Dr



June 19, 2008

49 093 K

PAION Deutschland GmbH

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Martinstraße 10 - 12, 52062 Aachen

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“Novel strategies for increasing the reperfusion in obstructed blood vessels”

Cellular function critically hinges on a sufficient supply of oxygen by the bloodstream. Thus, obstruction of blood supply may, depending on its extent, result in a damage or dysfunction of the downstream tissues. This inadequate flow of blood or shortage of blood supply to an organ or tissue is referred to as ischemia. One of the most prominent reasons underlying an ischemic event is a thrombus formation in a blood vessel.

Insufficient provision with oxygen means that tissues become hypoxic, or, if no oxygen is supplied at all, anoxic, a condition that, if prevailing for too long will cause necrosis (i.e. cell death).

Ischemia is inter alia a feature of certain heart diseases, transient ischemic attacks, cerebrovascular accidents, rupture of arteriovenous malformations and/or peripheral artery occlusive diseases. Tissues especially sensitive to inadequate blood supply include the heart, the kidneys and the brain. Ischemia in brain tissue, for example due to a stroke or head injury, causes the so-called ischemic cascade to be unleashed, which stands for a series of consecutive, parallel and interacting biochemical events involving proteolytic enzymes, reactive oxygen species, and other active compounds. The final outcome of this sequence is damage and destruction of brain tissue.

Stroke, a synonym for ischemic events in brain tissue, is the third leading cause of death, after cardiovascular disease and cancer. Each year, stroke is diagnosed in 750.000 patients and contributes to nearly 168.000 deaths in the United States only. Stroke has a high personnel and social impact because of the severe disability that the disease causes.

Recanalization of occluded arteries to restore blood supply is the most effective therapy for stroke treatment in humans to date. The success rate of such treatment is reduced by the possibilities of intracerebral hemorrhage and reocclusion. Hemorrhage is part of the damage caused by the ischemic cascade, but is also a risk associated with thrombolytic agents. Reocclusion may occur at the same site or by fragments of the original clot that have been carried downstream. In a recent study (Rubiera et al., Predictors of early arterial reocclusion after tissue plasminogen activator-induced recanalization in acute ischemic stroke; Stroke 2005; 36:1452-1456) reocclusion occurred in 84 of 142 (61%) consecutive stroke patients (53 partial, 31 complete). Of these, 21 (25%) patients worsened after an initial improvement.

In general, a known method for prevention of obstruction or reobstruction (reocclusion) of vessels is to treat a thrombotic patient with an anticoagulant or antiplatelet drug. Anticoagulants are substances, which reduce the ability of blood to form blood clots. Various anticoagulants are known to the skilled person, for example heparin or warfarin.

Although the anticoagulant or anti-thrombotic effects of various substances are known, currently there is not any approved anticoagulant therapy for treating acute stroke patients. Of the numerous antiplatelet drugs, only low-dose aspirin is recommended. However, according to the guidelines of the American Heart Association (AHA) and the American Stroke Association (ASA), this recommendation is limited to the first 24-48 hours after acute ischemic stroke (see Guidelines, May 2007. page 1681, left column).

Regarding anticoagulation therapy the guidelines explicitly state that

- urgent anticoagulation with the goal of preventing early recurrent stroke, halting neurological worsening, or improving outcomes after acute stroke is not recommend for treatment of patients with acute ischemic stroke,

- urgent anticoagulation is not recommend for patients with moderate and severe strokes because of an increased risk of serious intracranial hemorrhagic complications

- the initiation of anticoagulant therapy within 24 hours of treatment with intravenously administered tPA is not recommended (Guidelines, page 1680, left column).

The reluctance of scientists and regulatory authorities with respect to anticoagulant stroke therapy is merely due to the fact, that anticoagulants have been shown to increase the risk for hemorrhagic transformation in stroke patients, potentially obliterating any therapeutic benefit. The anticoagulant therapies approved so far are limited to the fields of cardiac infarction and pulmonary embolism.

However, according to the invention it has now been found that thrombomodulin can be used to improve or even effect reperfusion of obstructed blood vessels, in particular obstructed blood vessels of stroke patients. This improvement is linked to an substantial increase in the risk of hemorrhagic transformation. Due to this reperfusive activity thrombomodulin can be clinically used as a thrombolytic.

A thrombolytic is a substance that directly or indirectly removes or reduces an occlusion and thereby leads to reperfusion of a blood vessel. Besides this thrombolytic (or profibrinolytic) properties thrombomodulin exhibits – as already known – anticoagulative properties.

