Glycated collagen cross-linking alters cardiac mechanics in volume-overload hypertrophy

doi:10.1152/ajpheart.00168.2002

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Glycated collagen cross-linking alters cardiac mechanics in volume-overload hypertrophy

Keith L. Herrmann, Andrew D. McCulloch, and Jeffrey H. Omens

Whitaker Institute of Biomedical Engineering, University of California-San Diego, La Jolla, California 92093

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Alteration of hemodynamic loading induces remodeling that includes changes in myocardial properties and extracellular matrixstructure. We investigated the hypothesis that cardiac hypertrophydue to volume overload produces changes in myocardial diastolicmechanics and stiffness that are in part due to alterations inadvanced glycation end-product (AGE) collagen cross-linking. Ratsdeveloped volume overload induced by arteriovenous fistula (AVF).To assess the dependence of AGE cross-linking on mechanics, weprevented AGE formation by administering the drug aminoguanidine(AG) to one group of AVF rats (AG+AVF). Volume overload did notmodify collagen concentration. Right ventricular AGE cross-linkswere modestly elevated in AVF hearts but were significantly reducedby AG. AVF rats exhibited significantly increased septal AGE cross-linksthat were inhibited in the AG+AVF group. AVF-induced increasesin left ventricular longitudinal stiffness and septal circumferentialstiffness were prevented in AG+AVF hearts. Volume overload appearsto regionally modify AGE collagen cross-linking and stiffness,and AG treatment prevented these increases, demonstrating thatAGE cross-linking plays a role in mediating diastolic compliancein volume-overloadhypertrophy.

ventricle; strain; stress; material properties

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

DURING MYOCARDIAL HYPERTROPHY, the heart remodels in response to altered loading, and this remodeling includes changes inventricular geometry and tissue properties (14). Volume-overloadhypertrophy increases ventricular stiffness (11, 17) withoutsignificant changes in collagen content (11, 25). Collagenplays a significant role in passive cardiac muscle stiffness (21),and some studies implicate collagen cross-links as a significantdeterminant of chamber stiffness in the heart (1, 28). Previousstudies reported alterations in aortic compliance and ventricularchamber stiffness in association with the inhibition of enzymaticcollagen cross-linking (6, 19). Investigators also observeddiminished arterial and chamber compliance that correlated withan increase in nonenzymatic glycated collagen cross-links (2,36). In addition, there is evidence that myocardial collagencross-links may be elevated in response to volume-overload hypertrophy(15, 17).

Collagen formation includes enzymatic processes that create intra- and intermolecular cross-links. However, glucose and othersugars also act as cross-linking agents of the extracellular matrix(ECM). Collagen has a long biological half-life, and the levelof nonenzymatic glycosylation, or glycation, increases graduallywith aging (3) or in hyperglycemic conditions such as diabetes(24). Reducing sugars (glucose, fructose, etc.) bond to freeprotein amino groups and go through a series of reactions to forma class of heterogeneous, nonenzymatic sugar-amino adducts thatare called advanced glycation end-products (AGE) (3). AGE existin a nonreactive form as an irreversible, intermolecular covalentcross-link with other glucose-modified proteins (5, 34).

AGE modify and damage tissues in various ways in addition to forming cross-links (34). These modifications, and the cross-linkingactions of AGE, contribute to numerous clinical complicationsassociated with aging, diabetes, atherosclerosis, neuropathy,retinopathy, and renal failure (8, 34). Therefore, the investigationof disrupting AGE cross-links is of particular interest to thescientific and medical community. Currently, AGE disruption maybe achieved either by preventing their formation or by cleavingexisting AGE cross-links through specific drug interactions (8).One example is the compound aminoguanidine (AG), which preventsformation of fluorescent AGE products and the accumulation ofAGE collagen cross-links (5, 26).

