WO2006064686A1 - Drug and method for preventing or relieving delayed nerve cell death - Google Patents

Abstract

A method of preventing or relieving delayed nerve cell death occurring in nerve cells due to ischemia caused by blood flow disorder and post-ischemic reperfusion; a drug for preventing or relieving the delayed nerve cell death as described above and thus treating a cerebrovascular disease caused by the cell death; a method of evaluating the cell death as described above; and a method of screening a factor preventing or relieving delayed nerve cell death.

Description

 Specification

 Drugs and methods for protecting or remedying delayed neuronal death

 [0001] The present invention relates to a method for protecting or relieving delayed cell death of nerve cells caused by ischemia due to blood flow disorder and reperfusion after ischemia, and protecting or relieving the delayed cell death. Therefore, the present invention relates to a drug for treating cerebrovascular diseases caused by the cell death. Furthermore, the present invention relates to a method for evaluating the above-mentioned cell death and a method for screening an agent that protects or rescues delayed neuronal cell death. Background art

 [0002] Cerebrovascular disease is one of the top causes of death in Japan. It is well known that cerebral blood flow blockage (cerebral ischemia) due to many cerebral infarctions and myocardial infarctions causes neuronal cell death (for example, see Non-Patent Document 1 and Non-Patent Document 2). Cerebral ischemic damage and ischemia · reperfusion injury (ie, damage caused by post-ischemic reperfusion) or hypoxic damage and hypoxia, reoxygenation damage (ie, reoxygenation after hypoxia) Neuronal cell death caused by the resulting disability significantly affects the patient's prognosis. However, at present, most of the methods applied to suppress neuronal cell death caused by ischemia / reperfusion that cause cerebral infarction, etc., are treated in the acute phase (for example, hyperbaric oxygen therapy, urokinase). Thrombolytic therapy with edaravone and radical scavenging with edaravone), and there is a need for a therapeutic method and Z or therapeutic agent for rapid treatment during cerebral ischemia (for example, Non-Patent Document 3 and Non-Patent Document) (See 4). So far, many efforts have been made to develop drugs to protect and Z or suppress the neuronal cell death caused by this ischemia 'reperfusion, but have yet to be decisive! / Wow! / ヽ

[0003] Cerebral ischemia · It does not occur rapidly after reperfusion! /, Cell death that occurs after several days, or the existence of so-called delayed neuronal cell death is known! (Ref. 5 and Non-Patent Document 6). The present inventors have found that a fish larva extract mainly composed of nucleic acids and protamine has an inhibitory effect on delayed neuronal cell death caused by ischemia. (See Patent Document 1). This delayed neuronal cell death is considered to be a cell death that can be rescued because of its slow development. This late cell death is known to include the phenomenon of apoptosis (see Non-Patent Document 7). Apoptotic cell volume induced by non-ischemic stimulation induced by mitochondria-mediated stimulant (Staurosporin: STS), death receptor-mediated stimulant (Tumor Necrosis Factor—a: TNFα), or Fas ligand in cultured cells It is clear that the decrease (Apoptotic Volume Decrease: AV D) involves KC1 efflux due to the action of Cl_ and K + channels (see Non-Patent Document 8). The inventors of the present invention performed apoptosis by the above-described apoptosis-inducing agent by directly administering to a culture supernatant a drug that blocks the volume-sensitive C1-channel function of the carboxylic acid or stilbene derivative used in the present invention in cultured cells. Inventing a method to prevent the disease, mentioning the possibility of cell death caused by cerebral ischemic disease, cardiac ischemic disease, neurodegenerative disease and congestive heart failure (see, for example, Patent Document 2). However, it cannot be proved to anyone whether the delayed neuron death caused by ischemic stimulation in an individual can be protected by the invention described in Patent Document 2, and is merely a prediction. In addition, it has been reported that C1-channel blockers (administered before and after heart transplantation) act in a suppressive manner on neuronal apoptotic cell death that occurs during ectopic transplantation of rat heart (non-transplantation) (See Patent Document 9). However, development of a method for preventing or relieving cerebral ischemia 'reperfusion late neuronal death in individuals using a method aimed at suppressing volume-sensitive C1-channels has not yet been performed. .

It is well known that protein tyrosine kinase (PTK) is involved in the function of volume-sensitive C1-channel (for example, see Non-Patent Document 10). In addition, it is known that cerebral circulation is improved by inhibiting hemorrhoids, and as a result, neuronal cell death is suppressed (see Non-Patent Document 11). It is also known to be deceived (see Non-Patent Document 12). However, it is not known at all that hippocampal neurons have volume-sensitive C1-channels, and that acupuncture acts to suppress these hippocampal volume-sensitive C1-channels. That is, the protective action against nerve cell death based on the control of the hippocampal volume-sensitive C1-channels , Not at all known. In other words, the development of a method for protecting or relieving ischemia 'reperfusion late neuronal death targeting PTK inhibitors with a focus on functional control of volume-sensitive C1-channels has not yet been developed. I have not been told.

 [Patent Document 1]

 JP 2004-196701 (released July 15, 2004)

 [Patent Document 2]

 JP 2002-3402 (published January 9, 2002)

 [Non-Patent Document 1]

 izushima H, Zhou CJ, Dohi K, Horai R, Asano M, Iwakura Y, Hirabayashi T, Ara ta S, Nakajo S, Takaki A, Ohtaki H, Shioda S. (2002) "Reduced postischemic apoptosis in the hippocampus of mice deficient in interleuKin- 1, J. Comp. Neurol. 448: 20 3-216.

 [Non-Patent Document 2]

 De Keyser J, Suiter G, Luiten PG (1999) "Clinical trials with neuroprotective drug s in acute ischaemic stroke: are we doing the right thing? Trends Neurosci. 22: 53 5-540.

 [Non-Patent Document 3]

 Schaller B, Graf R. (2004) "Cerebral ischemia and reperfusion: the pathophysiologi c concept as a basis for clinical therapy. J. Cereb. Blood Flow Metab. 24: 351—371

[Non-Patent Document 4]

 Beresford IJ, Parsons AA, Hunter AJ. (2003) "Treatments for stroke. Expert. Opin. Emerg. Drugs. 8: 103-122.

