Perhexiline For Treating Chronic Heart Failure

Abstract

Disclosed are methods for the treatment of chronic heart failure, comprising administering to an animal in need thereof an effective amount of perhexiline, or a pharmaceutically acceptable salt thereof, to treat said chronic heart failure. The chronic heart failure may be non-ischaemic or ischaemic. Also disclosed is the use of perhexiline in the manufacture of a medicament to treat chronic heart failure, including chronic heart failure of a non-ischaemic origin and chronic heart failure of an ischaemic origin.

Description

The invention relates to a method and means for treating chronic heart failure, including the treatment of chronic heart failure of a non-ischaemic origin or an ischaemic origin.

Chronic heart failure (CHF) is associated with considerable morbidity and mortality despite recent advances in heart treatments. There are a number of aetiological conditions that ultimately result in chronic heart failure including coronary artery disease, different cardiomyopathies, hypertension, or valvular diseases. A detailed characterization of chronic heart failure as a clinical syndrome may be found in Hunt S A, Baker D W, Chin M H, Cinquegrani M P, Feldman A M, Francis G S, Ganiats T G, Goldstein S, Gregoratos G, Jessup M L, Noble R J, Packer M, Silver M A, Stevenson L W. ACC/AHA guidelines for the evaluation and management of chronic heart failure in the adult: a report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines (Committee to Revise the 1995 Guidelines for the Evaluation and Management of Heart Failure). 2001. American College of Cardiology (http://www.acc.org/clinical/guidelines/failure/hf_index.htm).

Coronary artery disease (obstruction or blockage of the arteries of the heart) leads to ischaemia; this is characterised by a lack of blood supply to tissues; in this case the heart. This lack of this essential oxygen and nutrients can result in the tissue becoming impaired or permanently damaged. Once damaged the cardiac tissue is unable to perform its function. As such, the strength and efficiency of the heart muscle is reduced (this is technically termed left ventricular systolic dysfunction and results in a reduced ejection fraction; a measure of the pumping capacity of the heart). In addition to its ability to damage the heart muscle; cardiac ischaemia is frequently though not invariably identified by the physical symptom of angina (in some cases—ischaemia may occur without the correlate of anginal chest pain). Angina typically occurs under circumstances that would be expected to increase the hearts workload; resulting in an increased requirement for energy. This increased energy requirement necessitates increased oxygen provision that cannot be provided in the presence of arterial blockage; causing relative ischaemia and hence pain. Exercise is a good example of this, where the output of the heart is increased but the blood supply does not match this increase in performance and thus some of the heart tissue becomes ischaemic resulting in pain. This ischaemia, despite causing pain need not invariably result in irreversible heart damage and is not invariably related to pump dysfunction. Although ischaemia can cause both angina and heart failure, the exact manifestation of ischaemia relates to its severity and time course. Ultimately ischaemia as an inciting influence for heart failure is dissociable from its capacity to cause angina; they may or may not co-exist.

However, a lack of blood supply is only one of the many causes for cardiac pump impairment. Other reasons include cardiac arrhythmias (abnormal heart electrical rhythms), hypertension (high blood pressure), valve diseases, infections, toxins or impairment in the nervous stimulation of the heart to name but a few.

While these initial insults to the heart are diverse in character and severity, their common feature is that they cause either damage to heart muscle cells (myocytes) or at least impair their ability to contract. This results in left ventricular systolic dysfunction. It is this common feature that triggers the cascade that results in the stereotyped and distinct state of chronic heart failure. As discussed in “Mechanisms and Models in Heart Failure: A Combinatorial Approach”, by Douglas L. Mann, M D, Circulation, 1999; pages 999-1008 and in “Drug Therapy: The Management of Chronic Heart Failure”, by Jay N. Cohn, MD, New England Journal of Medicine 1996; pages 490-498), heart failure may be viewed as a progressive disorder that is initiated after an index event either damages the heart muscle, with a resultant loss of functioning cardiac myocytes, or alternatively disrupts the ability of the myocardium to generate force, thereby preventing the heart from contracting normally. This index event may have an abrupt onset, as in the case of a myocardial infarction (heart attack), it may have a gradual or insidious onset, as in the case hemodynamic pressure or volume overloading, or it may be hereditary, as in the case of many of the genetic cardiomyopathies.