This research investigated the hypothesis that cardiac hypertrophy due to volume overload induces changes in myocardial mechanicsand stiffness that are in part due to alterations in nonenzymaticAGE collagen cross-linking. Experimental rats developed volume-overloadhypertrophy due to arteriovenous fistula (AVF). To test the dependenceof nonenzymatic cross-linking on cardiac mechanics, we preventedthe formation of AGE cross-links by administering AG to rats for6 wk. We found that inhibition of AGE cross-links prevented someof the alterations in myocardial stiffness and passive mechanicsassociated with volumeoverload.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Volume overload and drug administration. All studies were performed according to the National Institutes of Health Institute Guide for the Care and Use of LaboratoryAnimals, and all experimental protocols were reviewed and approvedby the University of California-San Diego Animal Subjects Committee.Each rat was anesthetized via intraperitoneal injection (100 mg/kgketamine HCl, 8 mg/kg xylazine, and 2 mg/kg morphine). Chronicvolume overload was produced in 10-wk-old rats weighing ~300 gby creating an AVF between the aorta and vena cava in the abdomen(also termed an aortocaval fistula) (11). The aorta and venacava were isolated and exposed through a large abdominal incision(~5.0 cm) under sterile conditions. They were cross-clamped withclips posterior and anterior to the site of incision below therenal vessels. After an aortic incision, a fistula was createdthrough the common wall by passing a microsurgical suture throughthe shared wall and resecting a small piece of the vessel. Theaortic incision was sutured, and the clamps were removed. Themixture of arterial and venous blood in the vena cava was visualizedto check for shunt patency. The visceral organs were restored,and the abdominal muscle and skin openings were surgically closed.This procedure increases the preload on the heart by increasingthe filling volume and pressure and results in volume-overloadhypertrophy. The chronic volume overload progressed over a 6-wkperiod. A comparative group of AVF rats were given the AGE inhibitorAG (25 mg · kg body wt¹ · day¹) in daily doses via intraperitoneal injections. Weight-matchedrats were also included in the study as a controlgroup.

Heart isolation. Rat hearts were excised and isolated 6 wk after the AVF surgery for mechanical testing and biochemical analysis. After anesthesiaadministration, the rats were ventilated with room air and ECGleads were inserted. A Millar catheter (1.4-Fr) was inserted throughthe carotid artery and advanced retrograde toward the heart andinto the left ventricle (LV) to measure in vivo arterial and myocardialhemodynamics. The heart was then arrested and excised by openingthe chest via thoracotomy and injecting cardioplegic arrest solution[4.0 g/l NaCl, 4.44 g/l KCl, 1.0 g/l NaHCO₂, 2.0 g/l sucrose,3.0 g/l 2,3-butanedione monoximine, and 1,000 units heparin (10ml/l)] into the LV apex. The heart was immediately rinsed in coldcardioplegic solution, trimmed, andweighed.

Isolated heart inflation and data collection. The experimental rats were divided into two subgroups to investigate the mechanics of either the LV or the septum. The leftatrium was trimmed, and a small pointed, flared tube was insertedand pushed through the apex of the LV to drain the ventricle.The heart was slowly perfused with an aortic cannula under lowpressure with additional cardioplegic solution to flush the remainingblood. A balloon connected to a closed inflation system was placedin the LV (11). The mechanics of the ventricle were recordedby passively inflating isolated hearts and recording the pressure-volume(P-V) and pressure-strain relations with video-imaged surfacemarkers (11) (composed of titanium oxide; no. T8141, Sigma,St. Louis, MO). In the LV study group, these markers were placedon the epicardial LV free wall. Alternatively, in the septal studygroup, the right ventricular (RV) free wall was excised and markerswere placed on the exposed septum. The hearts were kept moistduring the studies. Pressure, volume, and timing signals wererecorded online directly to a computer, and surface markers wereimaged onvideotape.

Strain and stress calculation. Deformation of the ventricle was analyzed by calculating the homogenous strain on the surface of the LV or septal wall. Themethods are given in detail in previous publications (11). Two-dimensionalfinite strain was computed during passive inflation either onthe septal or LV free wall surface. The resulting strains, E_ij,are the three independent components of the two-dimensional Lagrangianstrain tensor referred to a zero-pressure state. The referencecoordinate system is chosen to align with the long axis of theheart; thus E₁₁ represents circumferential strain, E₂₂ representslongitudinal strain, and E₁₂ represents in-plane shearstrain.