 [Non-Patent Document 5]

 Κιπηο T. (1982) "Delayed neuronal death in the gerbil hippocampus following ische mia Brain Res. 239: 57—69 ·

 [Non-Patent Document 6]

Κιπηο T. (2000) "Delayed neuronal death.〃 Neuropathology. 20 (Suppl): S95— S97. [Non-Patent Document 7]

 Zheng Z, Zhao H, Steinberg K, Yenari MA (2003) and ellular and molecular events underlying ischemia Induced neuronal apoptosis "Drug News Perspect. 16: 497-503

[Non-Patent Document 8]

 Maeno E, Ishizaki Y, Kanaseki T, Hazama A, Okada Y. (2000) 〃Normotonic cell sh rinkage because of disordered volume regulation is an early prerequisite to apoptosis, Proc. Natl. Acad. Sci. USA 97: 9487-9492.

 [Non-Patent Document 9]

 Mizoguchi K, Maeta H, Yamamoto A, Oe M, Kosaka H. (2002) "Amelioration of myocardial global ischemia / reperfusion injury with volume-regulatory chloride channel inhibitors in vivo. Transplantation. 73: 1185-93.

 [Non-Patent Document 10]

 Abdullaev IF, Sabirov RZ, Okada Y. (2003) "Upregulation of swelling- Lctivated CI channel sensitivity to cell volume by activation of EGF receptors in murine mamma ry cells.〃 J. Physiol. 549: 749-758.

 [Non-Patent Document 11]

 Paul R, Zhang Z, Enceri BP, Jiang Q, Boccia AD, Zhang RL, Chopp M, Cneresh DA. (2001) 〃Src deficiency or blockade of Src activity in mice provides cerebral prot ection following stroke, Nat. Med. 7: 222-227.

 [Non-Patent Document 12]

 Hon XY, Zhang GY, Yah JZ, Lin Y. (2003) "Increased tyrosine phosphorylation of alpha (lC) subunits of L-type voltage-gated calcium channels and interactions amon g Src / Fyn, PSD— 95 and alpha (l ) in rat hippocampus after transient brain ischemia. "Brain Res. 979: 43-50.

As described above, delayed neuronal cell death is cell death that occurs several days after ischemia / reperfusion. Drugs that are effective in preventing or remedying such delayed neuronal cell death have been completely displayed! Power against apoptosis-like neuronal death involving late neuronal death Drugs aimed at inhibiting apoptosis based on the inhibition of the spurase pathway may be under development, but due to the complex and diverse pathways of cell death, clinical applications are still in progress! ,. On the other hand, PTK inhibitors aimed at inhibiting metastasis of malignant tumors (ie cancer) have been developed, but no drugs for cerebral ischemic neuronal cell death have been developed.

 [0007] The present invention pays attention to the activity control of the C 活性 channel activated by the cell death signal, and a PTK inhibitor considered to be able to control the C 厂 channel blocker and the C1-channel.

, To provide a completely new method of protecting and Z or remedying delayed cell death of nerve cells due to ischemia / reperfusion by intravenous administration, as well as an agent for inhibiting delayed neuronal cell death and the inhibition of cell death The purpose is to provide a therapeutic drug for diseases caused by late-onset cell death.

 Disclosure of the invention

 [0008] The drug according to the present invention is characterized in that it contains a C-blocker or a PTK inhibitor in order to protect or rescue nerve cell death under reperfusion conditions after cerebral ischemia.

 [0009] In the drug according to the present invention, the neuronal cell death is preferably delayed neuronal cell death in an individual.

 [0010] In the drug according to the present invention, the neuronal cell death is preferably accompanied by fragmentation of nuclear DNA.

 [0011] In the drug according to the present invention, the neuronal cell death is preferably accompanied by a marked decrease in the release of cytochrome c from mitochondria.

[0012] The drug according to the present invention is preferably accompanied by an improvement in a decrease in cerebral blood flow that occurs during cerebral ischemia and reperfusion after ischemia.

[0013] In the drug according to the present invention, the C1-channel blocker is preferably 4,4′-diisothiocy anostilbene-2,2,1 disulf onic acid (DIDS).

[0014] The drug according to the present invention! The PTK inhibitor is preferably genistein ヽ

[0015] In the drug according to the present invention, when the neuronal cell death is cerebral infarction or myocardial infarction, Or it is preferable to occur during cerebral ischemia or reperfusion after cerebral ischemia, which occurs during heart transplantation or cerebrovascular anastomosis.

[0016] The method for protecting or relieving neuronal cell death according to the present invention includes the step of administering a C1-channel blocker or a PTK inhibitor to neurons under reperfusion conditions after ischemia. It is characterized by

 [0017] In the method according to the present invention, the neuronal cell death is preferably delayed neuronal cell death.

 [0018] In the method according to the present invention, the neuronal cell death is preferably accompanied by fragmentation of nuclear DNA.

 [0019] In the method according to the present invention, the neuronal cell death is preferably accompanied by a remarkable decrease in the activity of mitochondrial release of cytochrome c causing cell death.

 In the method according to the present invention, the C1-channel blocker is preferably 4, 4′-diisothiocy anostilbene-2, 2, 1 disulf onic acid (DIDS).

 [0021] In the method according to the present invention, it is preferable that the PTK inhibitor is genistein!

[0022] In the method according to the present invention, the neuronal cell death is caused by cerebral infarction or myocardial infarction, or at the time of cerebral ischemia or reperfusion after cerebral ischemia that occurs during heart transplantation or cerebral vascular anastomosis. Preferred to occur ,.

 [0023] The method for evaluating neuronal cell death under reperfusion conditions after ischemia using the individual according to the present invention measures cell death when a C1-channel blocker or a protein tyrosine kinase inhibitor is used. And comparing the measured value obtained by the above measurement with a reference value obtained by measuring cell death in the case where a C1-channel blocker or a protein tyrosine kinase inhibitor is not used. Yes.

In the method for evaluating neuronal cell death according to the present invention, the neuronal cell death is preferably cerebral ischemic delayed neuronal cell death.

[0025] The method for evaluating neuronal cell death according to the present invention is performed at the time of cerebral ischemia or myocardial infarction, or at the time of cerebral ischemia or reperfusion after cerebral ischemia that occurs during cardiac transplantation or cerebral vascular anastomosis. It is preferable to evaluate the survival rate of nerve cells. [0026] The method for evaluating neuronal cell death according to the present invention is preferably performed using the above-described process capability of measuring cell death as an indicator of the activity of mitochondria dehydrogenase.