Regardless and irrespective of the diverse nature of the inciting event, the feature that is common to all of these index events is that they all, in some manner, produce a decline in pumping capacity of the heart. Following the initial decline in pumping capacity of the heart, acutely, patients may become very symptomatic; they may be minimally symptomatic or may even remain asymptomatic. However, the decreased pump capacity generally results in a diminished cardiac output. This chronically activates the neurohumoral system, particularly the sympathetic nervous system, the renin-angiotensin-aldosterone system, and potentiates the release of vasopressin.

Although in the short term these adaptations are beneficial due to their capacity to maintain blood flow to vital organs; in the long term, these reflexes have deleterious effects and ultimately result in cardiac remodelling (FIG. 1). This remodelling is the central stereotyped feature of CHF irrespective of the inciting influence and is manifest at the macroscopic level (visible to the eye) by dilatation of the heart chambers. However there is also corresponding remodelling at the molecular and the cellular level. These include changes in cellular transcription (the genetic programmes determining cellular function) and the resulting cellular pathways. One aspect of cellular function that is altered in chronic heart failure is cellular metabolism and energy production.

The common unified programme of the failing heart irrespective of the inciting insult thus includes chronic energy starvation. It has been postulated that these energy changes are not simply just a feature of CHF but are of mechanistic importance in chronic heart failure. The failing heart is characterized by a marked change in substrate preference away from fatty acid metabolism toward glucose metabolism. Glucose is a more efficient cellular fuel and this particular adaptation may therefore be an adaptive feature of chronic heart failure—partially mitigating the effect of energy deficit. It therefore follows that augmentation of “metabolic remodelling” is a potential target in chronic heart failure; however to date there has been a paucity of even animal data to confirm this assertion.

Perhexiline (2-(2,2-dicyclohexylethyl) piperidine) is a known anti-anginal agent that operates principally by virtue of its ability to shift metabolism in the heart from free fatty acid metabolism to glucose, which is more energy efficient. Aside from being used for the treatment of angina as a manifestation of ischaemia (in patients who may or may not coincidentally have heart failure), there is no record of using perhexiline to treat instances of non-ischaemia and certainly no known use of this drug to treat instances of heart failure independent of angina. Phrased alternatively; while perhexiline has been used to treat patients with angina and ischaemia at the point where this may be an inciting influence for heart failure as demonstrated by arrow (a) in FIG. 1, (which therefore may or may not be associated with active ischaemia-related pump dysfunction or ischaemia-related congestive cardiomyopathy); there has never been a suggestion that perhexiline may be useful in the modification of chronic metabolic remodelling in the distinct stereotyped phenotype of chronic heart failure as demonstrated by arrow (b) in FIG. 1.

With further reference to FIG. 1, it is apparent that there is an inciting phase of heart failure, which is due to diverse initiating influences. While completely unrelated to one another, these diverse influences all result in pump failure and left ventricular systolic dysfunction. Irrespective of inciting influence, this pump failure initiates an initially adaptive but ultimately partially maladaptive remodelling. This chronic remodelling is a stereotyped molecular, cellular and macroscopic phenomenon, and the central cause of eventual progressive chronic heart failure. Chronic heart failure remodelling ultimately leads to a vicious cycle of detrimental events. Part of the chronic heart failure phenotype is energetic deficiency and a shift in cellular metabolism away from fatty acid metabolism to glucose metabolism.

Hitherto, perhexiline has been used as an anti-ischaemic agent at juncture a, the inciting phase; although even at this stage it has not been used explicitly as an anti-failure agent. The present invention postulates that metabolic manipulation with perhexiline is effective in modifying not an inciting influence; but rather the common programme of the chronic heart failure state; hence this invention postulates a role for treating chronic heart failure at the distinct juncture b.

The present invention is thus based on the hypothesis that perhexiline-induced metabolic modification may be beneficial to treatment of the stereotyped chronic heart failure state irrespective of its effect on the inciting aetiology. The corollary of this assertion would be that if indeed the effect of perhexiline is as a metabolic modifier of CHF rather than a simple anti-ischaemic agent; its benefit in both ischaemically-induced CHF and non-ischaemically induced CHF would be similar. The invention is supported by the first clinical data to show that any metabolic modifier (perhexiline in this case) is capable of improving human chronic heart failure; furthermore the hypothesis is supported by the finding that the benefit of perhexiline in patients having ischaemic or non-ischaemic heart failure as assessed by improvements in a number of key indicators associated with chronic heart failure, was remarkably similar.