Diastolic wall stress was calculated with an analytic model. The geometry was modeled as an axisymmetric truncated ellipsoidusing a three-dimensional prolate spheroidal shell and dimensionsmeasured from excised hearts. The reference state was the unloadedventricle with a finite initial volume and zero pressure. P-Vdata and epicardial strain ratios were used to simulate the passiveinflation of each rat heart. The average midwall circumferential(T₁₁) and longitudinal (T₂₂) wall stresses were calculated witha Mirsky formulation for midwall stress in an ellipsoid (23),where a and b are, respectively, the midwall semimajor and semiminoraxes of the prolate ellipsoid, P is the pressure, and h is thewall thickness

T<SUB>11</SUB> = <FR><NU>P<IT>b</IT></NU><DE><IT>h</IT></DE></FR><FENCE>1 − <FR><NU><IT>b</IT><SUP>2</SUP></NU><DE>2<IT>a</IT></DE></FR> − <FR><NU><IT>h</IT></NU><DE>2<IT>b</IT></DE></FR> + <FR><NU><IT>h</IT><SUP>2</SUP></NU><DE>8<IT>a</IT><SUP>2</SUP></DE></FR></FENCE>

T<SUB>22</SUB> = <FR><NU>P<IT>b</IT></NU><DE>2<IT>h</IT></DE></FR><FENCE>1 − <FR><NU><IT>h</IT></NU><DE>2<IT>b</IT></DE></FR></FENCE><SUP>2</SUP>

Stress-strain data were fit with an exponential curve (T = Ae^kE, where A is the stress intercept at zero strain) for each ratin each direction, and the myocardial stiffness coefficient (k)was taken as the exponential coefficient of the fitted trend,which is the slope of the linearized stress-strain relation (28,37).

Measurement of AGE. AGE content was determined based on the fluorescence assay methods of Monnier et al. (24) and Jyothirmayi et al. (18).First, frozen myocardial tissue was thawed and weighed. The tissuewas minced and homogenized in 3 ml of PBS. The homogenate wasthen centrifuged (3,000 g for 20 min), and the pellet was washedin 3 ml of PBS. After two repetitions, the pellet was extractedin 2 ml of 0.5 M acetic acid overnight at 4°C. After being spunagain, the precipitate was extracted in 2 ml of 1% pepsin in 0.5M acetic acid overnight at 4°C. The pepsin extraction was performedthree times. After the samples were spun, the remaining precipitatewas extracted in 2 ml of a solution containing 0.05% proteinaseK and 0.1% SDS overnight with low-speed shaking at 37°C. The sampleprecipitates were then extracted in 300 µl of 0.05% collagenaseVII (Sigma) in PBS. In addition, 1 µl each of chloroform and toluenewere added. These samples were incubated for 24 h at 37°C. Thesamples were centrifuged (1,000 g for 5 min), and the supernatantwas removed for analysis. Three 40-µl aliquots of the final supernatantwere each diluted with 100 µl of water for fluorescence measurementwith a SPECTRAmax microplate spectrofluorometer (Molecular Devices,Sunnyvale, CA). All fluorescence measures (370 nm excitation,440 nm emission) were corrected by subtracting the blank collagenaseVII sample fluorescence and averaged over the three readings.The remaining final supernatant was used for a colorimetric hydroxyprolinemeasurement, after which AGE content was calculated as arbitraryfluorescence units per milligram of collagen, and then normalizedto the average of control measurements for each group ofsamples.