[0027] In the method for evaluating neuronal cell death according to the present invention, the step of measuring the cell death comprises a nuclear DN.

It is preferable to perform fragmentation of A as an index.

[0028] Preferably, the method for evaluating neuronal cell death according to the present invention further includes a step of measuring a change in cerebral blood flow.

[0029] Preferably, the method for evaluating neuronal cell death according to the present invention further includes a step of temporarily reopening the both common carotid arteries after the mice are temporarily blocked.

[0030] The screening method according to the present invention is for screening in vitro for a factor that protects or rescues delayed cell death of neurons.

 Preparing cells for culturing;

 A hypoxic treatment step of culturing the cells under hypoxic or anoxic conditions in a medium not containing glucose;

 A reoxygenation step of culturing cells subjected to the ischemia treatment under aerobic conditions in a medium containing glucose; and

 Measuring cell death

 Including

 Compare cell death measured at the hypoxia treatment step or reoxygenation treatment step or before and after adding a candidate factor into the medium with cell death measured without adding the candidate factor. Process

 It is characterized by further including.

[0031] In the screening method according to the present invention, the step of measuring cell death includes mitochondrial dehydrogenase activity, nuclear DNA fragment i, caspase activity, mitochondrial force, and release of cytochrome c into the cytoplasm. Alternatively, it is preferable to use changes in the shape of the nucleus as an index.

[0032] Still other objects, features, and advantages of the present invention will be sufficiently enhanced by the following description. The benefits of the present invention will become apparent from the following description with reference to the accompanying drawings.

Brief Description of Drawings FIG. 1 is a schematic diagram showing an experimental schedule using a transient mouse both common carotid artery occlusion forebrain ischemia model.

 FIG. 2 is a graph showing volume-sensitive C1-current in mouse hippocampal primary cultured neurons. A is a view showing a state in which a gradually activated current is observed when a low osmotic pressure is applied to a mouse hippocampal primary cultured neuron under a whole cell patch clamp. B is a graph showing the current characteristics observed in A. FIG. C is a graph showing that the current observed in A is outwardly rectifying. D is a graph showing that the activity of hippocampal neurons is suppressed by volume-sensitive C channel inhibitor DIDS. E is a graph showing that the activity of hippocampal neuronal cells is suppressed by the volume sensitive C1-channel inhibitor genistein.

[FIG. 3] A is a photograph comparing the hippocampal CA1 region on day 4 of cerebral ischemia 'reperfusion morphologically stained with toluidine blue staining. B compares the hippocampal CA1 region of cerebral ischemia 'reperfusion day 4 with morphological staining with toluidine blue staining when DIDS (0.48 mg / kg) was administered 15 minutes before and after reperfusion It is a photograph. Furthermore, it is a photograph comparing the hippocampal CA1 region on day 4 of cerebral ischemia 'reperfusion with morphological staining by toluidine blue staining when DIDS (12 mgZkg) was administered 15 minutes before ischemia and after reperfusion. D is a photograph comparing morphological staining of the hippocampal CA1 region on day 4 of cerebral ischemia 'reperfusion with toluidine blue staining when DIDS (60 mg / kg) was administered 15 minutes before and after reperfusion. is there. E shows cerebral ischemia 'reperfusion day 4 hippocampal CA1 region morphologically stained with toluidine blue staining when Genistein (0.24 mgZkg) was administered 15 minutes before and after reperfusion. It is a photograph. F shows cerebral ischemia 'reperfusion day 4 hippocampal CA1 region morphologically stained with toluidine blue staining when Genistein (6.0 mg / kg) was administered 15 minutes before and after reperfusion It is a photograph. G shows cerebral ischemia 'reperfusion day 4 hippocampal CA1 region morphologically stained with toluidine blue staining when Genistein (30 mg / kg) was administered 15 min before and after reperfusion It is a photograph. H shows a comparison of morphological staining of the hippocampal CA1 region on day 4 of cerebral ischemia / reperfusion when Daidzein (6. OmgZkg) was administered 15 minutes before ischemia and after reperfusion. It is. FIG. 4 is a graph comparing the number of remaining normal neurons in the hippocampal CA1 region on day 4 of cerebral ischemia / reperfusion shown in FIG.

 FIG. 5A is a photograph of the hippocampal CA1 region on day 4 of cerebral ischemia 'reperfusion stained with Fluoro-JadeB (FJB) staining. B: Staining the hippocampal CA1 region on day 4 of cerebral ischemia / reperfusion with Fluoro-JadeB (F JB) staining when DIDS (0.48 mg / kg) was administered 15 minutes before and after reperfusion It is a photograph. C is a photograph of the hippocampal CA1 region on day 4 of cerebral ischemia 'reperfusion stained with Fluoro-JadeB (FJB) when DIDS (12 mg / kg) was administered 15 minutes before and after reperfusion. is there. D is a photograph of the hippocampal CA1 region on day 4 of cerebral ischemia 'reperfusion stained with Fluoro-JadeB (FJB) when DIDS (60 mg / kg) was administered 15 minutes before and after reperfusion. It is. E is a photograph of the hippocampal CA1 region stained with Fluoro-JadeB (FJB) staining on day 4 of cerebral ischemia / reperfusion when Genistein (0.24 mgZkg) was administered 15 minutes before and after reperfusion. is there. F is a photograph of the hippocampal CA1 region stained with Fluoro-JadeB (FJB) stained on day 4 of cerebral ischemia 'reperfusion when Genistein (6. OmgZkg) was administered 15 minutes before ischemia and after reperfusion. is there. G is a photograph of the hippocampal CA1 region on day 4 of cerebral ischemia 'reperfusion stained with Fluoro-JadeB (FJB) when Genistein (30 mgZkg) was administered 15 minutes before and after reperfusion. . H shows the hippocampal CA1 region on day 4 of cerebral ischemia / reperfusion when Daidzein (6. Omg / kg) is administered 15 minutes before and after reperfusion is stained with Fluoro-JadeB (FJB) staining It is a photograph.

 FIG. 6 is a graph comparing the number of FJB positive cells in the hippocampal CA1 region on day 4 of cerebral ischemia / reperfusion shown in FIG.

