Decreased hematopoiesis in bone marrow of mice with congestive heart failure

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Decreased hematopoiesis in bone marrow of mice with congestive heart failure

Per Ole Iversen¹, Per Reidar Woldbaek²^,³, Theis Tønnessen²^,³, and Geir Christensen²

¹ Institute for Nutrition Research, University of Oslo; ² Institute for Experimental Medical Research, and ³ Department of Cardiothoracic Surgery, Ullevål University Hospital, 0316 Oslo, Norway

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Patients with heart failure are predisposed to infections and anemia, possibly due to reduced hematopoiesis. The proinflammatorycytokine tumor necrosis factor- $alpha$ (TNF- $alpha$ ) is increased in heartfailure, and it inhibits normal hematopoiesis, partly due to apoptosisthrough the effector molecule Fas. We examined bone marrow progenitorcells of mice with heart failure induced by acute myocardial infarction.The fraction of progenitor cells in mice with heart failure wasonly ~40% of control. Measured with in vitro clonal assays, theproliferative capacity of the progenitor cells in mice with heartfailure was reduced to ~50% of control. Flow cytometry with specificmarkers revealed a threefold increase in apoptosis among progenitorcells from mice with heart failure. In these mice, TNF- $alpha$ /Fas expressionwas increased in bone marrow natural killer (NK) and T cells,and these lymphocytes showed increased cytolytic activity in vitroagainst progenitor cells. We conclude that the TNF- $alpha$ /Fas pathwayin lymphocytes is activated in the bone marrow during heart failure,which may play a pathogenic role in the observed decrease inhematopoiesis.

blood cells; bone marrow cells; immunity; myocardial infarction

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

DESPITE RECENT THERAPEUTIC advances, heart failure carries a poor prognosis, with acute myocardial infarction being a leadingcause of this debilitating disease (5). During progressionto overt heart failure, reduced cardiac output and concomitantneuroendocrine activation affect the functions of several organs.It has been observed that patients with severe heart failure areprone to infectious diseases and anemia (3). The reason forthis apparent depression of the hematopoietic system is not known,but one possibility is that the function of the bone marrow isaffected. However, whether a sustained decrease in the hematopoieticactivity occurs during development of heart failure has not beendetailed.

Recent evidence suggests that the proinflammatory cytokine tumor necrosis factor- $alpha$ (TNF- $alpha$ ) might play an important pathogenicrole in heart failure. It has been shown that the failing myocardiumexpresses elevated levels of both TNF- $alpha$ mRNA and TNF- $alpha$ protein(11, 20, 27, 29). TNF- $alpha$ also induced apoptosis among cardiomyocytes,and transgenic mice with cardiac-specific overexpression of TNF- $alpha$ developed cardiomyopathy (13, 24).

TNF- $alpha$ is a negative regulator of normal hematopoiesis in vitro, at least partly due to induction of the CD95/APO-1/Fas system,known to promote apoptosis among hematopoietic progenitor cells(4, 15, 18, 25). The various inhibitory effects of TNF- $alpha$ are pronounced in the cachectic state frequently noted among patientswith heart failure (14). Hence the increased TNF- $alpha$ involvedin heart failure might also repress normal hematopoiesis, possiblyvia Fas/Fas ligand activation. Interestingly, recent data suggestthat this Fas system might be involved in apoptosis of ischemiccardiomyocytes (10, 28). Therefore this study was conductedto test the hypothesis that bone marrow hematopoiesis is affectedduring heart failure. To this end we used mice with congestiveheart failure induced by acute myocardial infarction and examinedfunction, proliferation, and viability of their leukocytes aswell as the local expression of TNF- $alpha$ and Fas system among bonemarrowcells.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Animal preparation. The protocol was in accordance with the Norwegian National Committee for Animal Welfare Act, which closely conforms to theGuide for the Care and Use of Laboratory Animals [DHEW PublicationNo. (NIH) 85-23, Revised 1985, Office of Science and Health Reports,DRR/NIH, Bethesda, MD 20205]. We used 5- to 6-wk-old male BALB/cmice. Anesthesia was induced by injections of 0.2 ml (10 mg/ml)propofol (Diprivan, Zeneca, Macclesfield, Cheshire, UK) into thetail vein. After an anterior cervical midline incision was made,a tracheotomy was performed and a 20-gauge cannula was inserted.The animal was then connected to a rodent ventilator (model 874092,B. Braun, Melsungen, Germany) and given a mixture of 2% isofluranand 98% oxygen. A left thoracotomy was performed in the thirdintercostal space, and a silk suture was placed directly underneaththe left auricle in the interventricular groove. Acute myocardialinfarction was induced by ligation of the left coronary artery.Myocardial blanching was taken to signify that this artery wasoccluded. Perioperative mortality was 40%, comparable to thatobserved in other studies (6). In the sham-operated animalsthe left coronary artery was not occluded. The lungs were reexpandedby applying positive end-expiratory pressure (15 cmH₂O), and thethoracotomy and skin incision were closed with silk sutures. Theanimal was then ventilated with 100% oxygen before it was extubated.Postoperatively the animal was given 0.01 ml of the analgesicbupremorphine (0.3 mg/ml sc). Four to six weeks after primarysurgery, the animal was anesthetized and a 1.4-French micromanometer-tippedcatheter (model SPR-671, Millar Instruments, Houston, TX) wasplaced within the left ventricle via the left atrium for pressurerecordings. Then the animal was killed by cervical dislocationbefore the heart and lungs were removed, blotted dry, andweighed.