Thromboembolic events which can be treated with thrombomodulin as a thrombolytic includes, but is not limited to, myocardial infarction, deep vein thrombosis, pulmonary embolism, portal or renal vein thrombosis, hepatic thrombosis (Budd-Chiari syndrome), thrombosis of the upper extremities (Paget-Schroetter disease), or thoracic outlet syndrome as well as stroke events.

Thrombomodulin is a membrane protein that acts as a thrombin receptor on the endothelial cells lining the blood vessels. Thrombin is a central enzyme in the coagulation cascade, which converts fibrinogen to fibrin, the matrix clots are made of. Initially, a local injury leads to the generation of small amounts of thrombin from its inactive precursor, prothrombin. Thrombin, in turn, activates platelets and, second, certain coagulation factors including factors V and VIII. The latter action gives rise to the so-called thrombin burst, a massive activation of additional thrombin molecules, which finally results in the formation of a stable clot.

When bound to thrombomodulin, however, the activity of thrombin is changed in direction: A major feature of the thrombin-thrombomodulin complex is its ability to activate protein C, which then downregulates the coagulation cascade by proteolytically inactivating the essential cofactors Factor Va and Factor VIIIa (Esmon et al., Ann. N. Y. Acad. Sci. (1991), 614:30-43), thus affording anticoagulant activity. The thrombin-thrombomodulin complex is also able to activate the thrombin-activatable fibrinolysis inhibitor (TAFI), which then antagonizes fibrinolysis.

Although earlier studies were negative, more recent studies have indicated that thrombomodulin is not only present in brain endothelial cells (Boffa, et al., Nouv. Rev. Fr. Hematol. (1991), 33:423-9; Wong, et al., Brain Res. (1991), 556:1-5; Wang, et al., Arterioscler. Thromb. Vasc. Biol. (1997), 17: 3139-46; Tran, et al., Stroke (1996), 27:2304-10; discussion 2310-1) but is also expressed on the surface of astrocytes, where it functions as in the vasculature, namely activating protein C after forming a complex with thrombin (Pindon, et al., Glia (1997), 19:259-68). Thrombomodulin is also upregulated in reactive astrocytes in the CNS, in response to mechanical injury (Pindon, et al., J. Neurosci. (2000), 20:2543-50). A pertinent report suggests that recombinant thrombomodulin is capable of blocking thrombin's activation of another receptor, the protease-activated receptor 1 (PAR-1) in cultured neuronal cells (Sarker, et al. Thromb. Haemost. (1999), 82: 1071-77).

Activated protein C has also been strongly implicated in the regulation of inflammatory responses involving various cytokines or activated leukocytes (Esmon et al., Thromb. Haemost. (1991), 66:160-165). Consistent with this hypothesis, studies have shown that activated protein C, by inhibiting the production of tumor necrosis factor (TNF-alpha) prevents pulmonary vascular injury in rats administered endotoxin TNF-alpha is a potent activator of neutrophils (Murakami et al., Blood (1996), 87:642-647; Murakami et al., Am. J Physiol. (1996), 272:L197-2). This is consistent with the ability of recombinant human soluble thrombomodulin to prevent endotoxin-induced pulmonary vascular injury by inhibiting the activation of neutrophils, in an action mediated by protein C activation (Uchiba et al., Am. J. Physiol. (1996), 271 :L470-5; Uchiba et al., Am. J Physiol. (1997), 273:L889-94).

The thrombolytic effect of thrombomodulin according to one embodiment of the invention regarding the improvement of reperfusion was surprisingly found in an animal model with a stable occlusion of the middle cerebral artery (MCA). Mice with an occluded MCA were treated with a soluble thrombomodulin and surprisingly exhibited a substantial reperfusion as measured by an increase cerebral blood flow (CBF). This finding was unexpected, since the anticoagulant effects known for thrombomodulin from animal studies were merely suggestive of an ability to prevent blood clotting, rather than to restore blood flow.

In the context of the present invention the term “reperfusion” refers to any improvement of the blood flow compared to the state of occlusion, which can either be a partial or a total reperfusion. Thus the term reperfusion is not limited to effects, which result in the complete restoration of the original blood flow before the ischemic event. According to the invention, the reperfusing effect of thrombomodulin is assumed to include effects which antagonize the thrombus formation and/or support the spontaneous lysis of blood clots.

As used for the purpose of the invention the term “occlusion” is defined as any stricture or narrowing of a blood vessel which results in a reduced blood flow of the tissue distal thereof compared to the healthy or normal blood vessel. The occlusion can either be partial or complete. Hence, the term occlusion encompasses also a stenosis, i.e. abnormal narrowing of a blood vessel still allowing distal perfusion.