Measurement of collagen content. Hydroxyproline concentration (a marker of collagen content) was determined by the colorimetric assay of Woessner (35). Thevolume of the remaining supernatant or the mass of the lyophilizedtissue was recorded and hydrolyzed in 20× volumes of 6 N HCl andleft overnight (18-24 h) in a heat block incubator (Fisher Scientific,Pittsburgh, PA) at 100°C. After being cooled in a dark place,the liquid sample was filtered into a 5- to 25-ml volumetric flaskwith Whatman no. 1 filter paper and brought to volume with methanol.A portion of the sample (1 ml) was placed in a porcelain dishand evaporated in a 60°C water bath. The dried sample was solubilizedin 1 ml of methanol and then evaporated two more times. Driedsamples were then resolubilized in 5-10 ml of water. After subsequentadditions of 1 ml each of chloramine T solution, 3.15 M perchloricacid, and para-dimethylaminobenzaldehyde solution, each sampleand five hydroxyproline standards were incubated in a water bathfor 20 min. Hydroxyproline concentrations of the samples werecalculated from the absorbance at a wavelength = 557 nm and thecomputed hydroxyproline standard curve by a spectrophotometer(Beckman Coulter, Fullerton, CA). Collagen concentration was calculatedby assuming that collagen weighs 7.25 times hydroxyproline andhas a molecular weight of 300,000.

Measurement of hydroxylysyl pyridinoline cross-links. The remaining hydrolyzate from the hydroxyproline procedure was prepared for hydroxylysyl pyridinoline (HP) cross-link determinationby following the methods of Skinner (31). Briefly, the remaininghydrolyzate was concentrated on a rotoevaporator, suspended ina slurry of cellulose and mobile phase, and applied to a cellulosecolumn. HP cross-links absorb into a cellulose bed and can beseparated from other amino acids by washing with mobile phase.HP was eluted from the column with water and again concentratedon a rotoevaporator, and pyridoxamine hydrochloride was addedas an internal standard. The degree of collagen cross-linkingwas assessed with the reverse-phase HPLC methods of Eyre et al.(12). Pyridoxamine and HP were detected by fluorescence spectrophotometry(excitation 295 nm, emission 395 nm), and cross-link values arereported as moles of HP per mole ofcollagen.

Statistics. Results presented reflect means ± SE per group. To test for significance between groups, one- or two-way ANOVA or ANOVA repeated-measuresanalysis was performed with Fisher's protected least-significant-differencepost hoccomparisons.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Surgery statistics and body weights. Volume overload was successfully induced in 67% of the rats in the chronic study. The rats with closed fistulas at the timeof postmortem inspection (33%) were discarded from the study.There was no difference in initial weight between AG+AVF (303± 5 g) and AVF (303 ± 4 g) rats. AG+AVF rats weighed less at theend of the 6-wk study (AG+AVF 367 ± 5 g, AVF 413 ± 10 g; P < 0.01).Subsequently, AG+AVF rats gained considerably less weight comparedwith AVF rats (AG+AVF 21 ± 2%, AVF 37 ± 4%; P < 0.01).

Hypertrophy and geometry. The overall heart weight-to-body weight ratio increased as expected because of chronic volume overload (Table 1; P < 0.01).Significant myocardial enlargement was observed in the LV, septum,and RV for both AVF groups compared with controls (Table 1).Volume overload produced the greatest relative hypertrophy inthe RV (76% larger than controls), followed by the LV (52%) andthe septum (34%). AG did not alter the hypertrophic response ofthe RV, septum, or LV to AVF (Table 1). Apex-to-base dimensionincreased in both groups after AVF, and the wall thickness-to-radiusratio decreased in both groups after AVF. However, wall thicknesswas similar among all three groups.

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Table 1. Myocardial weights and geometry

Hemodynamics. LV end-diastolic pressure more than doubled from control pressures in both AVF groups (control 2.0 ± 0.2 mmHg, AVF 4.9 ± 0.6mmHg, AG+AVF 6.3 ± 0.7 mmHg; P < 0.01) and was also accompaniedby an increase in peak systolic pressure (control 78.4 ± 4.9 mmHg,AVF 90.4 ± 4.4 mmHg, AG+AVF 97.6 ± 6.1 mmHg; P < 0.05). Pulsepressure measured in the aorta was nearly twice as large in AVFand AG+AVF rats compared with controls (control 21.0 ± 2.1 mmHg,AVF 39.2 ± 1.4 mmHg, AG+AVF 44.8 ± 3.6 mmHg; P < 0.01). Therewas no effect of AG on hemodynamics between the AVFgroups.