Determination of leukocyte numbers in blood and bone marrow. A blood sample was collected by cardiac puncture immediately before the mice were killed. A smear was made, stained with May-Grünwald-Giemsa,and differential counting was performed. We isolated granulocytesand mononuclear cells after hemolysis with NH₄Cl by density gradientcentrifugation (Lymphoprep, Nycomed, Oslo, Norway). The mononuclearcell suspension was stained with fluorescent monoclonal antibodies(PharMingen, San Diego, CA) directed against either the CD4, CD19,or pan-natural killer (NK) antigens to identify T, B, and NK cells,respectively, using flow cytometry (FACScan; Becton Dickinson,Mountain View, CA). The positive staining of cell populationswas identified using the profiles obtained with an irrelevantcontrol antibody to adjust for nonspecificstaining.

Bone marrow cells were collected postmortem from the femoral bone as previously described (2). Mononuclear cells were isolatedas described above and stained with fluorescent monoclonal antibodies(PharMingen) directed against the lymphocyte antigens listed aboveand the pan-leukocyte marker CD45, the monocyte/macrophage antigenCD14, and the progenitor cell antigen CD34 and a panel of lineage(Lin) marker antibodies (anti-Gr-1, anti-Thy1.2, anti-Mac-1, anti-CD4,anti-CD8a, anti-TER119) before flow cytometry. T and NK cellswere isolated from the bone marrow mononuclear cell suspensionby magnetic sorting using the MACS system (Miltenyi Biotech, BergishGladbach,Germany).

Measurement of oxygen consumption rate. The oxygen consumption rate of blood granulocytes was estimated from the changes in oxygen tension in a cell suspension (21).Briefly, after separation the granulocytes were suspended in Fisher'smedium containing 0.5% bovine albumin and adjusted to pH 7.35with 10 mmol/l HEPES buffer. One milliliter of the cell suspension(10 million cells) was enclosed in a chamber while being stirred.The oxygen tension was then measured continuously with a polarographicelectrode(MSE).

Assessment of colony formation by hematopoietic progenitor cells. CD34+ bone marrow cells were isolated from the bone marrow mononuclear cell suspension using the MACS system. To assay forcolony (>40 cells) formation, we plated these cells (100,000 cellsper plate) in either semi-solid methylcellulose medium and/orliquid medium (MethoCult/MyeloCult; StemCell Technologies, Vancouver,BC, Canada) according to the instructions of the manufacturer.The cells grew for either 10 days (short-term colony formation)or 6-8 wk (long-term colony formation) (9). Subtypes of colonieswere identified after supravital staining. In a separate set ofexperiments we harvested cells from the 10-day colonies and assayedtheir clonogenic properties by reculturing them for another 10days. Briefly, cells were harvested from 10-12 different primarycolonies, resuspended, and then plated in the semi-solid mediumto develop into secondary colonies, as described (17).

Quantification of apoptosis. The fraction of apoptotic CD34+ cells was examined with both flow cytometric assessment of hypodiploid DNA stained with propidiumiodide (19) and flow cytometric detection of surface expressionof phosphatidylserine on apoptotic cells with annexin-V (ApoptosisDetection Kit, R&D Systems, Minneapolis,MN).