In another aspect of the invention, thrombomodulin can be used for preventing or at least lowering the risk of an occlusion of blood vessels by thromboembolic events, in particular by secondary thromboembolic events. These secondary thromboembolic events can be cerebral blood clots, deriving from the primary ischemic event. Thus, according to this embodiment of the invention, thrombomodulin can be used to treat stroke patients suffering from the risk of secondary cerebral vascular occlusions (reocclusions).

First results from a thrombomodulin Phase I clinical trial with the thrombomodulin Solulin (“SOLID-I”) confirmed the use of soluble thrombomodulin as a safe and highly efficacious anticoagulant and thrombolytic.

SOLID was designed as a single-center, randomized, single-blind, placebo-controlled Phase I study in healthy volunteers. In addition to the regular safety parameters, the SOLID-I study looked into possible negative effects of the applied Solulin doses on the clotting system. In the study, five groups of volunteers were each administered a single dose of Solulin, with escalating dosages in the consecutive dose groups. Each dose increase was first approved by the study safety committee. As a reference, some of the study subjects received a pharmacologically inactive substance, i.e. a placebo. Within the chosen dose range of 0.6 to 30 mg, Solulin was shown to inhibit thrombin formation in a dose-dependent manner by up to 98%. Already in the lowest dose group an effect could be seen and a 50% inhibition of thrombin formation was achieved with 1 mg indicating the expected therapeutic doses.

The factor 50 between the lowest and the highest dose of Solulin confirms the good tolerability of the substance already seen in the preclinical studies (see Tab. 1 and Fig. 8). Also in accordance with the results of the preclinical studies, no effect on blood coagulation parameters was observed which would have suggested an increased bleeding propensity.

Hence, according to the invention thrombomodulin combines in one molecule the diverse functional properties of an anticoagulant and a thrombolytic. Namely, like an anticoagulant thrombomodulin is able to prevent thrombotic events and like a thrombolytic thrombomodulin is able to induce or cause reperfusion. Therefore based on the invention thrombomodulin is a first representative of a new class of “bi-functional” drugs exhibiting anticoagulant and thrombolytic properties.

These properties render thrombomodulin in particular suitable for treating patients with a combination of a thrombotic risk and an existing or evolving thrombosis. Hence according to one embodiment of the invention minor strokes are treatable with thrombomodulin.

Curently, a minor stroke represents a clinical exclusion criterion for a thrombolytic therapy due to an unfavorable risk benefit ratio. This is due to the consideration, that on one hand patients with minor stroke often have had a clot that is already resolved, and on the other hand the inherent bleeding risk of thrombolytics restricts the use of thrombolytics to the more severe stroke cases. Since these patients have a high risk for a subsequent thrombotic event, it is also described as “unstable stroke patients”.

In a further embodiment of the invention thrombomodulin could be used to treat patients suffering a minor stroke or a stroke that has already improved by the time of the clinical assessment. As an anticoagulant it can be used to prevent further thrombotic event and as a thrombolytic it can resolve the clot “in statu nascendi”, in particular in cases where a clot has been formed despite thrombomodulin anticoagulation. In consequence thrombomodulin can be administered to the patient who is diagnosed with a minor stroke, and can be applied as a thrombolytic therapy for treating minor stroke..

A minor stroke can be defined by a stroke severity of equal to or less than 6, preferably equal to or less than 4 on the National Institutes of Health Stroke Scale (NIHSS). Alternatively minor stroke can be defined according to the 5 working definitions (definitions A-E) proposed by the National Institute of Neurological Disorders Stroke rt-PA Stroke Study Group (Ann Emerg Med (2005); 46: 243-251).

Definition A includes all patients who have scores of 0 or 1 on every baseline NIHSS score item, except level of consciousness (items 1a to 1c), which must be be 0. Maximum possible NIHSS score in this definition is 11.

Definition B includes all presumed small-vessel occlusive patients. This definition is based on a lacunar-like syndrome.

Definition C includes all patients with motor deficits (can include dysarthria or ataxia) with or without sensory deficits. These patients can have only a combination of motor, coordination, and sensory deficits without any deficits in the spheres of language, level of consciousness, extinction or neglect, horizontal eye movements, or visual fields, deficits generally ascribed to larger territories of focal ischemia. This definition attempts to capture those patients with the lacunar syndrome of pure motor hemiparesis or the related lacunar syndromes of sensorimotor stroke and ataxic hemiparesis.

Definition D includes all patients with baseline NIHSS in the lowest (least severe) quartile of severity (NIHSS score ≤9), excluding all patients with aphasia, extinction or neglect, or any points on the level-of-consciousness questions. This definition takes the least severe quartile of patients and further eliminates those with selected items that are generally not involved with smaller, more minor infarcts.

Definition E includes all patients who are in the lowest quartile of stroke severity based on baseline NIHSS score (maximum NIHSS score 9). The definition analyzes the group of patients with the lowest quartile of NIHSS scores independent of the spheres of neurological deficit involved.

