or other diagnoses (Other Dx) leading to low back pain, which included spinal stenosis (SS) and degenerative disc disease (DDD). Study participants (n = 16) were recruited from a back pain management practice. Pain numerical rating score (NRS), Oswestry Disability Index (ODI), and blood samples were collected pre- and at 7 to 10 days post-treatment. Blood samples were assayed for inflammatory mediators using commercial multiplex assays. Mediator levels were compared pre- and post-treatment to investigate the potential correlations between clinical and biochemical outcomes. Our results indicate that a single ESI significantly decreased systemic levels of SCGF-ß and IL-2. Improvement in pain in all subjects was correlated with changes in chemokines (MCP-1, MIG), hematopoietic progenitor factors (SCGF-ß), and factors that participate in angiogenesis/fibrosis (HGF), nociception (SCF, IFN-α2), and inflammation (IL-6, IL-10, IL-18, TRAIL). Levels of biochemical mediators varied based on diagnosis of LBP, and changes in pain responses and systemic mediators from pre- to post-treatment were dependent on the diagnosis cohort. In the DH cohort, levels of IL-17 and VEGF significantly decreased post-treatment. In the Other Dx cohort, levels of IL-2Rα, IL-3, and SCGF-ß significantly decreased post-treatment. In order to determine whether mediator changes were related to pain, correlations between change in pain scores and change in mediator levels were performed. Subjects with DH demonstrated a profile signature that implicated hematopoiesis factors (SCGF-ß, GM-CSF) in pain response, while subjects with Other Dx demonstrated a biomarker profile that implicated chemokines (MCP-1, MIG) and angiogenic factors (HGF, VEGF) in pain response. Our findings provide evidence that systemic biochemical factors in patients with LBP vary by diagnosis, and pain response to treatment is associated with a unique profile of biochemical responses in each diagnosis group. Future hypothesis-based studies with larger subject cohorts are warranted to confirm the findings of this pilot exploratory study.

Cardioreparation in hypertensive heart disease.

The normal myocardium is composed of a variety of cells. Cardiac myocytes, tethered within an extracellular matrix of fibrillar collagen, represent one third of all cells; noncardiomyocytes account for the remaining two thirds. Ventricular hypertrophy involves myocyte growth. Hypertensive heart disease (HHD) includes myocyte and nonmyocyte growth that leads to an adverse structural remodeling of the intramural coronary vasculature and matrix. In HHD, it is not the quantity of myocardium but rather its quality that accounts for increased risk of adverse cardiovascular events. Structural homogeneity of cardiac tissue is governed by a balanced equilibrium existing between stimulator and inhibitor signals that regulate cell growth, apoptosis, phenotype, and matrix turnover. Stimulators (eg, angiotensin II, aldosterone, and endothelins) are normally counterbalanced by inhibitors (eg, bradykinin, NO, and prostaglandins) in a paradigm of reciprocal regulation. To reduce the risk of heart failure and sudden cardiac death that accompanies HHD, its adverse structural remodeling must be targeted for pharmacologic intervention. Cardioprotective agents counteract the imbalance between stimulators and inhibitors. They include ACE and endopeptidase inhibitors and respective receptor antagonists. Cardioreparative agents reverse the growth-promoting state and regress existing abnormalities in coronary vascular and matrix structure. ACE inhibition has achieved this outcome with favorable impact on vasomotor reactivity and tissue stiffness. Today's management of hypertension should not simply focus on a reduction in blood pressure, it must also target the adverse structural remodeling that begets HHD.

Renin expression at sites of repair in the infarcted rat heart.