Collagen and cross-linking. Results of the collagen concentration analysis are shown in Table 2. There was no difference in LV or septum collagen concentrationamong the three experimental groups. RV collagen concentrationwas similar between control and AVF tissue but reduced in AG+AVFanimals (P < 0.01). In all rats and groups, the RV contained thehighest concentration of collagen, followed by the septum andthen the LV (P < 0.01). Absolute values of total hydroxyprolineare also included in Table 2.

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Table 2. Collagen concentration and total hydroxyproline in rat myocardium

Two types of collagen cross-linking were measured. LV enzymatic cross-linking (HP cross-linking) was similar among the threegroups (control 3.16 ± 0.28 mol HP/mol collagen, AVF 2.95 ± 0.39mol HP/mol collagen, AG+AVF 3.33 ± 0.22 mol HP/mol collagen).However, the regional variation in nonenzymatic AGE cross-linkingis illustrated in Fig. 1. LV nonenzymatic AGE cross-linking wassimilar in all groups. However, the AVF-induced increase in septalAGE cross-links (P < 0.05 vs. controls) was prevented in the AG+AVFgroup (P < 0.01 vs. AVF). RV AGE cross-links (data not shown)were slightly elevated in AVF hearts, but AGE accumulation wassignificantly reduced by AG treatment (P < 0.01 vs. AVF, P < 0.05vs. control).

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Fig. 1. Regional advanced glycation end-product (AGE) cross-linking in experimental groups. AGE cross-links were elevated in the septum of rats with arteriovenous fistula (AVF) but inhibited with aminoguanidine (AG) treatment. LV, left ventricle. $dagger$ P < 0.05 vs. controls; $Dagger$ P < 0.01 vs. AVF.

P-V curves. AVF and AG+AVF hearts exhibited LV P-V curves that were significantly shifted to the right of controls (Fig. 2; P < 0.01),depicting their larger LV volumes. There was no difference betweennontreated AVF and AG-treated AVF hearts with respect to theirdiastolic P-V characteristics.

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Fig. 2. LV chamber pressure-volume (P-V) curves measured during passive inflation. P-V values for AVF and AG+AVF hearts are similarly enlarged compared with the control curve (P < 0.01).

Stress, strain, and stiffness. Because the P-V curves represent global ventricular mechanics but the biochemical analysis showed alterations in AGE cross-linksonly on the septal wall, we measured pressure-strain relationsduring passive LV filling on the RV surface of the septum (Fig.3). AVF surgery with or without AG treatment had no statisticallysignificant effect compared with hearts of sham-operated ratson the relationship between pressure and strain in the circumferential,longitudinal, or shear directions on the septal wall.

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Fig. 3. Strains measured on the septal wall during passive inflation. Circumferential (E₁₁, A), longitudinal (E₂₂, B), and shear (E₁₂, C) strains were similar among experimental groups.

Because P-V and pressure-strain relations reflect the combined effects of changes in ventricular geometry and material properties,we used regional parameters (geometry, pressure, and strains)measured on the septum and LV free wall to estimate local stress-strainrelations. Passive septal circumferential (T₁₁-E₁₁) stress-straincurves exhibited significant differences among all three groups(Fig. 4). AG+AVF curves were shifted to the right of control curves.However, AVF stress-strain curves fell between the other two groupsand exhibited greater stiffness coefficients (Table 3; P < 0.01).Analysis of septal longitudinal (T₂₂-E₂₂) stress-strain curvesshowed that the AVF group exhibited a larger longitudinal stiffnesscoefficient (P < 0.01). The circumferential myocardial stiffnesscoefficient was increased in AVF rats compared with controls andattenuated in the AG+AVF group (Table 3). Likewise, longitudinalseptal stiffness mirrored the trends in T₂₂ curves, but thesechanges in longitudinal compliance were not statistically significant.Septal T₁₁-E₁₁ curves had larger initial linear slopes in thecontrol group compared with the AVF and AG+AVF groups (P < 0.01),possibly because of AVF-induced structural remodeling that reducedcircumferential compliance at low loads.