The NIHSS is a systematic assessment tool that provides a quantitative measure of stroke-related neurological deficit. The NIHSS was originally designed as a research tool to measure baseline data on patients in acute stroke clinical trials. Now, the scale is also widely used as a clinical assessment tool to evaluate acuity of stroke patients, determine appropriate treatment, and predict patient outcome. According to the NIHSS, parameters such as the level of consciousness, the eye movement, the facial palsy or the motor ability of arms or legs are assessed and subject to a pre-defined numerical scoring. On a regular basis a NIHSS score of 6 to approximately 15 is qualified as a stroke of medium severity. A score of 15 or more of the NIHSS scale indicates a rather severe stroke. Frequently a stroke of a NIHSS score of 20 or more is considered as being untreatable. However, notably the qualification of the severity of a stroke depends also on the individual assessment of the patient by the physician, which includes aspects of the overall clinical performance of the patient. According to the invention a baseline NIHSS score of equal to or less than 6 is preferable.

Like for other thrombolytics the visualization of the blood vessel status can be taken for a therapeutic decision for a thrombomodulin therapy. According to one aspect of the invention any imaging tool can be applied which results in the visualization of the inner opening of structures filled with blood ad therewith enables the identification of an arterial occlusion. Possible imaging modalities include MRI or CT and further developments or modifications thereto; however without being limited to it. The visualization of blood vessels can also be referred to as angiography. Various methods for the further evaluation of MRI or CT images are known to the person skilled in the art (e.g. MTT, TTP or Tmax as post processing maps).

In a further embodiment of the invention, occlusion can be treated which are localized in a cerebral artery, in particular the middle cerebral artery (MCA), the anterior cerebral artery (ACA) and/or the posterior cerebral artery (PCA) including all of their branches, in particular M1 and/or M2.

In a preferred embodiment of the invention the use of thrombomodulin either as an anticoagulant or as a thrombolytic can be based on the diagnosis of the status of the blood vessels. For this purpose the TIMI scale can be used. The TIMI scale (Thrombolysis in Myocardial infarction scale) was originally developed for the assessment of arterial occlusions in myocardial infarction and encompasses 4 grades as follows:

grade 3: normal blood flow

grade 2: artery entirely perfused but blood flow delayed

grade 1: artery penetrated by contrast material but no distal perfusion

grade 0: complete occlusion of the vessel

Patients with a TIMI grade of 0 to 2 suffer from a complete or partial occlusion and can be (preferably acutely) treated with thrombomodulin based on its thrombolytic activity. At a TIMI grade of 3 thrombomodulin can however prevent (re-)occlusion and is given for acute prevention or chronically, e.g. for longer time periods from days to weeks as secondary prevention treatment.

In another embodiment of the invention thrombomodulin can be used to treat patients suffering from a transient neurological attack. Transient neurological attacks (TNAs) are attacks with temporary ( 1 hour, a known hypercoagulable state, or an appropriate combination of the californian score, the ABCD score or the ABCD2 score (National Stroke Association guidelines for the management of TIA). Since these clinical features indicate an increased risk for a further thrombotic event they could be also taken as inclusion criteria for a thrombomodulin therapy.

The general medical assessment of TIA includes an EKG, full blood count, serum electrolytes and creatinase and fasting blood glucose and lipids. This assessment should help to define the nature of the event and can be used to decide on a thrombomodulin therapy.

Several brain imaging technologies like computed tomography (CT) and computed tomography angiography (CTA) or magnetic imaging resonance (MRI) and magnetic resonance angiography (MRA) may show infarcts and vascular occlusion and is recommended to corroborate differential diagnosis with other pathologies that can mimic TIA. Transcranial dopper is a complementary examination in patients with a recent TIA. It may provide additional information on patency of cerebral vessels, recanalization and collerateral pathways. Every of the above mentioned brain imaging technologies taken alone or in combination can therefore be helpful to decide on a thrombomodulin therapy.

Based on the efficacy of soluble thrombomodulin in animal model of venous thrombosis and photothrombotic stroke at doses which do not significantly increase the bleeding propensity, thrombomodulin can be used as a thrombolytic or an anticoagulant for the treatment of non-cardioembolic or cardioembolic TIA/stroke.