 FIG. 7 is a photograph showing the result of cytochrome c imnob fitting in the cytoplasmic fraction of the hippocampal region after cerebral ischemia / reperfusion.

 FIG. 8 is a graph comparing local cerebral blood flow in the cerebral cortex in the middle cerebral artery region during cerebral ischemia / reperfusion.

BEST MODE FOR CARRYING OUT THE INVENTION

No effective drug has been developed to protect or rescue late neuronal cell death. The present inventors have intensively studied to solve the above problems. Specifically, book The inventors used mouse hippocampal primary cultured neurons,

 (1) Is there a volume-sensitive C1-channel in mouse hippocampal primary cultured neurons?

(2) If present, is the volume-sensitive C1-channel of mouse hippocampal primary cultured neurons suppressed by the above-mentioned C1-channel blockers and PTK inhibitors?

 Was examined. Furthermore, using a transient mouse cerebral ischemia model,

 (3) Mouse cerebral ischemia · Whether reperfusion delayed neuronal death can be suppressed by administering C1-channel blocker;

 (4) Mouse cerebral ischemiaReperfusion late neuronal death Whether or not it can be suppressed by administering a PTK inhibitor,

 (5) Murine cerebral ischemia · Whether apoptosis that occurs during induction of reperfusion delayed neuronal death can be suppressed,

 (6) Cerebral ischemia · Whether cerebral blood flow during reperfusion can be improved

 Was examined.

 [0035] As a result, the present inventors have revealed for the first time that volume-sensitive C1-channel exists in neurons in the hippocampal region of mice. Furthermore, the present inventors have shown that the volume-sensitive C1-channel can be inhibited by administering a C 厂 channel blocking force or using a PTK inhibitor.

 [0036] Further, based on these findings, the present inventors used a cerebral ischemia / reperfusion model when both the common carotid arteries of a mouse were temporarily blocked and then reopened. Delayed neuronal cell death, morphological histological observation of living cells and Z or degenerated neurons, increased cytochrome c in the cytoplasm! ] Or by measuring local cerebral blood flow.

 As a result, the present inventors have found that delayed neuronal cell death that occurs during cerebral infarction or myocardial infarction, or at the time of cerebral ischemia or reperfusion after cerebral ischemia in heart transplantation or cerebral vascular anastomosis A therapeutic drug and Z or protective drug for this drug was found, and a method for determining the effect of the drug was established.

[0038] According to the present invention, delayed neuronal cell death caused by cerebral ischemia / reperfusion is suppressed by repeatedly administering a C1-channel blocker or a PTK inhibitor into the vein. can do. This rescue mechanism is responsible for apoptotic cell volume reduction (AVD This is thought to be achieved by suppressing the activity of the volume-sensitive Cl_ channel that leads to Thus, the present invention is directed against ischemia / reperfusion neuronal injury targeting volume sensitive C1-channel activity, which is an early reaction of late neuronal cell death, and its activity signal. Provide new defense methods.

 [0039] As used herein, a "neural cell" is a neuron in vivo or a commercially available cultured cell derived from a neuron, or a brain derived from a biological force. Even primary cultured neurons.

 [0040] As used herein, the term "ischemic 'reperfusion experimental system" refers to ischemic culture cells or mice that are in vitro systems using cultured cells or in vivo systems using mice.

Experimental systems that allow reperfusion (or reoxygenation and glucose re-administration) treatment after treatment (or oxygen removal and glucose removal) are contemplated. In addition, as used herein, the term “ischemia / reperfusion” intends reperfusion performed after ischemia.

 [0041] (1) Agent and method for protecting or relieving neuronal cell death

 The present invention provides a drug for suppressing nerve cell death and a method for suppressing nerve cell death using the drug. Nerve cell death occurs in various parts of the brain and causes various diseases.In particular, late neuronal cell death is considered to be a cell death that can be rescued due to its slow development. If such a means for suppressing cell death can be developed, an effective therapeutic or preventive agent for various diseases caused by the cell death can be obtained, which can be said to be very beneficial.

 [0042] The agent according to the present invention is characterized by comprising a C1-channel blocker or a protein tyrosine kinase (PTK) inhibitor. In one embodiment, C1—channel blocking force, 4, 4—diisothiocyanostilbene—2, 2′—disulfonic acid (DIDS) is preferred. In other embodiments, the PTK inhibitor is preferably genistein.

[0043] Preferably, according to the embodiment, the agent according to the present invention suppresses neuronal cell death caused by ischemia or reperfusion after ischemia, particularly delayed neuronal cell death (ie, protection or Can be used to rescue. Neuronal cell death caused by ischemia or post-ischemic reperfusion may include cerebral or myocardial infarction or heart transplantation or cerebral vascular anastomosis Neuronal cell death that occurs during cerebral ischemia or reperfusion after cerebral ischemia.

 [0044] As described above, it is known that apoptosis is involved in the induction of delayed neuronal cell death. As used herein, the term “apoptosis” is used interchangeably with “cell death by apoptosis” or “apoptotic cell death”.

 [0045] The agent according to the present embodiment is preferably used for suppressing apoptosis of nerve cells caused by ischemia or reperfusion after ischemia. More preferably, the agent according to this embodiment can be used to suppress apoptosis induced by abnormalities occurring during ischemia in nerve cells. Abnormalities that occur during ischemia include, but are not limited to, cell swelling, tissue edema, and tissue destruction.

 [0046] As used herein, the term "ischemia" intends local ischemia. When ischemia occurs, the surrounding tissue changes in various ways (eg, apoptosis or necrosis) depending on the duration of ischemia, the sensitivity of the tissue to ischemia, or the presence or absence of vascular anastomoses at the site. ) Is generated. As used herein, the term “ischemic injury” intends an injury caused by an abnormality that occurs in a tissue due to ischemia. Forces that cause various abnormalities in tissues due to ischemia Usually, ischemic injury includes neuronal cell death and apoptotic cell volume reduction (AVD), and damage caused by post-ischemic reperfusion is also Included in injury. A disease (disorder) that is a treatment target of the drug according to the present invention may be one of the above ischemic disorders, a combination of a plurality of ischemic disorders, or a combination with another disease. Moyo.

 [0047] When assessing apoptotic cell death, a marked increase in nuclear DNA fragmentation or mitochondrial force cytochrome c release into the cytoplasm can be used as an indicator. If such a phenomenon is observed, it can be judged that the cell death rate is high.