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Fig. 4. Diastolic stress-strain curves from the septal wall. The AVF circumferential stress-strain (T₁₁-E₁₁) curve (A) is significantly steeper (P < 0.01) and modestly shifted compared with the control curve. AG+AVF curves were also shifted (P < 0.05) but exhibited a shape similar to that of control curves. Longitudinal stress-strain (T₂₂-E₂₂) values (B) were consistent among all groups, but AVF curves were again significantly steeper than both control and AG+AVF curves (P < 0.05).

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Table 3. Myocardial stiffness coefficients

In contrast to LV longitudinal stiffness, LV circumferential myocardial stiffness was unaffected by AVF or AG treatment (Table3). The longitudinal stiffness coefficient in the LV free wallwas significantly increased in AVF rats compared with controls,and this change in myocardial compliance was almost completelyprevented in AG+AVF hearts (P < 0.05; Table 3). There was nodifference in initial linear slopes of LV stress-straincurves.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Summary of results. The purpose of this study was to investigate the hypothesis that nonenzymatic AGE collagen cross-links play a role in mediatingmyocardial stiffness in volume-overload hypertrophy in rats. Specifically,we postulated that inhibition of AGE cross-links would preventdecreases in compliance of the LV and septum in rats with volumeoverload. The main findings of this study are that 1) volume overloadappears to induce regional upregulation of AGE cross-linking inthe septum without modifying collagen concentration; 2) concomitantincreases in regional tissue stiffness in the septum may be aresult of these increased cross-links; and 3) inhibition of AGEformation by AG prevented alterations in myocardial compliance.Thus it appears that nonenzymatic AGE cross-links are at leastpartly responsible for increased myocardial stiffness in volume-overloadhypertrophy induced byAVF.

Collagen and cross-linking in volume overload. Collagen concentration values in volume overload were similar to those previously published for rats (11, 25). AG treatment(AG+AVF group) had no effect on collagen concentration in theLV and septum but did reduce collagen in the RV. This modificationof RV collagen may be due to the fact that the RV sustains a largeportion of the increased loading due to the overload and thusundergoes more extensive ECM remodeling. This augmented RV remodelingis also evident in the fact that the RV exhibited the largestrelative hypertrophy in both AVFgroups.

AGE cross-linking was significantly increased in the septum and modestly elevated in the RV but did not change in the LV.This heterogeneous cross-link remodeling may be due to the regionalvariation in loading experienced in the heart because of AVF-inducedvolume-overload hypertrophy. Although accumulation of AGE is usuallyassociated with prolonged exposure to hyperglycemic conditionssuch as diabetes or aging, other studies have observed AGE cross-linkchanges stimulated by altered hemodynamic loading in euglycemicconditions. For example, Norton and colleagues (28) concludedthat alterations in collagen cross-links were responsible forthe stiff myocardium associated with hypertension in spontaneouslyhypertensive rats when treatment increased collagen solubility(an indication of reduced cross-links) and diminished myocardialstiffness without modifying collagenconcentration.

Hypertrophy and remodeling. Our results suggest that AG did not affect global or regional hypertrophy compared with that in nontreated AVF rats. Previouschronic studies reported mixed results concerning the effect ofAG on heart weight or the heart weight-to-body weight ratio inrats (9, 20, 27). This variation may be due to dosage,length of exposure, or additional cardiac assaults in the rats.Our results also showed that AG had no effect on dilation or wallthinning compared with those in nontreated AVF rats. However,AG+AVF weight gain was considerably impaired over the 6-wk studycompared with that in nontreated AVF rats and may have influencedthe calculated weightratios.