STATEMENTS OF INVENTION

According to a first aspect of the present invention, there is provided a method of treating chronic heart failure, which comprises administering to an animal in need thereof an effective amount of perhexiline, or a pharmaceutically acceptable salt thereof, to treat said chronic heart failure. The animal is preferably a mammal and most preferably a human.

In one embodiment, said chronic heart failure may be chronic heart failure as a result of an initial inciting influence of ischaemia.

In another embodiment, said chronic heart failure may be as a result of an initial non-ischaemic inciting influence, that is to say, chronic heart failure in the absence of significant coronary artery disease, as for example may be determined by coronary angiography.

According to another aspect of the present invention, there is provided the use of perhexiline in the manufacture of a medicament to treat chronic heart failure. In one embodiment, the medicament is for the treatment of non-ischaemic chronic heart failure, that is chronic heart failure in the substantial absence of inciting ischaemia. In another embodiment, the medicament is for the treatment of chronic heart failure having an ischaemic inciting origin.

In aspects of the present invention, the perhexiline exists in the form of a salt of perhexiline, preferably the maleate salt. The perhexiline may be sued at doses in the normal therapeutic range for perhexiline (Kennedy J A, Kiosoglous A J, Murphy G A, Pelle M A, Horowitz J D. “Effect of perhexiline and oxfenicine on myocardial function and metabolism during low-flow ischemia/reperfusion in the isolated rat heart”, J Cardiovasc Pharmacol 2000; 36(6):794-801).

Physiologically acceptable formulations, such as salts, of the compound perhexiline, may be used in the invention. Additionally, a medicament may be formulated for administration in any convenient way and the invention therefore also includes within its scope use of the medicament in a conventional manner in a mixture with one or more physiologically acceptable carriers or excipients. Preferably, the carriers should be “acceptable” in the sense of being compatible with the other ingredients of the formulation and not deleterious to the recipient thereof. The medicament may be formulated for oral, buccal, parental, intravenous or rectal administration. Additionally, or alternatively, the medicament may be formulated in a more conventional form such as a tablet, capsule, syrup, elixir or any other known oral dosage form.

According to a further aspect of the invention there is provided a treatment programme for treating chronic heart failure, which involves the co-use or co-administration of perhexiline with one or more other compounds that are advantageous in treating chronic heart failure or the symptoms thereof. In one embodiment, the programme is for the treatment of non-ischaemic chronic heart failure, that is chronic heart failure in the substantial absence of inciting ischaemia. In another embodiment, the programme is for the treatment of chronic heart failure having an ischaemic inciting origin.

An embodiment of the invention will now be described by way of example only wherein a double-blind, randomised, placebo-controlled study was undertaken in order to investigate the effects of perhexiline on chronic heart failure.

56 patients with CHF were recruited and all provided written informed consent. Entry criteria were as follows: left ventricular ejection fraction (LVEF) <40%, optimally medicated heart failure with New York Heart Association (NYHA) Class II-III symptoms. Cardiopulmonary exercise testing with respiratory gas analysis, completion of the Minnesota Living with Heart Failure Questionnaire (MLHFQ) and 2-D echocardiography were performed at baseline on all patients.

Patients were then allocated to two groups (ischemic or non-ischemic) depending on the presence or absence of significant coronary artery disease during coronary angiography.

The ischemic group (n=30) was also subjected to dobutamine stress echocardiography at baseline. The non-ischemic group (n=26) was subjected to

31P magnetic resonance spectroscopy to measure changes in muscle mitochondrial function.

All patients:

Cardiopulmonary Exercise Test

Incremental exercise testing with assessment of respiratory gas exchange was performed on a treadmill using the Weber protocol. Breath by breath respiratory gases were measured during exercise using a Pulmolab EX670 system mass spectrometer which was calibrated before every study. Raw data were averaged to 30 second intervals and oxygen consumption during peak exercise was obtained (VO₂max; ml/kg/min). Electrocardiograms and blood pressure were monitored throughout. Exercise was terminated at the subject's request due to fatigue or breathlessness.

Minnesota Living With Heart Failure Questionnaire (MLHFQ)

A standard 21-question MLHFQ was employed to determine if perhexiline affected patient quality of life. This is a well validated measure of symptomatology in heart failure (17) and includes questions to assess the ability to perform activities of daily living as well as questions gauging the severity of symptoms due to heart failure. Each question was scored out of 5. The sum of the scores were calculated where a higher score indicated a poorer quality of life. All patients completed the questionnaires alone and without assistance.