Cytokine measurement, RNAse protection assay, and Western blotting. The concentration of circulating TNF- $alpha$ was determined in plasma using and ELISA kit according to the instructions of the manufacturer(sensitivity >5 pg/ml; Quantikine, R&D Systems). We determinedmRNA for TNF- $alpha$ , interleukin (IL)-1 $beta$ , and IL-6 among sorted (MACSsystem) populations of T, NK, and CD34+ cells using RNAse protectionassays after extraction of total RNA, as detailed (12). GAPDH-mRNAwas used as an internal control. Western blotting with an anti-Fasligand antibody (PharMingen) was used to detect the Fas ligandprotein in these cell populations (8).

Statistics. For each mouse, the individual assays were performed in triplicate, and the corresponding median value from each mouse wasused to calculate the means and SE for either the mice with heartfailure (n = 8) or the sham-operated mice (n = 8). Differenceswere evaluated with two-tailed Wilcoxon's test for unpaired samplesand considered statistically significant for P < 0.05.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Development of congestive heart failure. Figure 1, bottom, shows fibrosis as well as a pronounced dilatation of the left ventricular myocardium of a mouse studied6 wk after ligation of the left coronary artery, indicating alarge infarcted area. Furthermore, at this time point, lung weight-to-bodyweight ratio was significantly higher in mice with myocardialinfarction compared with the sham-operated mice: 7.9 vs. 6.2 mg/g(P < 0.05). Moreover, left ventricular end-diastolic pressurein mice with myocardial infarction and the sham-operated miceaveraged 5.3 and 3.2 mmHg (P < 0.05), respectively.

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Fig. 1. Histological sections of hearts studied 6 wk after surgery of sham-operated mice (top) and of mice with ligation of the left coronary artery (bottom). The sections were stained with hematoxylin and eosin, magnification ×20.

Hematological changes in mice with heart failure. The concentrations of blood leukocytes and their subsets in mice with heart failure were not significantly different fromthose observed in the sham-operated animals (data not shown).The hemoglobin concentration was significantly lower in mice withheart failure compared with the sham-operated animals: 10.4 vs.13.6 g/100 ml (P < 0.05), respectively. Although we could notfind any differences in the numbers of mature leukocytes sampledfrom the bone marrow of mice with heart failure compared withsham-operated mice, the numbers of progenitor cells, detectedas either CD34+ cells or Sca-1+/Lin $-$ cells, were markedly reducedin mice with heart failure (Table 1).

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Table 1. Bone marrow cytograms

We also studied the function of blood granulocytes by measuring their oxygen consumption rate. The function of granulocytessampled from mice with heart failure was impaired, their oxygenconsumption rate being 22.4 compared with 39.6 nmol · l O₂¹ · min¹ (P < 0.05) in granulocytes from sham-operatedmice.

Reduced long-term colony formation by bone marrow progenitor cells of mice with heart failure. To examine the proliferative capacity of early bone marrow progenitor cells, we plate sorted CD34+ cells in semi-solid mediumand assayed their growth as formation of colonies during eithera 10-day or a 6- to 8-wk period. There were no significant differencesin colony numbers obtained after 10 days between the two animalgroups (Table 2). After 6-8 wk of growth, a substantial reductionof all subsets of colonies occurred when mice with heart failurewere compared with sham-operated mice (Table 2). In line withthis, a lower number of long-term colony initiating cells (i.e.,early, noncommitted progenitor cells) was detected in mice withheart failure than in sham-operated mice: 10 vs. 58 per 10⁶ inoculated CD34+ cells (P < 0.05). Also corroborating these findingswere the results of the recloning experiments. Here the numberof secondary colonies of mice with heart failure was much smallerthan those of the sham-operated mice when assayed after another10 days in methylcellulose culture (Fig. 2).

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Table 2. Formation of CFU by bone marrow progenitor cells

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Fig. 2. Reduced proliferation of bone marrow progenitor cells in mice with heart failure. The cells were harvested after 10 days in the primary colony assays and then recultured for another 10 days before the colony numbers of these secondary cultures were counted. Values are the numbers of clonogenic cells (i.e., the numbers of secondary colonies) per primary colony and given as means + SE, n = 8. *P < 0.05 for mice with heart failure compared with sham-operated mice.