Influence of cross-linking on cardiac mechanics. Previous studies demonstrated that myocardial compliance is altered by AGE cross-linking. Diabetes produced increased myocardialstiffness and AGE accumulation in rats; however, both stiffnessand AGE were inhibited with the administration of AG (27). Likewise,in diabetic dogs, elevated AGE accompanied increased LV chamberstiffness but drug administration with either AG (2) or metformin(18) prevented AGE formation and consequently decreased chamberstiffness.

In our study, AGE cross-linking appears to play a role in determining cardiac mechanics as evidenced by the alterations inmyocardial stress, strain, and stiffness that occur because ofchanges in cross-linking. Passive P-V characteristics in ratswith volume overload were not altered because of the inhibitionof AGE cross-links. On the basis of the regional measures of ECMstructure and function made in the present study, it is not surprisingthat the P-V curves were not sensitive to local changes in ECMor passive mechanics. Because P-V curves represent a global descriptionof ventricular mechanics, local changes in structure and functionmay not be reflected in measures of global passiveproperties.

LV circumferential strain was significantly increased in AVF rats compared with controls, but this increase was completelyprevented with cross-link inhibition (data not shown). These changesin mechanics do not appear, at first glance, to be associatedwith cross-linking because AGE cross-links were unchanged in theLV free wall. However, the changes in septal compliance may explainchanges observed in the LV free wall. For example, in AVF rats,the increase in circumferential septal stiffness may cause theincreased distension of the LV free wall (evidenced by elevatedE₁₁ strains) as a compensatory reaction to the volume overload.Moreover, circumferential septal stiffness returns to normal withAG treatment, as does the E₁₁ strain in the LV free wall in AG+AVFrats. The changes in septal and LV mechanics with the onset ofvolume overload and the reactions to cross-link inhibition demonstrateboth the local and regional compensatory interactions that occurin theheart.

There was a significant reduction in AGE cross-linking, along with a modest decrease in longitudinal stiffness (P = 0.06),in the septum of AG+AVF rats compared with the AVF group. Volumeoverload increased LV longitudinal stiffness in AVF rats, andthis change in compliance was also prevented by AG treatment.However, there was no change in AGE cross-links in the LV, sothis effect appears to be due to the mechanical interaction ofthe other regions of the heart, namely, the septum, in a mannersimilar to that describedabove.

Regional mechanics and ECM. Volume overload appears to regionally modify the loading on the heart and produce dissimilar remodeling responses throughoutthe myocardial tissue and ECM. For example, previous studies reportedchanges in tension development and relaxation that occurred inRV papillary muscles, but not in LV muscles, from rats with volumeoverload (22). It is well known that RV and LV filling affectthe pressure and compliance of the other ventricle in normal anddiseased states (30, 33). This LV-RV interaction may be largelydependent on septal stiffness (13). However, abnormal loadingin the heart can change septal, as well as ventricular, mechanics(30). In clinical hypertrophic cardiomyopathy, diastolic septalstiffness was found to be slightly higher than that of the LVposterior wall (4). In addition, aortic regurgitation resultedin LV volume overload and regional ischemia that produced septalhypertrophy and increased metabolism that was in response to greaterstress development in the septum compared with the LV (10).

Regional changes in mechanics may be due to regional remodeling of the ECM. Echocardiography showed that patients with hypertrophyexhibited abnormal motion in the septum and posterior wall andthat these regional abnormalities were strongly associated withaltered myocardial properties most likely due to the ECM (29).Spinale and colleagues (32) observed regional differences incollagen extractability within the normal LV free wall and regionalvariations in cross-link remodeling during the progression andregression of tachycardia-inducedcardiomyopathy.

Therefore, the heterogeneous response of AGE cross-links and myocardial remodeling reported in this study agree with previousobservations of regional remodeling and support the hypothesisthat altered loading in the heart initiates local myocardial andECM remodeling that subsequently modifies regional mechanics,such as strain and wall stress, in a nonhomogeneousmanner.