Resting Echocardiography

Echocardiography was performed with patients in the left lateral decubitus position using a Vingmed System V echocardiographic machine and a 2.5 MHz transducer. Images were stored digitally. Resting scans were acquired using standard echocardiographic windows for LVEF, transmitral valve Doppler, and resting tissue Doppler. Tissue Doppler echocardiography allows objective assessment of regional wall motion and is superior to conventional grey-scale echocardiography when used in conjunction with dobutamine stress (18).

Left ventricular volumes for calculation of LVEF were obtained using biplane echocardiography and the modified Simpson's formula. Volumes were averaged over 3 beats. In addition, on-line tissue Doppler peak systolic velocity (PSV) of the lateral mitral valve annulus was obtained as a reflection of left ventricular long-axis function.

In theory, improving metabolic efficiency would also lead to an improvement in diastolic function of the left ventricle as energy is also required for cardiac relaxation. The ratio of peak E wave from transmitral valve Doppler vs. the E wave from tissue Doppler of the lateral mitral valve annulus (E:EA ratio) is a sensitive indicator of left ventricular end diastolic pressure (19).

Ischemic Group:

Tissue Doppler assessment of the left ventricle was performed at rest and analysed off-line using Echopac software in order to determine regional myocardial PSV from 15 left ventricular segments described in detail elsewhere (20). These segments were selected to include all areas supplied by the three major coronary arteries and for the greatest reproducibility for acquisition of PSV (21). (See FIG. 4)

Dobutamine Stress Echocardiography

Following resting echocardiography dobutamine infusion was commenced via a syringe driver and incremented at 3 minute intervals from 5 mcg/kg/min to 10, 20, 30 and 40 mcg/kg/min. Digital loops of 15 views outlined above were stored at 90 seconds of each stage. Up to 1 mg of atropine was given if the hemodynamic response was submaximal. Electrocardiograms and blood pressure were monitored at each stage. End-points for termination of the test were attainment of >85% of the target heart rate, evidence of ischemia, or severe side effects from dobutamine. Data from all stages were analysed off-line as with the resting images.

PSV data are expressed as velocity at rest, low dose dobutamine infusion (10 mls/kg/min) and peak dose dobutamine infusion (the last infusion stage before infusion terminated, which may include the addition of atropine).

Non-ischemic group:

³¹P Magnetic Resonance Spectroscopy

Patients with CHF have abnormally rapid skeletal muscle phosphocreatine (a high energy phosphate metabolite critically involved in muscle contraction) depletion during exercise with delayed recovery (22). ³¹P magnetic resonance spectroscopy allows changes in skeletal muscle intracellular high energy phosphate compounds and pH to be measured non-invasively. At the end of exercise, because glycogenolysis has stopped and phosphocreatine resynthesis is purely oxidative, analysis of phosphocreatine recovery provides information about skeletal muscle mitochondrial function. In order to determine the effect of augmenting glucose metabolism on muscle energetics, magnetic resonance spectroscopy of calf muscle before, during and after local exercise was performed. Only patients in the non-ischemic heart failure population were subjected to magnetic resonance spectroscopy as underlying peripheral vascular disease leads to abnormalities in skeletal muscle energetics independent of heart failure.

Skeletal muscle high-energy phosphate metabolism was measured using a 2-Tesla superconducting whole-body magnet interfaced to a Bruker Avance spectrometer at least 3 days after the peak exercise tolerance test. The methodology has been described in detail elsewhere (23).

Briefly, subjects were positioned within the magnet in the supine position with a 6 cm diameter surface coil under the maximal circumference of the right calf muscle. ³¹Phosphorus spectra were collected at rest, during exercise and recovery. Following spectral acquisition at rest, a standardized exercise protocol was employed which involved plantar flexion at 0.5 Hz lifting 10% of lean body mass a distance of 7cm. This workload was continued for 4 minutes before being incremented by 2% of lean body mass for every subsequent minute until fatigue or phosphocreatine hydrolysis reached 50% of the resting level. Recovery spectra were subsequently acquired for 11 minutes. Examples of the spectra obtained during a typical study are shown in FIG. 3. Phosphocreatine concentrations were quantified using a time-domain fitting routine (VARPRO, R. de Beer). Phosphocreatine recovery halftime following exercise (PCr t½), a marker of skeletal muscle mitochondrial function which is independent of skeletal muscle mass and exercise intensity, was calculated as previously described (24).