Apoptosis of bone marrow progenitor cells is enhanced in mice with heart failure. To further study the mechanism underlying the reduced numbers of progenitor cells in mice with heart failure, we examinedthe apoptotic fraction among sorted bone marrow-derived CD34+cells using propidium iodide labeling and annexin-V staining.With these two independent assays we could clearly demonstrateincreased apoptosis of CD34+ cells collected from mice with heartfailure (Fig. 3). We could not detect any significant differencein the percentage of cells stained with either propidium iodideor annexin-V in either mice with heart failure or in the sham-operatedmice.

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Fig. 3. Increased apoptosis in situ of bone marrow progenitor cells in mice with heart failure. The percentage of apoptotic cells was determined with flow cytometry of cells labeled with either propidium iodide (PI) or annexin-V. Values are the means + SE, n = 8. *P < 0.05 for mice with heart failure compared with sham-operated mice.

We examined the cytotoxic ability of bone marrow T and NK cells in vitro by coculturing these cells from sham-operated miceor from mice with heart failure with CD34 progenitor cells collectedfrom bone marrow of intact, syngenic mice. Figure 4 shows thatT cells (Fig. 4A) and NK cells (Fig. 4B) from mice with heartfailure more efficiently induced apoptosis among normal CD34 hematopoieticprogenitor cells than lymphocytes from sham-operated mice.

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Fig. 4. Increased apoptosis of CD34 hematopoietic progenitor cells in vitro by T cells (A) and natural killer (NK) cells (B). The percentage of apoptotic cells was determined with flow cytometry of cells labeled with either PI or annexin-V. Values are the means + SE, n = 8. *P < 0.05 for mice with heart failure compared with sham-operated mice.

Increased expression of TNF- $alpha$ and Fas ligand in bone marrow lymphocytes from mice with heart failure. The increase in apoptosis of the bone marrow progenitor cells could result from increased TNF- $alpha$ /Fas pathway locally withinthe bone marrow. We therefore studied whether the expression ofthese molecules was increased in bone marrow lymphocytes. Figure5A shows that, among the mice with heart failure, TNF- $alpha$ mRNA synthesiswas substantially increased in sorted NK and T cells. The relativeTNF- $alpha$ mRNA level in the T cells was significantly higher thanin the NK cells in mice with heart failure, whereas no differencewas detected in the sham-operated mice. The concentrations ofcirculating TNF- $alpha$ were 19.5 and 7.7 pg/ml (P < 0.05) in the micewith heart failure and in the sham-operated group, respectively.We could not detect either IL-1 $beta$ - or IL-6 mRNA in any cell type,and no TNF- $alpha$ mRNA was observed in CD34+ cells (data not shown).Enhanced levels of the Fas ligand protein were present withinNK and T cells of the mice with heart failure (Fig. 5B). Flowcytometric analysis did not reveal any differences in surface-boundFas ligand among either NK or T cells when mice with heart failurewere compared with sham-operated mice (data not shown). This indicatesthat the increased level of Fas ligand protein (Fig. 5B) was primarilylocalized within the cytoplasmic compartment. Fas ligand was notdetectable within the CD34+ population (data not shown), and theexpression of Fas receptor on these cells was apparently unchangedwhen mice with heart failure were compared with sham-operatedmice (Fig. 6).

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Fig. 5. Increased Fas ligand and TNF- $alpha$ in bone marrow lymphocytes in mice with heart failure. A: Western blot of Fas ligand protein among T and NK cells showing the expected 3.2-kDa band. One of eight representative experiments is shown. B: tumor necrosis factor (TNF)- $alpha$ mRNA levels were estimated with an RNAse protection assay. Values are given relative to the mRNA levels for the internal GAPDH standard and presented as means + SE, n = 8. *P < 0.05 for mice with heart failure compared with sham-operated mice.

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Fig. 6. Unaltered Fas expression on bone marrow progenitor cells in mice with heart failure. Flow cytometric profiles showing the levels of Fas receptor surface expression on CD34+ cells collected from the bone marrow. One of eight representative experiments is shown.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

In this study we demonstrated anemia and impaired function among blood granulocytes as well as reduced numbers and decreasedviability among immature bone marrow progenitor cells in micewith congestive heart failure after acute myocardial infarction.In addition to these novel findings, we showed that the TNF- $alpha$ /Fasdeath molecules were upregulated in bone marrow-derived lymphocytesof affectedanimals.