Y. Sun, J. Zhang, J. Q. Zhang and K. T. Weber. Renin Expression at Sites of Repair in the Infarcted Rat Heart. Journal of Molecular and Cellular Cardiology (2001) 33, 995-1003. Angiotensin (Ang) II has autocrine and paracrine functions that contribute to structural cardiac remodeling by fibrous tissue following myocardial infarction (MI). The recruitment of angiotensin converting enzyme (ACE) and AngII receptors by inflammatory and fibroblast-like cells involved in tissue repair of the infarcted heart is now well established. On the other hand, the temporal and spatial response and cellular source of renin in infarcted hearts have not been fully elucidated. The relationship between renin synthesis and circulating renin activity have likewise not been addressed. The present study sought to assess the cellular source, spatial distribution and temporal response of renin expression and synthesis in the rat heart following anterior transmural MI, and to determine its relationship to circulating renin activity. At day 3 and weeks 1, 2, 3 and 4 following left coronary artery ligation, the localization and optical density of cardiac renin mRNA was detected by quantitative in situ hybridization; cardiac and circulating renin activity was measured by radioimmunoassay; cells expressing cardiac renin were detected by immunohistochemistry; and injury/repair was assessed by hematoxylin/eosin and collagen-specific picrosirius red staining. Unoperated rats served as normal controls. The authors found: (1) renin mRNA and activity were not detected in either normal control or non-infarcted myocardium, but were expressed at the site of infarction and other sites of repair involving visceral pericardium and endocardium of interventricular septum at all time points; (2) cells expressing renin at day 3 and weeks 1 and 2 were predominantly macrophages, while at weeks 3 and 4, they were primarily myofibroblasts; (3) renin activity in the infarcted myocardium rose progressively over the course of 4 weeks; and (4) circulating renin activity was significantly increased at day 3 and week 1, reached a peak at week 2, declined at week 3 and returned to normal levels at week 4. Thus, renin expression and activity appear at sites of repair in the infarcted rat heart on day 3 and rise progressively thereafter over 4 weeks, independent of circulating renin. Several types of cells are responsible for renin synthesis at these sites; primarily macrophages during the inflammatory phase of repair, and myofibroblasts during the subsequent fibrogenic phase. Cardiac renin production following MI contributes to local AngII generation that regulates tissue repair and structural remodeling following MI.

Spironolactone in congestive heart failure.

When a large multicenter research trial is abruptly terminated, it is usually a consequence of significant adverse events. In contrast, when the Randomized Aldactone Evaluation Study (RALES) mortality trial was discontinued 18 months early, it was because of the prominent salutary effect of spironolactone, added to standard multidrug therapy consisting of an angiotensin converting enzyme (ACE) inhibitor and loop diuretic (with or without digoxin), in reducing the incidence of death and hospitalization in patients with severe congestive heart failure (CHF). Therapies directed toward suppression of neurohormonal activation have contributed to significant reductions in morbidity and mortality. ACE inhibitors, in particular, have had the largest impact on adverse outcome measures in CHF. Yet despite combined therapy with an ACE inhibitor and loop diuretic, patients on these agents still have an unacceptably high incidence of progressive ventricular failure and death. In the years that followed its discovery in 1954, aldosterone was considered a target for therapy in CHF because of its role in sodium retention. It is now clear that chronic elevations in plasma aldosterone are responsible for many other adverse effects (Fig. 1), including enhanced potassium and magnesium excretion, myocardial fibrosis, inhibition of catecholamine reuptake, endothelial cell and baroreceptor dysfunction, and ventricular arrhythmias. Blockade of aldosterone action is a desirable pharmacologic approach to treating both the underlying pathophysiology of CHF and its clinical consequences. Spironolactone promotes magnesium and potassium retention, increases uptake of myocardial norepinephrine, attenuates formation of myocardial fibrosis, and decreases mortality associated with both progressive ventricular dysfunction and malignant ventricular arrhythmias. Despite the encouraging results seen in the recent RALES mortality trial, a diagnosis of CHF still carries 30% to 40% mortality at 2 years. We need to continue the trend of evaluating newer therapies directed at the pathophysiologic mechanisms of this syndrome, with a goal toward delaying and eventually reversing long-term consequences.

Connective tissue and the heart. Functional significance and regulatory mechanisms.