Intervention

Following baseline studies, patients were randomized in a double-blind fashion to receive either perhexiline (n=28) or placebo (n=28) 100 mg twice daily. Blood was obtained at 1, 4, and 8 weeks after initiation of the drug for measurements of serum perhexiline levels with subsequent dose titration in order to prevent toxicity. Dose adjustments were advised as per a standard protocol by an unblinded physician. Identical dosage adjustments were also made for randomly allocated placebo-treated patients by the unblinded observer in order to ensure blinding of the investigators was maintained. After 8 weeks of treatment, patients were re-evaluated as above.

Statistics

The primary end-point for this study was pre-defined as VO₂max with the following secondary endpoints: MLHFQ score, LVEF, E:EA ratio, resting, low dose and high dose mean PSV during stress echocardiography and PCr t½. Therapy randomization of the ischemic and non-ischemic groups occurred separately but with similar protocols in order to allow for pre-hoc analysis of the primary endpoint in each group. The study had a 95% power to detect a 2 ml/kg/min increase in VO₂max in the active vs. placebo groups with a significance level of 0.05. Data were analyzed with SPSS 11.5 for Windows® and expressed as mean±standard error of mean. ANCOVA using baseline values as covariates was performed to test for significance of differences seen in the perhexiline vs. placebo groups following treatment. A p value of <0.05 was taken to indicate statistical significance.

Results

All patients completed the 8-week course of treatment. There were no deaths in either group during the study period. Side effects in the perhexiline group were restricted to transient nausea and dizziness during the first week of treatment (n=3). Both groups were well matched for baseline characteristics and treatment (Table 1). There was a significant fall in the NYHA class within the perhexiline group after treatment (p=0.02).

VO₂max at baseline was similar in the perhexiline and placebo groups (Table 2). Following treatment, VO₂max was unchanged in the placebo group but markedly increased by 2.7±0.8 ml/kg/min (16.7%) in the perhexiline group. ANCOVA demonstrated a significant effect of perhexiline vs. placebo on VO₂max; p<0.001. The increase in VO₂max in the ischemic and non-ischemic group were 2.9±1.2 ml/kg/min (p=0.008) and 2.5±0.4 ml/kg/min (p=0.03) respectively. Exercise time tended to increase in the perhexiline group. MLHFQ scores were significantly reduced by 24.4% following treatment in the perhexiline group (p=0.04) but unchanged in the placebo group. Perhexiline therapy was also associated with a significant reduction in PCr t½ (from 67±15 to 44±7 seconds; p<0.05) in the non-ischemic group. The normal range for PCr t½ in normal healthy adults is 14 to 50 seconds (23).

Mean LVEF was also markedly increased following treatment in the perhexiline group (by 9.9±2.0 absolute percentage points, a relative increase of 42%) and unchanged in the placebo group (p<0.001). Whilst left ventricular diastolic volume tended to decrease in the perhexiline group (p=0.06), systolic volume was significantly reduced (p<0.001) suggesting an increase in myocardial contractility. There was a significant reduction in E:EA ratio following treatment with perhexiline reflecting a reduction in left ventricular end diastolic pressure. In addition long-axis systolic function was increased in the perhexiline group reflecting an improvement in subendocardial function.

Within the ischemic cohort, there was no significant difference in heart rate at rest or during dobutamine stress in both groups. However, there was a significant 15% (p=0.04) increase in resting mean PSV in the perhexiline group following treatment. This increase reflects the increases seen in long-axis function and LVEF. During tissue Doppler stress echocardiography; there was a trend towards an increase in PSV at baseline (p=0.07) in the perhexiline group but a marked increase in peak dose PSV (24% p=0.03). At lower doses of dobutamine the myocardial velocities are inevitably lower; these low velocities are further diminished when measured off-line when compared to those obtained on-line by pulsed tissue Doppler. This is because they are derived from regional mean velocities rather than peak velocities. Though standard practice; this diminution will artificially appear to diminish the significance of the differences at low myocardial velocities. This explains the contrast between the seemingly small differences in baseline and low dose stress tissue Doppler parameters compared to the consistent and large increases in LVEF and online PSV of the lateral mitral annulus.

The data for the primary and secondary end-points are depicted on FIGS. 3 and 4 and summarized on Table 2.