 [0048] It should be noted that a person skilled in the art who has read this specification is that C1-channel blockers or protein tyrosin kinase (PTK) inhibitors are effective only against cell death caused by ischemia or post-ischemic reperfusion. It is easy to understand that it is effective for apoptotic cell death caused by other causes.

[0049] The present invention further provides a drug for preventing a disease caused by apoptosis. " Examples of diseases caused by apoptosis include, but are not limited to, cerebral infarction, myocardial infarction, vascular dementia, neurodegenerative diseases such as Alzheimer's disease, autoimmune diseases such as rheumatoid arthritis, and senile alopecia. .

 [0050] The drug according to the present invention is a mammal (human, mouse, rat, usagi, inu, cat, ushi, horse.

, Pigs, monkeys, etc.).

[0051] The agent according to the present invention includes C1-channel blocker or protein tyrosine kinase (

PTK) inhibitors may be used as is, but may contain a pharmaceutically acceptable carrier. The drug according to the present invention can be produced according to a known method as a method for producing a pharmaceutical composition.

 [0052] According to one embodiment, the medicament according to the present invention may be a pharmaceutical composition. The pharmaceutically acceptable carrier used in the pharmaceutical composition can be selected according to the dosage form and dosage form of the pharmaceutical composition.

 [0053] As used herein, pharmacologically acceptable carriers include various organic or inorganic carrier materials that can be used as pharmaceutical materials, and excipients in solid formulations, It is incorporated as a lubricant, binder, or disintegrant, or as a solvent, solubilizer, suspension, isotonic agent, buffer, or soothing agent in a liquid preparation.

 [0054] Examples of the excipient include lactose, sucrose, D-manntol, xylitol, sorbitol, erythritol, starch, crystalline cellulose and the like, and examples of the lubricant include magnesium stearate and calcium stearate. , Talc and colloidal silica.

 [0055] Examples of the binder include pregelatinized starch, methylcellulose, crystalline cellulose, sucrose, D-mannitol, trenorose, dextrin, hydroxypropylcellulose, hydroxypropylmethylcellulose, polybulurpyrrolidone, and the like.

 [0056] Examples of the disintegrant include starch, carboxymethylcellulose, low-substituted hydroxypropinoresenorelose, canoleoxymethinoresenorelose canolecium, croscanolemellose sodium, carboxymethyl starch sodium, and the like. It is done.

[0057] Examples of the solvent include water for injection, alcohol, propylene glycol, macrogol, sesame oil, corn oil, tricaprylin and the like. [0058] Examples of solubilizers include polyethylene glycol, propylene glycol, D-mann-tol, trehalose, benzyl benzoate, ethanol, trisaminomethane, cholesterol, triethanolamine, sodium carbonate, citrate. Sodium etc. are mentioned.

 [0059] Examples of the suspending agent include surfactants such as stearyltriethanolamine, sodium lauryl sulfate, laurylaminopropionic acid, lecithin, benzalkonium chloride, benzethonium chloride, and glyceryl monostearate. Alternatively, hydrophilic polymers such as polyvinyl alcohol, polyvinyl pyrrolidone, sodium carboxymethyl cellulose, methyl cellulose, hydroxy methenoresenorelose, hydroxyethinoresenorelose, and hydroxypropinoresenorelose can be used.

 [0060] Examples of the isotonic agent include sodium chloride salt, glycerin, D-manntol and the like.

 [0061] Examples of the buffer include buffer solutions of phosphate, acetate, carbonate, citrate, and the like.

 [0062] Examples of the soothing agent include benzyl alcohol.

[0063] Examples of the preservative include noroxybenzoates, chlorobutanol, benzyl alcohol, phenethyl alcohol, dehydroacetic acid, sorbic acid and the like.

[0064] Examples of the antioxidant include sulfite and ascorbic acid.

[0065] The pharmaceutical composition according to the present embodiment can be produced according to a method commonly used in the field of pharmaceutical technology. In the pharmaceutical composition according to the present embodiment, the content of the C1-channel blocking force mono- or protein tyrosine kinase (PTK) inhibitor is determined using the pharmaceutical composition, which will be described later, in consideration of the administration form, administration method, etc. There is no particular limitation as long as the C1—channel blocker or protein tyrosine kinase (PTK) inhibitor can be administered in a range of amounts.

[0066] Examples of the dosage form of the pharmaceutical composition according to the present embodiment include tablets, capsules (including soft force capsules and microcapsules), powders, granules, syrups and other oral preparations, or Examples include parenteral preparations such as injections, suppositories, pellets, and drops. The term “parenteral” as used herein is intravenous, intramuscular, intraperitoneal, intrasternal, subcutaneous, and Refers to the mode of administration including intranodal injection and infusion.

 [0067] The dosage of the pharmaceutical composition according to this embodiment varies depending on the administration subject, administration route, symptom, and the like, but those skilled in the art will determine the optimal dose depending on the administration subject, administration route, symptom, etc. Appropriate conditions can be set as appropriate.

 [0068] The pharmaceutical composition according to this embodiment can be administered by an appropriate administration route according to the preparation form. The administration method is not particularly limited, and can be applied by internal use, external use or injection. The injection can be administered, for example, intravenously, intramuscularly, subcutaneously, intradermally, or the like.

[0069] The dosage of the pharmaceutical composition according to the present embodiment is appropriately set depending on the preparation form, administration method, purpose of use, and age, weight, and symptoms of the patient to whom the pharmaceutical is administered, and is not constant. In general, the dose of the active ingredient contained in the preparation is preferably 5 to 400 / ζ ₈ per day for an adult. Of course, since the dose varies depending on various conditions, an amount smaller than the above dose may be sufficient or may be necessary beyond the range. Administration may be carried out within a desired dose range, in a single day or in several divided portions. Moreover, the pharmaceutical composition according to the present embodiment can be administered orally as it is, or can be added daily to any food or drink.

 [0070] Thus, it can be said that the drug according to the present invention may contain at least a C1-channel blocker or a protein synthase (ΡΤΚ) inhibitor. That is, it should be noted that an agent containing a plurality of C channel blockers or protein tyrosine kinase (ΡΤΚ) inhibitors is also included in the technical scope of the present invention.