The heart has a three-dimensional extracellular fibrillar collagen scaffolding that normally serves a variety of functions important to tissue integrity and efficiency of muscular systolic pump and diastolic suction pump function (see article by Kovács). An adverse accumulation of extracellular matrix structural protein compromises tissue stiffness and adversely affects myocardial viscoelasticity, this leads to ventricular diastolic and systolic dysfunction. Hormonal factors, such as chronic, inappropriate (relative to dietary salt intake and intravascular volume) elevations in circulating angiotensin II and aldosterone, are accompanied by fibrosis of right and left sides of the heart. Hemodynamic factors regulate cardiac myocyte work and their adaptive hypertrophic growth. The relative contributions of hormonal and hemodynamic factors in regulating growth of muscular and nonmuscular compartments must form the basis for the selection of pharmacologic intervention that will optimize the management of symptomatic heart failure that accompanies hypertensive heart disease and ischemic cardiomyopathy. Cardioprotective strategies that prevent alteration of normal cardiac tissue structure by fibrosis and appearance of abnormal ventricular stiffness (viscoelasticity) are based on negating the generation of these hormones or interfering with their receptor-ligand binding. A regression of established cardiac fibrosis and improvement in abnormal ventricular stiffness is feasible. Experimental and clinical findings with lisinopril in hypertensive heart disease, where cardiac fibrosis and abnormal ventricular stiffness are present, indicate that such cardioreparation should be a targeted objective of pharmacologic intervention. Systematic analysis of this approach using a controlled clinical trial format is warranted. In recognizing the importance of viscoelastic elements in regulating the mechanical behavior of cardiac tissue, and in turn systolic and diastolic ventricular function, a broader tissue compartment based paradigm (ECM versus myocyte) for the management of heart failure emerges.

Synthesis of glycolipid analogues that disrupt binding of HIV-1 gp120 to galactosylceramide.

HIV-1 has been shown to infect CD4 negative cells by the binding of HIV gp120 to the glycolipid galactosylceramide (1) (GalCer). Several analogues of 1 were prepared to investigate the specific orientation of 1 in the membrane bilayer that is involved in gp120 binding. Interestingly, N-stearyl-1-deoxynojirimycin (8) displayed potent and specific affinity for gp120 equal to that of 1, a finding that may shed light on the antiviral activity of N-butyl-1-deoxynojirimycin.

Infarct scar: a dynamic tissue.

Infarct scar, a requisite to the rebuilding of necrotic myocardium following myocardial infarction (MI), has long been considered inert. Earlier morphologic studies suggested healing at the infarct site was complete within 6-8 weeks following MI and resultant scar tissue, albeit necessary, was acellular and simply fibrillar collagen. Utilizing molecular and cellular biologic technologies, recent studies indicate otherwise. Infarct scar is composed of phenotypically transformed fibroblast-like cells, termed myofibroblasts (myoFb) because they express alpha-smooth muscle actin (alpha-SMA) and these microfilaments confer contractile behavior in response to various peptides and amines. These cells are nourished by a neovasculature and are persistent at the MI site, where they are metabolically active expressing components requisite to angiotensin (Ang) peptide generation, including converting enzyme, receptors for AngII and transforming growth factor (TGF)-beta1. They continue to elaborate fibrillar type I collagen. Their generation of these peptides contribute to ongoing scar tissue collagen turnover and to fibrous tissue formation of noninfarcted myocardium. Infarct scar contraction accounts for its thinning and its tonus may contribute to abnormal ventricular chamber stiffness with diastolic dysfunction. Infarct scar is a dynamic tissue: cellular, vascularized, metabolically active and contractile. Pharmacologic interventions with angiotensin converting enzyme inhibitor or AT1 receptor antagonist has proven effective in attenuating scar tissue metabolic activity and minimizing adverse accumulation of fibrous tissue in noninfarcted myocardium.

Fibrosis and hypertensive heart disease.

The normal myocardium is composed of a variety of cells: cardiac myocytes and noncardiomyocytes, which include endothelial and vascular smooth muscle cells and fibroblasts. Hypertensive heart disease involves a structural remodeling of muscular and nonmuscular compartments. It is not the quantity but rather the quality of myocardium that accounts for pathologic hypertrophy and predisposes to ventricular dysfunction and arrhythmias, which, in turn, confer increased risk of adverse cardiovascular events. Herein, factors regulating growth of these compartments are reviewed and in particular signals involved in promoting adverse remodeling of intramyocardial coronary arteries and arterioles by fibrous tissue.

Recruitable ACE and tissue repair in the infarcted heart.