The underlying mechanism of cardioembolic TIA/stroke is occlusion of cerebral vessels with debris from a cardiac source. An embolus may consist of platelet aggregates, thrombus, platelet-thrombi, cholesterol, calcium or bacteria. Most embolic debris contain platelet aggregates. However, no single mechanism is responsible for the development of cardiac emboli. The specific underlying cardiac disease determines the pathophysiology and natural history, and hence each cardioembolic source must be considered individually. Cardioembolic embolism accounts for approximately 20% of ischemic strokes each year. In general, cardioembolic strokes have a worse prognosis and produce larger and more disabling strokes than other ischemic stroke subtypes. This general observation is derived from platelet-rich emboli originating in cardiac chambers, which are on average on large size (e.g. atrial appendage, ventricular thrombi). With respect to the cardioembolic TIA/stroke thrombomodulin may represent a promising therapeutical option since it inhibits directly and indirectly (via protein C) thrombin which is a potent platelet activator and plays a key role in the initiation of platelet thrombus as well as in the late platelet thrombus growth and/or stability.

More than 20 specific disorders have been implicated in leading to brain embolism. Dividing cardiac sources of emboli into major- and minor-risk categories is clinically useful. Major-risk sources carry a relative high risk of initial and recurrent stroke. When a major-risk cardioembolic source is present, efforts of primary prevention of stroke are indicated which also qualify those patients for a thrombomodulin therapy.

High-risk cardiac sources includes, but is not limited to, rheumatic mitral stenosis, prosthetic valves, infective endocarditis, nonbacterial thrombotic (marantic) endocarditis, ischemic heart diesease, acute myocardial infarction, left ventricular akinesis or aneurysm, nonischemic cardiomyopathies (e.g. idiopathic dilating, viral myocarditis-associated, echinococcal, peripartum, amyloid-associated, hypereosinophilia syndrome-associated, rheumatic myocarditits-associated, sarcoidosis-related, neuromuscular disorder-associated, catecholamin-induced, doxorubicin-induced, mitoxantrone-related, crack-cocaine-related, cardiac oxalasis-associated), atrial fibrillation, atrial flutter, atrial myxoma or the sick-sinus syndrome (so called brachy-tachy syndrome).

In a preferred aspect of the invention thrombomodulin is used in patients with an increased risk for a thrombotic event. This enhanced risk may be the consequence of a underlying disorder which includes, but is not limited to, stroke, diabetes, myocardial infarction, unstable angina, atrial fibrillation, renal damage, pulomary embolism, deep vein thrombosis and organ and prosthetic implants. Other risk factors are hypotension, hypercholesteremia, hyperlipidemia, cigarette smoking, alcohol consumption, obesity and low physical activity. The risk can be the result of clinical factors like age, blood pressure, microemboli, and biomarkers. Clinical factors can be used to establish a diagnostic score. There are several recently developed diagnostic procedures like the ABCD score (Rothwell et al.: “A simple score (ABCD) to identify individuals at high early risk of stroke after transient ischaemic attack.” in Lancet 2005, 366:29-36) or the ABCD2 score (Johnston et al.: “Validation and refinement of scores to predict very early stroke risk after transient ischaemic attack.” In: Lancet 2007 369: 283-92) in order to predict the risk of a further thrombotic events for patients with TNAs and focal symptoms (better known as transient ischemic attacks: TIAs).

The ABCD2 score can predict the likelihood of a subsequent thrombotic event and is calculated as:

• Age ≥ 60 years = 1point

• Blood pressure at presentation ≥ 140/90 mm Hg = 1 point

• Clinical Features:

o Unilateral weakness = 2 points

o Speech disturbance without weakness = 1point

• Duration of attack:

o ≥ 60 minutes = 2 points

o 10-59 minutes = 1 points

• Diabetes = 1 point

The total score is in a range of 0 to 7. The risk for a thrombotic event is low for a score of 0-3, moderate for a score of 4-5 and high for a score of 6-7. According to the invention in one embodiment patients with an ABCD² of 3 or more, in particular of at least 4, more preferred of at least 6 are treated with thrombomodulin.

In addition the thrombotic risk may be assessed based on the genetic predisposition of the patient (e.g. Factor V Leiden, mutations or polymorphisms in the following genes: Cystatin C, type 4 collagen alpha-1, prothrombin, phosphodiesterase 4D, ACE, Interleukin 1-receptor antagonist, interleukin-6, 5-lipoxygenase activating protein (FLAP), arachidonate 5-lipoxygenase (Alox-5), toll-like receptor-4, mannose-binding lectin), the use of medications (e.g. contraceptives) or pathological changes of the vasculature including artherosclerosis, vasculitis and aneurysma.