Discussion

As a result of these experiments, it was found that Perhexiline use resulted in significant improvements in peak exercise capacity, myocardial function at rest and stress, patient reported symptoms and skeletal muscle energetics. Remarkably; as well as being statistically highly significant, these improvements represent clinically significant improvements in patients who were already optimally treated. Our results suggest that perhexiline provides consistent improvements in these parameters, in the absence of significant side effects, irrespective of the initial inciting influence of CHF.

Without wishing to be bound by theory, the mechanism for the improvement seen in myocardial function with perhexiline is likely to be related to inhibition of FFA uptake and a metabolic shift towards the use of glucose and lactate. This may restores the failing hearts insulin sensitivity and makes it more oxygen efficient. In addition to requiring more oxygen than glucose to generate energy, excessive FFA metabolism has other potentially detrimental effects on the heart. FFA metabolism is known to uncouple oxidative phosphorylation and suppresses glucose oxidation through a direct inhibitory action on the glycolytic pathway. This inhibition causes increases lactate and proton accumulation within myocardial cells (Lopaschuk G D, Wambolt R B, Barr R L. “An imbalance between glycolysis and glucose oxidation is a possible explanation for the detrimental effects of high levels of fatty acids during aerobic reperfusion of ischemic hearts”, J Pharmacol Exp Ther 1993; 264(1):135-144) leading to a fall in intracellular pH which is associated with a reduction in contractile function (Heusch G. “Hibernating myocardium”, Physiol Rev 1998; 78(4):1055-1085). Furthermore, FFA metabolite accumulation have been shown to reduce ventricular arrhythmia threshold (Murnaghan MF. “Effect of fatty acids on the ventricular arrhythmia threshold in the isolated heart of the rabbit” Br J Pharmacol 1981; 73(4):909-915) and induce diastolic dysfunction (Depre C, Vanoverschelde J L, Taegtmeyer H. “Glucose for the heart”, Circulation 1999; 99(4):578-588.).

The anti-anginal efficacy of perhexiline, both as mono- and combined therapy, is well documented (Horowitz J D, Mashford M L. “Perhexiline maleate in the treatment of severe angina pectoris”, Med J Aust 1979; 1(11):485-488; Cole P L, Beamer A D, McGowan N, Cantillon C O, Benfell K, Kelly R A et al. “Efficacy and safety of perhexiline maleate in refractory angina. A double-blind placebo-controlled clinical trial of a novel antianginal agent”, Circulation 1990; 81(4):1260-1270). However, use of the drug declined due to reports of hepatotoxicity and peripheral neuropathy. It is now apparent that the risk of toxicity was related to the ability to metabolize the drug. ‘Slow hydroxylators’, with a genetic variant of the cytochrome P450-2D6, are particularly prone to progressive drug accumulation. In the absence of dosage adjustment; prolonged elevation of levels leads to phospholipid accumulation which may also occur with prolonged use of other CPT inhibitors, such as amiodarone. The risk of development of hepato-neuro-toxicity with perhexiline is markedly reduced by monitoring and maintaining serum levels between 0.15 and 0.60 mg/l. None of the patients in this study developed abnormal liver function tests or neuropathy as a consequence of perhexiline treatment followed by close serum level monitoring and titration.

³¹P magnetic resonance spectroscopy was included in the study design to determine whether perhexiline treatment also improved skeletal muscle energetics. PCr t½ is a muscle bulk and workload independent marker of skeletal muscle mitochondrial function. The faster phosphocreatine recovery after exercise in the perhexiline treated patients suggested an improvement in skeletal muscle mitochondrial oxidative function. This may reflect an improvement in the heart failure syndrome and/or be a direct consequence of the metabolic substrate shift in skeletal muscle.