 [0071] By administering the drug according to the present invention, apoptotic cell death can be suppressed. In addition, administration of the drug according to the present invention can protect nerve cells during cerebral ischemia or reperfusion after cerebral ischemia that occurs during heart transplantation or cerebral vascular anastomosis. Furthermore, diseases caused by apoptosis can be treated by administering the drug according to the present invention.

 [0072] (2) Evaluation method of cell death caused by ischemia and reperfusion after ischemia

The present invention provides a method for evaluating neuronal cell death under reperfusion conditions after ischemia. The method for evaluating neuronal cell death under post-ischemic reperfusion conditions according to the present invention comprises cell death when a C1-channel blocker or a protein tyrosine kinase inhibitor is used. And a step of comparing the measured value obtained by the above measurement with a reference value obtained by measuring cell death in the case where a C1-channel blocker or a protein tyrosine kinase inhibitor is not used. It is a feature. In one embodiment, in the method for evaluating neuronal cell death according to the present invention, the neuronal cell death is preferably delayed neuronal cell death. Preferably, the neuronal cell death evaluation method according to the present embodiment is a neuronal cell during cerebral infarction or myocardial infarction, or at the time of cerebral ischemia or reperfusion after cerebral ischemia in heart transplantation or cerebral vascular anastomosis Assess the survival rate.

 [0073] The method for evaluating neuronal cell death according to the present invention is preferably performed by using the process power of measuring cell death as described above, and the activity of mitochondria dehydrogenase as an index, but by performing fragmentation of nuclear DNA as an index. Also good. The neuronal cell death evaluation method according to the present invention preferably further includes a step of measuring a change in cerebral blood flow.

 [0074] In one aspect, the present invention provides a method for evaluating cell death caused by ischemia and post-ischemic reperfusion in a system using cultured cells in the in vitro port.

 [0075] Hypoxia 'reoxygenation injury (ie, caused by reoxygenation after hypoxia) to induce ischemia · reperfusion injury (ie, damage caused by reperfusion after ischemia) You can induce a fault). In order to provide hypoxic or anoxic conditions using cultured cells, the cultured cells must be cultured in hypoxic or anoxic conditions without including dalcose! do it. The buffer solution used in this step is not particularly limited as long as it does not contain dalcose. In order to apply the reoxygenation condition, cells subjected to the hypoxic treatment (anoxic treatment) may be cultured in an aerobic condition in a medium containing glucose.

[0076] In addition, as used herein for cell culture under hypoxic conditions or anoxic conditions, the term "anoxic conditions" refers to an oxygen concentration of 1% or less. It is preferable that oxygen is hardly contained at all (0.01% or less). Accordingly, those skilled in the art will understand that the “anoxic conditions” described herein are cell cultures performed under carbon dioxide, nitrogen gas, and argon gas, for example, 95% argon gas + 5% carbon. It will be readily understood that the conditions of acid gas are also oxygen-free conditions. The instrument and Z or culture method used for cell culture are appropriately selected from those known in the art. It will be apparent to those skilled in the art that the choice may be made.

 [0077] By using the cell death evaluation method according to the present invention, the cell to be evaluated experiences reperfusion after ischemia. Therefore, by using the in vitro cell death evaluation method according to the present invention, cell death such as cell viability is evaluated before and after ischemia treatment or before and after reperfusion treatment after ischemia. By comparison, reperfusion cell death can be easily evaluated.

 In the in vitro cell death evaluation method according to the present invention, the cells to be evaluated are not particularly limited, and nerve cells, brain neurons, and brain glial cells are preferably used. Can do. By using nerve cells, cell death caused by ischemia or reperfusion after ischemia caused by cerebral infarction or myocardial infarction can be evaluated. By using cranial nerve cells or brain glial cells, it can be said that cell death caused by reperfusion after ischemia or ischemia caused by cerebral infarction or the like can be evaluated. In addition, as the above cells, commercially available cultured cells or primary cultured cells may be used.

 [0079] In the method for evaluating cell death according to the present invention, the step of detecting cell death is not particularly limited. For example, a method of performing mitochondrial dehydrogenase activity as an index (MTT method or MTS method), Methods that use nuclear DNA fragmentation as an indicator (such as DNA ladder testing), methods that use the activity of intracellular proteolytic enzymes (caspases) that cause cell death, and mitochondrial force that releases cytochrome c into the cytoplasm. Examples include an index method, and a method using an index of nuclear morphological change (for example, nuclear concentration or fragmentation).

[0080] Since the activity of mitochondrial dehydrogenase decreases when the cell dies, if the enzyme activity decreases using the activity of mitochondrial dehydrogenase as an index, it can be determined that the cell death rate is high.

 [0081] When cells are killed by necrosis, the cells cause membrane damage and are stained with propidium iodide (PI). At this time, if the nuclei of all cells are stained with Hoechst 33342, the proportion of cells that have undergone necrotic cell death can be calculated.

[0082] In addition, when cells are killed by apoptosis, nuclear DNA is fragmented, By observing the state of DNA in the nucleus on the ladder by electrophoresis or the like, it can be easily determined whether or not the cell is apoptotic.

[0083] Furthermore, when cells die due to apoptosis, caspase is activated (increases in activity). Therefore, if the enzyme activity increases with caspase activity as an index, apoptotic activity is increased. It can be determined that the cell death rate is high.

[0084] In addition, when cells are killed by apoptosis due to mitochondrial stimulation, cytochrome c is released into the cytoplasm as well as mitochondrial force. Therefore, mitochondrial force is also measured as cytochrome c release into the cytoplasm Can be easily determined whether the force is apoptotic cell death.

[0085] In addition, when cells die due to apoptosis, nuclear morphological changes such as nuclear concentration and fragmentation occur. Therefore, the nuclear morphological changes can be observed with an electron microscope or the like using the nuclear morphological changes as an index. For example, it can be easily determined whether apoptotic cell death occurs.

 [0086] In another aspect, the present invention provides a method for assessing cell death caused by ischemia and post-ischemic reperfusion in an in vivo animal system.

 [0087] As ischemia using mice and reperfusion after ischemia, if both common carotid arteries of the mouse are temporarily blocked and then reopened, use the cerebral ischemia / reperfusion model Is preferred.

 [0088] As a method for evaluating delayed neuronal cell death, it is preferable to use morphological histological observation of living cells and Z or degenerated neurons, increase of cytochrome c in the cytoplasm, or measurement of local cerebral blood flow. Better ,.