In a further embodiment thrombomodulin is used for the treatment of so called lacunar stroke. A lacunar stroke is defined as a small subcortical infarct (>15 mmm in diameter) in the territory of the deep penetrating arteries (diameter 0.2 -15mm). Lacunes occur most frequently in the basal ganglia and internal capsule, thalamus, corona radiata, and pons. Symptoms often occur in either a flucatuating (e.g. capsular warning syndrome) or a progressive manner. Patients that exhibits this course of disease are often diagnosed too late in order to receive a thrombolytic therapy with r-tPA. In turn these patients qualifiy for a thrombolytic therapy using thrombomodulin. In addition patients with lacunar stroke often show an early substantial improvement and hence thrombomodulin can be used as anticoagulant to prevent a subsequent thrombotic event.

It is known to the skilled person, that currently no anticoagulant therapy for preventing a reocclusion with anticoagulants is approved, since there is an incalculable risk of intracerebral hemorrhage, which is even accentuated after the administration of a thrombolytics. The novel teaching according to one embodiment of the invention thus is that thrombomodulin can be administered to an ischemic patients (in particular stroke patients) with less or no substantial risk of deleterious effects, in particular bleeding, compared to patients untreated with thrombomodulin. Hence, even if the patient had suffered a stroke before and/or had received thrombolytic therapy, he can be subject to anticoagulation therapy with soluble thrombomodulin according to one embodiment of the invention. The beneficial effect of thrombomodulin regardless of a possible prior thrombotic or ischemic event or a thrombolytic therapy, was unexpected to the skilled person, since studies reported an association between an increased level of soluble thrombomodulin and an increased risk of death in patients with stroke (Olivot JM, et al: Soluble Thrombomodulin and Brain Infarction. in: Stroke 2004, 35:1946-1951) .

In yet another aspect of the invention, the thrombomodulin is administered to the patient within the acute or early phase of the ischemic event. In a particular embodiment, the administration is applied in the time window of the first 24 hours after the administration of a thrombolytic substance, for example tPA or any other plasminogen activating factor. In this case, thrombomodulin preferably is administered as an anticoagulant.

In a further embodiment of the invention, the thrombomodulin as administered for anticoagulation within three hours after the onset of the ischemic event.

According to yet another aspect of the invention the thrombomodulin is administered to the patients in a dosage, which does not substantially increase the blood coagulation parameters, as measured for example by an APTT or PTT assay known to the skilled person in the art. The APTT (Activated Partial Thromboplastin Time) or PTT (Partial Thromboplastin Time) is an assay which is indicative of the efficacy of the intrinsic and the common coagulation pathway, respectively. Apart from detecting abnormalities in blood clotting, it is also used to monitor the treatment effects of anticoagulants.

According to another embodiment of the invention, a dosage of thrombomodulin is administered to the patient, which is not associated with a prolonged coagulation time. The APTT values of healthy humans lie normally between around 25 sec. and 39 sec. Values outside this range are generally considered as abnormal. According to this aspect of the invention, the applied dosage does not substantially prolong the APTT, but effectively prevents vessel occlusion as measured e.g. in the assay of photothrombotic occlusion of the middle cerebral artery in the mouse.

The preferred dosage of thrombomodulin according to the invention is approximately 0.01 to 5 mg/kg body weight, preferably 0.03 to 3 mg/kg body weight, most preferred 0.03 to 1.5 mg/kg body weight or 0.05 to 1.0 mg/kg body weight. Thus according to the invention, a possible dosage unit form, such as a vial or ampoule, is suggested containing around 0.8 to 400 mg, preferred 2.4 to 240 mg, most preferred 0.8 to 1200 mg or 4 to 80 mg (assuming a patient of around 65 kg body weight).

In another embodiment of the invention the dose range of thrombomodulin, in particular Solulin, for treating stroke, preventing coagulation and re-occlusion or thrombolytic therapy is approximately from 0.5 (in particular 0.6) to approximately 30 mg per patient and a more preferred dose range is 1 to 10 mg, most preferred 3 to 10 mg per patient. Thus, according to the invention a ready-to-use pharmaceutical composition with a fixed thrombomodulin dose is provided.

Thrombomodulin, in particular Solulin, preferably is given non-orally e.g. by intravenous application. An intravenous bolus application is possible. Thus according to the invention a pharmaceutical composition is provided containing thrombomodulin, in particular Solulin, in a doses in the range of 1-30 mg or more, preferably a fixed dose of 1, 2, 2.5, 3, 4, 5, 6, 7, 7.5, 8, 9 or 10 mg of thrombomodulin, in particular Solulin.

According to the invention thrombomodulin can be administered either in a single dose or a multiple dose or a combination thereof. Doses as above, either body weight adjusted or fixed doses can ne used.

The single dose groups as well as the multiple dose groups showed that the administration of thrombomodulin (in particular Solulin) did not result in an antibody production against thrombomodulin within the volunteer. Hence, even a multiple administration of thrombomodulin, in particular Solulin is possible for a long lasting period, i.e. an administration over weeks, months or years. Thus, according to the invention a chronic thrombomodulin therapy is possible. In addition, this lack of immunogenicity allows that patients can receive more than therapy with thrombomodulin (in particular Solulin) in their lifetime.