Congestive heart failure after myocardial infarction in the mouse is characterized by left ventricular dilatation and pulmonaryedema (6, 23). In the present study the infarcted area wasexamined immediately postmortem to ensure that only mice withuniform-sized infarcted hearts were included. Furthermore, micewith myocardial infarction had pleural effusion and pulmonaryedema with a consistent increase in lung weight, indicating thatthese mice had developed a marked congestive heart failure. Moreover,the observed increase in left ventricular end-diastolic pressurein mice with myocardial infarction was in line with other studies(6, 23).

Heart failure is a serious condition that affects the functions of several organs. However, whether the bone marrow activitycan be affected has not yet been systematically investigated.In the present study we observed a marked reduction in the numberof hematopoietic progenitor cells recorded with three independentmethods: 1) flow cytometric assessment of bone marrow cells labeledwith specific monoclonal antibodies to enumerate CD34+ or Sca-1+/Lin $-$ cells; 2) proliferation assays with reculturing of colony-formingcells; and 3) hematopoietic progenitor cells cultured for as longas 6-8 wk. Notably, the observed hematopoietic defect must haveoccurred at an early stage of blood cell formation, because alltested cell lineages were affected. The blood concentrations ofleukocytes did not change with the establishment of heart failure.This is probably not the result of an increased differentiationcapacity among the progenitor cells, because the number of cellswithin the individual colonies did not differ between sham-operatedmice and mice with heart failure (data not shown). Alternatively,the unchanged blood concentration of leukocytes in mice with heartfailure might reflect a changed distribution of circulating andmarginated leukocytes and/or that most mature leukocytes neverleave the bone marrow, as has been shown for neutrophilic granulocytes(16). Possibly, the pools of circulating and marginated matureleukocytes suffice as immune defense against minor infectionsin heart failure, but they may become too small to mount a sufficientlyvigorous response to combat a prolonged infection efficiently.In addition, we found a reduced oxygen consumption rate amongblood granulocytes of mice with heart failure, indicating an impairedability to form, for example, reactive oxygen compounds necessaryfor mounting an adequate inflammatoryresponse.

With the use of two independent markers of apoptosis using flow cytometry, we consistently demonstrated an increased apoptoticrate in situ among bone marrow progenitor cells from mice withheart failure. This finding was confirmed with purified effectorlymphocytes and CD34 cells in vitro. Our findings suggest thatthe hematopoietic activity of the bone marrow is markedly suppressedin heart failure, possibly due to increased activity of the TNF- $alpha$ /Fasdeath machinery in T and NK cells locally in the bone marrow.How the TNF- $alpha$ /Fas system may interact in this context is unknown.Our data, showing an upregulation of both cytoplasmic Fas ligandand TNF- $alpha$ in lymphocytes and unaltered expression levels in CD34+cells, suggest an increased activation of bone marrow-derivedlymphocytes and not necessarily any change in the progenitor cellpopulation itself. The discrepancy between cytoplasmic and surfacelevels of Fas remains to be fully explained. Possibly the increasedcytoplasmic level reflects increased synthesis of Fas ligand moleculesthat can be secreted into the bone marrow microenvironment toreach the target cells. Presently it is not possible to measurelocal interstitial concentrations of Fas ligand in situ in thebonemarrow.

How TNF- $alpha$ exerts its effects on cardiomyocytes and hematopoietic progenitor cells remains to be fully explained. There isstrong evidence that TNF- $alpha$ is a major inducer of the Fas/Fas ligandknown to inhibit hematopoietic activity in various settings (4,15, 18, 25), and recent data also indicate that the TNF- $alpha$ /Faspathway can be activated in the ischemic myocardium (10, 28).Others have suggested that the negative inotropic effects of TNF- $alpha$ might be due to activation of the sphingomyelinase pathway (22).Whether this inhibitory mechanism operates within the hematopoieticsystem during increased TNF- $alpha$ activity is, however, not known.Moreover, TNF- $alpha$ reportedly acts as a repressor of cardiomyocytefunction via blunting of adrenergic stimulation (7). In linewith this, murine bone marrow progenitor cells reportedly expressadrenergic receptors, indicating a modulating role of catecholaminesin hematopoiesis (1). To this end one cannot exclude the possibilitythat the activation of the autonomous nervous system that accompaniesthe failing heart could repress hematopoietic activity. Althoughthe bone marrow innervation apparently plays no regulatory roleduring baseline hematopoiesis in intact animals (2), we foundthat patients with a complete spinal cord injury had impairedhematopoiesis in decentralized bone marrow where the input fromthe autonomic nervous system is altered (9).