 [0089] The cell death evaluation method according to the present invention includes a method of transiently blocking both common carotid arteries of a mouse in order to successfully perform reperfusion after ischemia and ischemia of the mouse according to the present invention described above. After that, use the cerebral ischemia / reperfusion model.

 That is, the method for evaluating neuronal cell death under reperfusion conditions after ischemia according to the present invention measures cell death when using a C1-channel blocker or a protein tyrosine kinase inhibitor, and measures the measurement. Compare the value with the reference value.

[0091] (3) In vitro screening for factors that protect or rescue delayed cell death of neurons How to

 The present invention provides a method for screening in vitro a factor that protects or rescues delayed cell death of neurons. The screening method according to the present invention includes a step of preparing cells that can be cultured by preferably using a culture system. In order to lead the prepared cultured cells to delayed cell death, as described above, hypoxia's reoxygenation injury may be induced rather than induction of ischemia / reperfusion injury.

 [0092] In one embodiment, the screening method according to the present invention comprises a step of preparing a cell for culturing; the cell is subjected to hypoxic conditions or anoxic conditions in a glucose-free medium. Including a hypoxic treatment step of culturing in step 1; a reoxygenation step of culturing cells subjected to the ischemic treatment under aerobic conditions in a medium containing dalcose; and a step of measuring cell death, and Compare cell death measured at the time of the hypoxia treatment step or at the time of the reoxygenation treatment step, or before and after adding the candidate factor into the medium, to the cell death measured without adding the candidate factor. Process.

 [0093] According to the screening method of the present invention, the step of measuring cell death includes the mitochondrial dehydrogenase activity, fragmentation of DNA in the nucleus, caspase activity, and mitochondrial force as described above. The index may be the release of cytochrome c into the nucleus or the change in the shape of the nucleus.

 [0094] As described above, by using the "evaluation method of cell death caused by ischemia and reperfusion after ischemia" described in detail in (2), the delayed cell death of neurons is protected or rescued. Can be screened in vitro.

 [0095] Hereinafter, the present invention will be described in more detail with reference to Examples, but the present invention is not limited thereto.

 [0096] [Example]

 (1: Procedure)

 The expression of volume sensitive C1-channel-channel) in hippocampal neurons was confirmed by the following method.

[0097] Hippocampal neurons were isolated from the fetus from which the mouse force on the 16th day of pregnancy was also collected. The resulting primary cultured hippocampal neurons were added with 10% urchin fetal serum, streptomycin, and penicillin. In a Dulbecco essential medium, the cells were cultured at 37 ° C in a 5% CO incubator. Culture 5

 2

 Current measurement was performed using the whole cell patch clamp method applied to the hippocampal neurons on the 7th day. In the Notch clamp experiment, a solution having the following composition was used. For extracellular fluid, 124 mM N-methyl D glucamine (NMDG), 124 mM HC1, lOmM NaCl, 4 mM MgCl, 0.33 mM NaH PO, 0.5 mM EGTA, lOmM 2— [4— (2—

 2 2 4

 Hydroxyethyl) 1 piperazyl] ethanesulfonic acid (HEPES), 2 mM 4 aminobiperidine (4-AP), 5.5 mM glucose, and osmotic pressure was adjusted by adjusting the mannitol concentration (normal) Osmotic pressure solution: 315 mOsm, low osmotic pressure solution: 280 m Osm). 124 mM NMDG, 24 mM HC1, lOOmM aspartate, 2 mM MgCl, 5 mM Na ATP, 0.3 mM Na GTP, ImM EGTA, lOmM

 2 2 3

 Using HEPES, the osmotic pressure was adjusted to 300 mOsm. The pH (both extracellular and internal fluids) was adjusted to 7.4 using NMDG. After observing the time course of channel activation after forming the whole cell patch clamp mode, the current response was recorded by applying a test potential of ± 60 mV as the holding potential of 40 mV. In addition, in order to investigate the nature of the current after drug administration after normal osmotic pressure, low osmotic pressure stimulation, step responses from 100mV to + lOOmV were given as needed, and current responses were recorded.

[0098] To examine the effects of C1-channel blockers or PTK inhibitors on delayed neuronal cell death due to ischemia and reperfusion, both common carotid arteries of mice were occluded with cerebrovascular clips and the clips removed. We used a transient cerebral ischemia 'reperfusion model to reperfuse by.

[0099] Fig. 1 shows the protocol. Specifically, C57ZBL6Crj (9-: L 1 week old, male) and jugular vein force from DIAS (0.48, 12, 60 mg / kg), genistein (0.24, 6.0) from 20 minutes before ischemia 30 mgZkg) or daidzein (30 mgZkg) was administered at a flow rate of 0.8 LZ min Zg body weight (240-300 μLZ mice) for 15 min. The control group (vehicle) received a solution (PBS containing 10% DMSO and 10% polysorvate 80) without compound. Thereafter, cerebral ischemia / reperfusion was performed by occlusion of both common carotid arteries for 12 minutes. In order to prevent a decrease in body temperature, the animals were reared in a thermostatic bath at 1 ° C to 35 ° C and then raised at room temperature (24 ± 1 ° C) for 4 days. In a preliminary study, it was not possible to observe a protective effect against cell death only by a single administration before ischemia. In addition, by adding DMSO and polysorvate 80 in the solvent, Improved solubility in the liquid was obtained. Therefore, not only before ischemia but also on the first, second, and third days after ischemia, the same amount of compound as that administered intravenously was administered intraperitoneally. On day 4, the slaughtered and histological examination was performed.

 [0100] In these cerebral ischemia models, about 10% of the neurons died on the first day of ischemia and reperfusion, but on the fourth day, nearly 50% of the neurons were killed, so-called delayed onset. Neuronal cell death was observed.

 [0101] In addition, to elucidate whether this delayed neuronal death involves apoptosis and to investigate the effects of C1-channel blockers or PTK inhibitors on this mechanism, In the experimental model system, an increase in cytochrome c in the cytoplasmic fraction in the hippocampal region was observed by biochemical techniques (Western blotting). In addition, the effect of PTK inhibitors on cerebral blood flow was measured with a laser Doppler local blood flow meter. The local cerebral blood flow was measured as follows: 1. 6 to 9 left and right cerebral cortices in the middle cerebral artery region were measured with a laser diameter of Omm. Calculations were made assuming that 100% before compound administration.