These embodiments of the invention are based on the results of the above mentioned SOLID-I study. In this study escalating single doses of 0.6, 1.0, 3.0, 10.0 and 30 mg of thrombomodulin (Solulin) were administered intravenously as a bolus to five groups of volunteers. In this single dose part Solulin caused no increased bleeding propensity, as evidenced from aPTT, prothrombin-ratio, prothrombin-time measurements, and the PFA 100 bleeding assay. This fact together with the observation of only few and mild adverse events confirmed that Solulin is a very safe drug. The factor 50 between the lowest and the highest dose of Solulin in the single dose part confirms the good tolerability of the substance already seen in preclinical studies (see Tab. 1 and Fig. 8).

In this part of the study, Solulin inhibited thrombin formation in a dose-dependent manner by up to 98%, whereby a dose of 1 mg/volunteer leads to a 50% inhibition (Figure 11).

In the multiple dose part of the study Solulin, was administered once daily over 5 days. Thus, according to the invention a pharmaceutical composition is provided, which is suitable for allowing a multiple administration of thrombomodulin. In the multiple dose part Solulin caused no increased bleeding propensity, as evident from aPTT, prothrombin-ratio, prothrombin-time measurements, and the PFA 100 bleeding assay. This findings further confirm the fact, Solulin is a safe anti-thrombotic drug.

Furthermore Solulin was shown to inhibit thrombin formation in a dose-dependent manner by up to 93% (Figure 12). This range of thrombin generation inhibition correlates with the results of the single dose application. Thus, these two dosing regimens can be combined e.g to start with a single dose and therafter conclude with a multiple dose regimen with a preferably shorter time interval or vice versa.

In addition, a long plasma elimination half-life (15 to 30 hours) was observed which allows for longer than daily treatment intervals in future therapeutic applications. The results of the multiple dose groups together with the long plasma half life teach application intervals between 1 and 8 days, more preferably between 2 and 7 days and most preferably betweeen 3 and 6 days.

Analysis of all dose groups showed that Solulin exhibited a linear pharmakokinetics demonstrating low interidividual differences in the metabolism of Solulin. Based on the linear pharmakokinetics and the broad therapeutic window a fixed dose application is more prefered than a body weight dose application, which is more convenient for the physician and patients and significantly reduces the risk of over- or underdosing. Thus, according to the invention a ready-to-use pharmaceutical composition with a fixed thrombomodulin dose is provided.

The excellent dose dependency of the Solulin effect that was observed for the inhibition of thrombin inhibition teaches the possiblity to adjust easily the dose for a patient based on diagnostic results (eg. coagulation parameters) or other clinical observations.

The methods according to the invention can be performed with any soluble thrombomodulin. Thrombomodulin in the context of the present invention is defined as any protein, including thrombomodulin modifications, analogues, variants, fragments and derivatives thereof, substantially showing the biological activity of native thrombomodulin regarding the capacity to form a functional complex with thrombin (all commonly referred to herein as thrombomodulin). According to the invention a “functional complex” with thrombin is any complex, which activates the protein C / protein S pathway.

Various forms of soluble thrombomodulin are known to the skilled person, e.g. the so called ART-123 developed by Asahi Corporation (Tokyo, Japan) or the recombinant soluble human thrombomodulin Solulin, currently under development by PAION Deutschland GmbH, Aachen (Germany). The recombinant soluble thrombomodulin, i.e. a soluble thrombomodulin without a modification of the amino acid sequence, is subject of the Asahi patent EP0 312 598

Solulin is a soluble, as well as protease and oxidation-resistant analogue of human thrombomodulin and thus exhibits a long life in vivo. Solulin’s main feature lies in its broad mechanism of action since it not exclusively inhibits thrombin. It also activates the natural protein C / protein S pathway, and therefore stops further generation of thrombin. Furthermore, Solulin exerts a neuroprotective effect (see e.g. EP 1 365 788), since binding of Solulin to thrombin prevents the latter from activating its Protease Activatable Receptors (PARs). Inhibition of PAR receptors in turn blocks apoptotic cell death.

Solulin is inter alia subject of the European patent 0 641 215 B1, EP 0 544 826 B1 as well as EP 0 527 821 B1.According to one embodiment of the invention, Solulin is administered to the patient. Solulin contains modifications compared to the sequence of native human thrombomodulin (SEQ. ID NO. 1) at the following positions: G –3V, Removal of amino acids 1-3, M388L, R456G, H457Q, S474A and termination at P490. This numbering system is in accordance with the native thrombomodulin of SEQ. ID NO. 1. The sequence of Solulin as the preferred embodiment of the invention is shown in SEQ. ID NO. 2.