The results of the current study therefore establish that perhexiline exerts incremental benefits on symptomatic status, left ventricular function at rest and peak stress, and skeletal muscle metabolism in patients with stable chronic heart failure, over and above standard neurohumoral therapy. Indeed, the improvements in VO₂max were comparable to those seen in patients treated with beta-blockers (Hulsmann M, Sturm B, Pacher R, Berger R, Bojic A, Frey B et al. “Long-term effect of atenolol on ejection fraction, symptoms, and exercise variables in patients with advanced left ventricular dysfunction”, J Heart Lung Transplant 2001; 20(11):1174-1180) but exceeded those seen with ACE inhibitors (Vescovo G, Dalla L L, Serafini F, Leprotti C, Facchin L, Volterrani M et al. <<Improved exercise tolerance after losartan and enalapril in heart failure: correlation with changes in skeletal muscle myosin heavy chain composition”, Circulation 1998; 98(17):1742-1749), spironolactone (Cicoira M, Zanolla L, Rossi A, Golia G, Franceschini L, Brighetti G et al. “Long-term, dose-dependent effects of spironolactone on left ventricular function and exercise tolerance in patients with chronic heart failure”, J Am Coll Cardiol 2002; 40(2):304-310) or even with biventricular pacing (Auricchio A, Stellbrink C, Butter C, Sack S, Vogt J, Misier A R et al. “Clinical efficacy of cardiac resynchronization therapy using left ventricular pacing in heart failure patients stratified by severity of ventricular conduction delay”, J Am Coll Cardiol 2003; 42(12):2109-2116). As this study included patients with and without significant coronary artery disease who all benefited, the benefit cannot therefore be ascribed purely to an anti-ischemic mechanism, rather, it is suggestive of our hypothesis that Perhexiline is modifying the central metabolic remodeling of CHF.

The contents of all references cited herein are hereby incorporated herein in their entirety for all purposes.

TABLE 1
Baseline characteristics and treatment
	Placebo Group	Perhexiline Group
N	28	28
Ischemic:Non Ischemic	13:15	13:15
Age	63 ± 2	63 ± 2
Sex (M:F)	23:5	27:1
Weight (kg)	83 ± 3	89 ± 3
Height (cm)	165 ± 6	cm	175 ± 2	cm
Body mass index	28 ± 1	29 ± 1
NYHA Class
Pre:	2.2 ± 0.1	2.4 ± 0.1
Post:	2.1 ± 0.1	1.9 ± 0.2+
Corrected QT Interval
Pre:	421 ± 7	ms	413 ± 11	ms
Post:	421 ± 9	ms	413 ± 13	ms
Diabetes	2	5
Loop Diuretic	20	17
ACE Inhibitor	25	22
Lisinopril (mean dose)	22 ± 4	mg	23 ± 3	mg
Ramipril	10	mg	8.3 ± 1	mg
Perindopril	6	mg	6	mg
Enalapril	22 ± 10	mg	15 ± 5	mg
Trandolapril	4	mg	4	mg
AT2 Receptor Blockers	4	3
Losartan	63 ± 38	mg	100	mg
Valsartan	80	mg	80	mg
Irbersartan	175 ± 125	mg	—
Beta-Blockers	15	18
Carvedilol	37 + 10	mg	50	mg
Bisoprolol	2 ± 0.4	mg	4 ± 1	mg
Metoprolol	75 ± 25	mg	100	mg
Atenolol	67 + 17	mg	69 ± 19	mg
Aspirin	15	11
Clopidogrel	1	3
Warfarin	9	9
Calcium Channel Blockers	5	3
Spironolactone (mean dose)	7 (21 ± 4	mg)	6 (23 ± 2	mg)
Amiodarone	4	1
Oral Hypoglycaemics	1	2
Insulin	0	2
Statin	18	12
Serum perhexiline levels:
Week 1:	0	0.57 ± 0.19	mg/l
Week 4:	0	0.67 ± 0.20	mg/l
Week 8:	0	0.43 ± 0.12	mg/l
+p = 0.02