In addition to TNF- $alpha$ , the vasoactive cytokine endothelin and the proinflammatory cytokines IL-1 $beta$ and IL-6 may be involvedin the pathogenesis of myocardial dysfunction (20, 26). Itis, however, not likely that locally derived IL-1 $beta$ or IL-6 willhave an impact on hematopoiesis in heart failure, because theywere not expressed in bone marrow NK and T cells from our micewith heartfailure.

Finally, altered local hemodynamics within the bone marrow microenvironment could perturb hematopoiesis. We have, however,been unable to demonstrate any changes in either bone marrow bloodflow, interstitial fluid pressure, or cellular oxygenation inrats with a similar postinfarction congestive heart failure (unpublishedobservations).

The present study showing a depressed hematopoietic activity during the development of heart failure might help explain whypatients with heart failure are predisposed to infections andanemia.

Perspectives

The heart failure syndrome represents a serious disorder that affects the function of several vital organs, such as the heartitself and the kidneys. The present investigation using an invivo model indicates that heart failure also affects bone marrowfunction. How this dysregulation comes about remains to be fullyestablished. Our study shows that the TNF- $alpha$ /Fas pathway is activatedin the bone marrow in mice with heart failure. This finding suggeststhat local production of mediators in the bone marrow induceschanges in hematopoiesis in a condition that is considered tobe primarily a hemodynamic disorder. It is possible that alterationsin the autonomous nervous system or circulating factors will emergeas important links between circulatory disturbances in heart failureand local factors affecting bone marrow function. Further elucidationof the mechanisms by which heart failure influences bone marrowfunction may allow development of novel therapeutic strategies.If studies in patients with heart failure reveal that the TNF- $alpha$ /Faspathway plays an important role in depression of the hematopoieticsystem observed in this disease (3), novel drugs targeted tointeract with this pathway may prove beneficial in thesepatients.

	ACKNOWLEDGEMENTS

We thank H. B. Benestad for critical reading of themanuscript.

	FOOTNOTES

This study was financed by The Throne Holst Foundation, The Norwegian Cancer Society, Anders Jahre's Fund for the Promotionof Science, and The Norwegian ResearchCouncil.

Address for reprint requests and other correspondence: P. O. Iversen, Institute for Nutrition Research, PO Box 1046 Blindern,0316 Oslo, Norway (E-mail: poiversen{at}hotmail.com).

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.

Received 18 June 2001; accepted in final form 31 August 2001.

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Anaemia and heart failure
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Increased syndecan expression following myocardial infarction indicates a role in cardiac remodeling
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P. van der Meer, A. A. Voors, E. Lipsic, W. H. van Gilst, and D. J. van Veldhuisen
Erythropoietin in cardiovascular diseases
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K. Schroecksnadel, B. Wirleitner, D. Fuchs, W. Steinborn, P. Ponikowski, S. Anker, P. van der Meer, W. H. van Gilst, D. J. van Veldhuisen, J. Ezekowitz, et al.
Anemia and Congestive Heart Failure * Response
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The effect of correction of anaemia in diabetics and non-diabetics with severe resistant congestive heart failure and chronic renal failure by subcutaneous erythropoietin and intravenous iron
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				J. N. Nanas, C. Matsouka, D. Karageorgopoulos, A. Leonti, E. Tsolakis, S. G. Drakos, E. P. Tsagalou, G. D. Maroulidis, G. P. Alexopoulos, J. E. Kanakakis, et al. Etiology of Anemia in Patients With Advanced Heart Failure J. Am. Coll. Cardiol., December 19, 2006; 48(12): 2485 - 2489. [Abstract] [Full Text] [PDF]