However, notably, according to the invention also thrombomodulin analogues can be utilized, which comprise only one or more of the above mentioned properties, or of the properties outlined in the above mentioned European patent documents EP 0 544 826 B1, EP 0 641 215 B1 and EP 0 527 821 B1.

Particularly preferred thrombomodulin variants applicable according to the invention are those that have one or more of the following characteristics:

(i) they are oxidation resistant,

(ii) they exhibit protease resistance,

(iii) they have homogeneous N- or C-termini,

(iv) they have been post-translationally modified, e.g., by glycosylation of at least some of the glycosylation sites of native thrombomodulin (SEQ ID NO: 1),

(v) they have linear double-reciprocal thrombin binding properties,

vi) they are soluble in aqueous solution in relatively low amounts of detergents and typically lack a transmembrane sequence,

vii) they are lacking a glycosaminoglycan chain.

The manufacture of these analogues used in this invention is disclosed in the above mentioned European patent documents.

Most preferred is a molecule comprising all of these modifications, e.g. as shown by Solulin..

In a further embodiment of the invention, the thrombomodulin analogue known from the WO 01/98352 A2 or US 6,632,791 can be used. In another embodiment of the invention rabbit derived thrombomodulin can be used. The 6EGF fragment of Solulin is an example of a thrombomodulin fragment with essentially the same biological activity regarding the formation of a complex with thrombin with the ability to activate human protein C. This fragment essentially consists of the six epithermal growth factors domain of native thrombomodulin.

I. EXAMPLE

Photothrombotic Model of Ischemic Stroke: Thrombomodulin Added Prior to Arterial Occlusion

Using a model of photothrombotic occlusion of the middle cerebral artery the ability of soluble thrombomodulin (Solulin) to interfere with thrombosis was tested. The drug was added prior to occlusion of the middle cerebral artery.

1. Test system

The study was conducted in male mice, C57BL/6 strain. The average body weight of the animals at the time of allocation was 26 grams. The age of the animals was approximately 10 weeks.

2. Experimental procedures

Stroke model

The mice were anesthetized with 90mg/kg intraperitoneal chloral hydrate Morton Grove Pharmaceutical Morton Grove, IL) and then placed securely under a dissecting microscope (Nikon SMZ-2T, Mager Scientific, Inc.). After exposing the left middle cerebral artery (MCA), a laser Doppler flow probe (Type N (18 gauge), Transonic Systems) was attached to the surface of the exposed skull over the cerebral cortex located 1.5 mm dorsal median from the bifurcation of MCA. The probe was connected to a flowmeter (Transonic model BLF21) and records were made using a continuous data acquisition program (Windaq, DATAQ Instruments). A 1.5 mW green light laser (540 nm, Melles Griot) was directed at the MCA from a distance of 6 cm and Rose Bengal (Fisher Scientific) diluted to 10 mg/mL in PBS was then injected into the tail vein with the final dose of 50 mg/kg. The laser was then continued for 10 minutes after occlusion. The tissue perfusion rate of the cerebral cortex was monitored continuously with the laser doppler flow meter and recorded for approximately 2-3 hours. Stable occlusion was achieved if the tissue perfusion rate was reduced by 70 % or more of its original value.

Study treatment and observations

30 min before induction of thrombus formation by laser irradiation, rats received bolus injections of Solulin (1 or 3 mg/kg) or vehicle in equal volumes (100 µl/kg). The time to thrombus formation was assessed by Laser Doppler measurement. The laser measurements were continued for at least 150 min after injection of Solulin or vehicle. The experiments were terminated approximately 2 hours after Solulin or vehicle administration by sacrificing the surviving animals

Data analysis

Tissue perfusion units (TPU) were recorded using DATAQ Instruments Win DAQ Serial Acquisition.

Occlusion time

Time needed for occlusion was calculated as the time between injection of Bengal red and stable occlusion. The latter was assumed when a 70% or higher reduction of blood flow had prevailed for 5 min. Times were read directly off the tracing and converted to number format.

Determination of blood flow

Blood flow data was compressed (~ 20 points per second) and saved as a CSV file. Raw data was graphed and irregular points were deleted. The flow data was normalized to a percentage using the average TPU value from 10 minutes before Rose Bengal injection to the injection. Area under the curve was calculated from the normalized flow from the Rose Bengal injection to 120 minutes using GraphPad Prism. In cases in which blood flow data became unavailable for technical reasons or death of the animal, a value of zero was assumed from that time point on.

Statistics

A two tailed tTest was used to determine significance. For each test measure, probability values of p ................
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