TABLE 2
Primarv and secondary endpoints. (All P values refer to ANCOVA
of the differential effect of perhexiline vs. placebo)
	Placebo	Perhexiline	P
	Group	Group	value
VO2max (ml/kg/min)
Pre:	16.3 ± 0.8	16.1 ± 0.6	*<0.001
Post:	16.0 ± 0.9	18.8 ± 1.1*
Exercise Time (mins)
Pre:	9.9 ± 1.2	10.5 ± 1.2
Post:	10.9 ± 0.9	12.3 ± 1.1
Respiratory exchange
ratio during peak
exercise+
Pre:	1.1 ± 0.02	1.1 ± 0.03
Post:	1.1 ± 0.02	1.1 ± 0.03
Resting BP (mmHg)
Pre:	111/63 ± 5/3	116/69 ± 7/4
Post	113/67 ± 5/4	113/67 ± 7/4
Peak Exercise BP
(mmHg)
Pre:	141/69 ± 5/4	141/75 ± 9/3
Post:	137/68 ± 7/4	142/70 ± 9/5
Resting Heart
Rate(min−1)
Pre:	76 ± 4	73 ± 3
Post:	78 ± 4	73 ± 3
Peak Exercise Heart
Rate(min−1)
Pre:	124 ± 6	121 ± 6
Post:	121 ± 5	120 ± 5
Minnesota living with
heart failure
questionnaire score
Pre:	42 ± 5	45 ± 5	†0.04
Post:	40 ± 4	34 ± 5†
Left ventricular end-
diastolic volume (ml)
Pre:	213 ± 16	232 ± 11
Post:	216 ± 16	212 ± 9
Left ventricular end-
systolic volume (ml)
Pre:	159 ± 13	176 ± 8	‡<0.001
Post:	162 ± 14	140 ± 8‡
Left ventricular
ejection fraction (%)
Pre:	26 ± 1	24 ± 1	§<0.001
Post	26 ± 1	34 ± 2§
Long axis function
(cm/s)
Pre:	6.4 ± 0.6	5.8 ± 0.4	∥0.04
Post:	6.4 ± 0.5	7.2 ± 0.6∥
E:EA Ratio
Pre:	8.3 ± 1.0	8.6 ± 0.6	#0.02
Post:	8.9 ± 1.8	6.5 ± 0.9#
PCr t½
(seconds)
Pre:	58 ± 10	67 ± 15	**<0.05
Post:	73 ± 24	44 ± 7**
Dobutamine Stress
Echocardiography:
Heart Rate: Rest
Pre	67 ± 5	57 ± 2
Post	66 ± 6	53 ± 2
Low Dose
Pre	86 ± 8	78 ± 7
Post	74 ± 6	65 ± 6
Peak Dose
Pre	130 ± 5	126 ± 4
Post	128 ± 5	122 ± 3
Mean PSV Rest
(15 segments)
Pre	3.5 ± 0.2	3.3 ± 0.2	††0.07
Post	3.4 ± 0.2	3.8 ± 0.2††
Low Dose
Pre	4.6 ± 0.3	4.7 ± 0.3
Post	4.8 ± 0.3	5.0 ± 0.5
Peak Dose
Pre	6.4 ± 0.4	6.6 ± 0.5	§§0.003
Post	5.8 ± 0.4	8.2 ± 0.8§§
*Ratio of CO2 emission/oxygen consumption

Claims

1. A method of treating chronic heart failure, which comprises administering to an animal in need thereof an effective amount of perhexiline, or a pharmaceutically acceptable salt thereof, to treat said chronic heart failure.

2. A method of treating chronic heart failure, which comprises administering to an animal in need thereof an effective amount of perhexiline, or a pharmaceutically acceptable salt thereof, to treat said chronic heart failure, wherein said chronic heart failure is chronic heart failure as a result of an initial inciting influence of ischaemia.

3. A method of treating chronic heart failure, which comprises administering to an animal in need thereof an effective amount of perhexiline, or a pharmaceutically acceptable salt thereof, to treat said chronic heart failure, wherein said chronic heart failure is a result of an initial non-ischaemic inciting influence.

4. A method according to claim 1, wherein the animal is a human.

5. A method according to claim 1, wherein a salt of perhexiline is used.

6. A method according to claim 5, wherein the salt is the maleate salt.

7. A method according to any preceding claim 1, wherein the perhexiline or salt thereof is used in conjunction with one or more other compounds for treating chronic heart failure or the symptoms thereof.

8. (canceled)

9. (canceled)

10. (canceled)

11. (canceled)

12. (canceled)

13. A treatment programme for treating chronic heart failure, which comprises the co-use or co-administration of perhexiline with one or more other compounds that are advantageous in treating chronic heart failure or the symptoms thereof.

14. A treatment programme according to claim 13, for the treatment of non-ischaemic chronic heart failure.

15. A treatment programme according to claim 13, for the treatment of chronic heart failure having an ischaemic inciting origin.

16. A method according to claim 2, wherein the animal is a human.

17. A method according to claim 3, wherein the animal is a human.

18. A method according to claim 2, wherein a salt of perhexiline is used.

19. A method according to claim 3, wherein a salt of perhexiline is used.

20. A method according to claim 4, wherein a salt of perhexiline is used.

21. A method according to claim 2, wherein the perhexiline or salt thereof is used in conjunction with one or more other compounds for treating chronic heart failure or the symptoms thereof.

22. A method according to claim 3, wherein the perhexiline or salt thereof is used in conjunction with one or more other compounds for treating chronic heart failure or the symptoms thereof.

23. A method of improving the myocardial function of a patient comprising the step of administering an effective amount of perhexiline or a pharmaceutically acceptable salt thereof.