Constitutive angiotensin-converting enzyme (ACE) is bound to endothelial cells where it serves to regulate circulating concentrations of angiotensin II (Ang II) that normally contribute to circulatory homeostasis. Recruitable ACE, bound to macrophage and myofibroblast cell membrane, regulates local concentrations of Ang II involved in tissue repair. De novo generation of Ang II modulates expression of TGF-beta1 whose autocrine/paracrine properties regulate collagen turnover at sites of fibrous tissue formation that appear in response to various forms of injury in diverse tissues. Persistent myofibroblasts and their ACE activity at the infarct site contribute to a sustained metabolic activity that can account for a progressive fibrosis at, and remote to, sites of myocardial infarction. Activation of the circulating renin-angiotensin-aldosterone system with sustained elevations in plasma Ang II and aldosterone induce a pro-inflammatory vascular phenotype of small arteries and arterioles. This further promotes the appearance of recruitable ACE bound to macrophages and myofibroblasts involved in vascular remodelling. Locally produced Ang II from these vascular sites leads to perivascular fibrosis of intramural coronary vasculature of non-infarcted myocardium. At these sites, remote to the infarct, such adverse structural remodelling by fibrous tissue eventuates in ICM, a major aetiologic factor involved in the appearance of chronic cardiac failure and contributes to its progressive nature.

Angiotensin II receptor blockade during gestation attenuates collagen formation in the developing rat heart.

OBJECTIVE: Fetal cardiac development includes rapid formation of a three-dimensional collagen network, composed mainly of type I and III fibrillar collagens. Collagen fibrils have been found in cardiac jelly at very early stages of cardiac development and are thought to have structural and functional properties. In adult rat cardiac tissue, angiotensin II (AngII) via AT1 receptor binding and AngII-regulated expression of transforming growth factor beta-1 (TGF-beta 1) each upregulate collagen transcription. AT1 and AT2 receptor subtypes are developmentally regulated; both have been localized in fetal tissue where the AT2 receptor is considered a determinant of morphogenesis. We sought to determine whether blockade of either receptor would result in attenuation of collagen mRNA expression and fibrillar collagen accumulation and alter TGF-beta 1 mRNA expression in the developing fetal heart examined at birth. METHODS: Pregnant rats were treated either with an AT1 receptor antagonist losartan or an AT2 receptor antagonist PD123319 and compared with untreated age-matched controls. Offspring were studied within 24 h of birth. Type I and type III collagen mRNA expression, as well as TGF-beta 1 mRNA expression, were examined by in situ hybridization. Collagen concentration was determined spectrophotometrically by picrosirius red staining and type I and III collagens were detected by immunoblotting. RESULTS: We found: (1) comparable birth weights in control and PD123319-treated animals, but reduced body weight in newborn losartan-treated animals; (2) compared to untreated animals, type I collagen and TGF-beta 1 mRNA expression in cardiac tissue were each equally reduced in both losartan and PD123319-treated animals; (3) increased type III collagen mRNA expression in both PD123319- and losartan-treated groups; and (4) a significant decrease in total soluble cardiac collagen concentration in both losartan and PD123319-treated groups, confirmed by attenuated immunoreactivity of type I and III collagens in whole heart extracts by Western blotting. CONCLUSIONS: The results of these pharmacologic interventions suggest AngII receptors are expressed in cardiac tissue during gestation, where both AT1 and AT2 receptors are involved in the regulation of type I and III collagen expression and structural protein accumulation. These effects appear to be mediated, in part, by attenuated cardiac TGF-beta 1 levels. The marked decrease in newborn cardiac collagen content has yet undefined functional consequences.

Angiotensin II and connective tissue: homeostasis and reciprocal regulation.

As a concept traditionally applied to integrative organ physiology, homeostasis likewise applies to self-regulated growth and structure of loose, dense and specialized connective tissues. De novo generation and co-induction of signals, either stimulatory or inhibitory to the formation of these tissues, provide for a reciprocal regulation of their composition; angiotensin (Ang) II is a growth stimulator. Components involved in AngII generation and its biological activity, including angiotensin converting enzyme (ACE) and AngII receptors, are expressed by mesenchymal cells responsible for connective tissue turnover. ACE inhibition or AT1 receptor antagonism attenuate the formation of these connective tissues. The concept of circulatory homeostasis, and the endocrine properties of plasma AngII involved in maintaining same, need each be broadened to encompass auto- and paracrine effects of AngII produced within connective tissues, where it contributes to their homeostatic regulation of structure and composition.