				A. S. Go, J. Yang, L. M. Ackerson, K. Lepper, S. Robbins, B. M. Massie, and M. G. Shlipak Hemoglobin Level, Chronic Kidney Disease, and the Risks of Death and Hospitalization in Adults With Chronic Heart Failure: The Anemia in Chronic Heart Failure: Outcomes and Resource Utilization (ANCHOR) Study Circulation, June 13, 2006; 113(23): 2713 - 2723. [Abstract] [Full Text] [PDF]

				Y.-D. Tang and S. D. Katz Anemia in Chronic Heart Failure: Prevalence, Etiology, Clinical Correlates, and Treatment Options Circulation, May 23, 2006; 113(20): 2454 - 2461. [Full Text] [PDF]

				D. O. Okonko, D. J. Van Veldhuisen, P. A. Poole-Wilson, and S. D. Anker Anaemia of chronic disease in chronic heart failure: the emerging evidence Eur. Heart J., November 1, 2005; 26(21): 2213 - 2214. [Full Text] [PDF]

				P. O. Iversen and H. Wiig Tumor Necrosis Factor {alpha} and Adiponectin in Bone Marrow Interstitial Fluid from Patients with Acute Myeloid Leukemia Inhibit Normal Hematopoiesis Clin. Cancer Res., October 1, 2005; 11(19): 6793 - 6799. [Abstract] [Full Text] [PDF]

				K. Caiola and J. W. Cheng Use of Erythropoietin in Heart Failure Management Ann. Pharmacother., December 1, 2004; 38(12): 2145 - 2149. [Abstract] [Full Text] [PDF]

				A J S Coats Anaemia and heart failure Heart, September 1, 2004; 90(9): 977 - 979. [Full Text] [PDF]

				H. Wiig, E. Berggreen, B. A. S. Borge, and P. O. Iversen Demonstration of altered signaling responses in bone marrow extracellular fluid during increased hematopoiesis in rats using a centrifugation method Am J Physiol Heart Circ Physiol, May 1, 2004; 286(5): H2028 - H2034. [Abstract] [Full Text] [PDF]

				A. V. Finsen, P. R. Woldbaek, J. Li, J. Wu, T. Lyberg, T. Tonnessen, and G. Christensen Increased syndecan expression following myocardial infarction indicates a role in cardiac remodeling Physiol Genomics, February 13, 2004; 16(3): 301 - 308. [Abstract] [Full Text] [PDF]

				P. van der Meer, A. A. Voors, E. Lipsic, W. H. van Gilst, and D. J. van Veldhuisen Erythropoietin in cardiovascular diseases Eur. Heart J., February 2, 2004; 25(4): 285 - 291. [Abstract] [Full Text] [PDF]

				K. Schroecksnadel, B. Wirleitner, D. Fuchs, W. Steinborn, P. Ponikowski, S. Anker, P. van der Meer, W. H. van Gilst, D. J. van Veldhuisen, J. Ezekowitz, et al. *Anemia and Congestive Heart Failure Response** Circulation, August 12, 2003; 108 (6): e41 - e42. [Full Text] [PDF]

				D. Silverberg Outcomes of anaemia management in renal insufficiency and cardiac disease Nephrol. Dial. Transplant., June 1, 2003; 18(suppl_2): ii7 - ii12. [Abstract] [Full Text] [PDF]

				J. A. Ezekowitz, F. A. McAlister, and P. W. Armstrong Anemia Is Common in Heart Failure and Is Associated With Poor Outcomes: Insights From a Cohort of 12 065 Patients With New-Onset Heart Failure Circulation, January 21, 2003; 107(2): 223 - 225. [Abstract] [Full Text] [PDF]

				D. S. Silverberg, D. Wexler, M. Blum, J. Z. Tchebiner, D. Sheps, G. Keren, D. Schwartz, R. Baruch, T. Yachnin, M. Shaked, et al. The effect of correction of anaemia in diabetics and non-diabetics with severe resistant congestive heart failure and chronic renal failure by subcutaneous erythropoietin and intravenous iron Nephrol. Dial. Transplant., January 1, 2003; 18(1): 141 - 146. [Abstract] [Full Text] [PDF]

				J. M. Edelberg Auto Repair on the Aging Stem Cell Superhighway Sci. Aging Knowl. Environ., September 4, 2002; 2002(35): pe13 - 13. [Abstract] [Full Text]