Actions of AG on hemodynamics. AG treatment did not change hemodynamic parameters from those in nontreated AVF rats. In general, the influence of AG on thecardiovascular system may be complicated because two of its targetsgenerate contrasting effects on hemodynamics, namely, collagencross-links, which may stiffen cardiovascular tissue, and nitricoxide (NO), which acts as a vasorelaxant. AG inhibition of theenzyme inducible nitric oxide synthase could theoretically preventNO from contributing beneficial effects on hemodynamics. In fact,there is growing evidence that AG does not affect parameters associatedwith this type of NO activity and actually may improve hemodynamicparameters itself (7, 16).

Study limitations. The results of this study are subject to some limitations. An analysis of RV mechanics was not obtained, and this preventeda complete investigation of AGE cross-linking influence in volume-overloadhypertrophy. The experimental and computational difficulties ofobtaining RV stresses hindered this analysis. Stress in the LVand septum was calculated as average wall stress based on an analyticmodel using a symmetric prolate ellipsoid. Factors such as residualstress were not included in this simple model analysis, and theycould play a role in altering the values of calculated wallstress.

There was no control group of animals treated only with AG in this study; however, others have already published such results.Previous chronic studies of 4, 6, and 18 mo reported no changesin body weight, kidney weight, mortality, aortic collagen andelastin content, myocardial hydroxyproline concentration, or myocardialcollagen fluorescence between normal and AG-treated rats (9,20, 27). More importantly, these same studies observed nodifference in mean blood pressure, systolic and diastolic pressure,cardiac output, heart rate, and, most notably, LV elastic stiffness.However, inconsistent results were reported in regard to changesin heart weight, LV weight, and the heart weight-to-body weightratio, as mentionedabove.

Another limitation was the lack of blood glucose data, which prohibited a thorough description of the glycemic conditionspresent in the experimental animals and impeded identificationof a possible candidate for AGE stimulation. Statistical strengthof the data analyses, in general, was weakened because of themodest number of animals in the experimental groups. Finally,there were no sham-operated animals, and therefore any effectof the surgery and long-term housing compared with chronic AVFrats could not be accountedfor.

In conclusion, this study provides a description of regional collagen and AGE cross-linking composition in volume-overloadhypertrophy. We investigated the hypothesis that regional variationsin passive myocardial mechanics are modulated by changes in localcollagen cross-linking. Specifically, we postulated that the inhibitionof nonenzymatic AGE cross-links would prevent changes in diastolicmechanics and myocardial stiffness due to volume-overload hypertrophy.Our results show that volume overload appears to induce heterogeneousalterations in AGE formation and myocardial stiffness in the myocardium.Furthermore, inhibition of AGE formation by AG in rats with volumeoverload prevented these decreases in myocardial compliance. Thusit appears that nonenzymatic AGE cross-links are at least partlyresponsible for increased myocardial stiffness in volume-overloadhypertrophy.

	ACKNOWLEDGEMENTS

The authors thank Dr. David Amiel and Fred Harwood [Department of Orthopaedics, University of California-San Diego (UCSD)]for assistance with the HP cross-link analysis. In addition, weare grateful to Dr. James Covell, Rish Pavelec, Zhuangjie Li,Troy Kalscheur, and Rachel Alexander (Department of Medicine,UCSD) for assistance with the chronic animal experiments and dataanalysis.

	FOOTNOTES

This study was supported by National Heart, Lung, and Blood Institute Grants HL-64321 and HL-54686 and a Whitaker FoundationBiomedical GraduateFellowship.

Address for reprint requests and other correspondence: J. H. Omens, 9500 Gilman Dr., Mail Code 0613J, La Jolla, CA 92039-0613(E-mail: jomens{at}ucsd.edu).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

First published December 5, 2002;10.1152/ajpheart.00168.2002

Received 27 February 2002; accepted in final form 27 November 2002.

	REFERENCES

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

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