 [0102] [2: Mouse hippocampal neurons have volume-receptive C1-channels]

 The existence of volume-sensitive C1-channels in neurons has been reported so far. This is because rat sympathetic neurons (Leaney JL, Marsh SJ, Brown DA. (1997) 〃A swelling-activated chlo ride current in rat sympathetic neurons. "J. Physiol. 501: 555—564.), rat carotid body type 1 neurosecretory cells (Carpenter E, Peers C. (1997)" Swelling- and camp-activated. 1 currents in isolated rat carotid body type I cells. See J. Physiol. 50 3: 497-511.) And mouse cerebellar granule cells (Patel AJ, Lauritzen I, Lazd unski M, Honore E. (1998) ) "Disruption of mitochondrial respiration inhibits volume- regulated anion channels and provokes neuronal cell swelling, j. Neurosci. 18: 3117 -3123.). We investigated whether to do this (Figure 2).

[0103] Volume-sensitive C1-channels have not been elucidated in molecular identity, so immunohistological techniques cannot be applied. Therefore, the expression was confirmed by current recording by the patch clamp method. [0104] As shown in Fig. 2A, when a low osmotic load was applied to mouse hippocampal primary cultured neurons under whole cell patch clamp, a gradually activated current was observed. The reversal potential of this activated current (= —36 mV) approximates the equilibrium potential of Cl_ (= —40 mV) and is high for positive rectification (> +80 mV) with outward rectification (Figure 2C). Shows inactivation (Figure 2B). All of these results are consistent with the volume sensitive C1-current characteristics. Thus, it was revealed that volume-sensitive C1-channels are present in mouse hippocampal primary cultured neurons.

 [3: Volume-sensitive C1-channel of mouse hippocampal primary neurons is suppressed by DIDS and enistein]

 Volume-sensitive C1-channel force in mouse hippocampal primary cultured neurons We confirmed whether it was suppressed by DIDS and genistein, which are known as inhibitors (Fig. 2). The inhibitory effect of 500 M DIDS was only seen on the positive potential and was voltage-dependent (Fig. 2D). In addition, suppression by 1OO ^ M genistein was independent of the potential, and it exhibited the suppression effect at all potentials except near the reversal potential (Fig. 2E). This force confirmed that DIDS and genistein reliably suppressed the volume-sensitive C1-channel of hippocampal neurons.

[4: Murine cerebral ischemic delayed neuronal cell death is rescued by C1-channel blocker]

 Apoptosis induced by staurosporine (STS) in cultured rat neurons is reported to be rescued by DIDS, a blocker of C1-channels (Ta nabe S, Maeno E, Okada Y (2002) Prevention of staurosporine- induced apoptotic cell death by DIDS and SITS in rat cardiomyocytes in primary culture. "Jpn. J. Physio 1. 52 (Suppl): S34). We investigated whether or not can be suppressed by Cl_ channel blocker.

[0107] As shown in Fig. 3, when neuronal death was induced by 12 minutes of ischemia, the nucleolus of the hippocampal _CA1 region neurons became unclear when morphologically observed by toluidine blue staining. Reduction of pyramidal cells was observed (Fig. 3, arrow A). The number of remaining morphologically normal cells per fixed area decreased from about 60 before cerebral ischemia (results not shown) to 37.1 (Figure 2, first bar graph). If DIDS (0.48, 12, 60 mgZkg), a C1-channel blocker, was administered 15 minutes before ischemia and after reperfusion, 0.48 mgZkg or When administered at 60 mgZkg, the effect was less pronounced (Figs. 3 and 5). However, the morphological change decreased in the 12 mg Zkg group (Fig. 3, D), and the number of remaining morphologically normal cells increased to 52.5 (Fig. 3, third bar graph).

 Furthermore, as shown in FIG. 3, when neuronal cells showing neurodegeneration (detected by Fluoro-JadeB staining) were observed, they were clearly strongly fluorescently stained in the hippocampal CA1 region of vehicle-treated mice. Denatured neurons were observed (Figure 5, arrow A). The number of degenerated neurons per unit area was 28.4 (Figure 6, first bar graph). When DIDS12mg Zkg was administered, the number of stained cells decreased (Figure 5, C). The number of degenerated neurons was clearly reduced to 12.0 (Fig. 6, third bar graph). These results indicate that DIDS, a C 厂 channel blocker, works rescued against delayed neuronal death after transient mouse cerebral ischemia.

 [4: Murine cerebral ischemic delayed neuronal cell death is rescued by PTK inhibitor]

 As shown in Figure 3, when a vehicle was administered 15 minutes before ischemia to induce 12 minutes of ischemic neuronal cell death, the number of morphologically normal cells remaining per fixed area was 37.1. (Figure 4, first bar graph). When the PTK inhibitor genistein (l.2, 6, 30 mgZkg) is administered 15 minutes before ischemia and 1, 2, and 3 days after reperfusion, the neuronal cells in the hippocampal CA1 region The number of remaining morphologically normal cells per unit area increased to 48.2, 50.8, and 55.7, respectively (Fig. 3, E, F, and G) (Fig. 4). , 5th, 6th and 7th bar graphs). When degenerated neurons were observed, clearly denatured neurons were observed in the hippocampal CA1 region of the vehicle-administered group (Fig. 5, A). When Genistein was administered, the appearance of degenerated neurons decreased (Figure 5, D, E, F). The number of degenerated neurons per unit area clearly decreased to 14.0, 11.7, and 5.8 in a concentration-dependent manner (FIG. 6, fifth, sixth, and seventh bar graphs). Furthermore, the administration group of daidzein (30 mgZkg), an analog without PTK activity of genistein, was unable to suppress the decrease in morphological normal cells and the increase in degenerated neurons (Fig. 3, H; Fig. 4). , Eighth bar graph; FIG. 5, H; FIG. 6, eighth bar graph). These results indicate that genistein, a PTK inhibitor, has a rescue action against delayed neuronal cell death after transient mouse cerebral ischemia.

[0110] [5: Apoptosis caused by mouse cerebral ischemic delayed neuronal cell death is C1-channel block force Suppressed by one or PTK inhibitor)

 In the process of apoptotic cell death, it is known that the release of cytochrome c from the mitochondria to the cytoplasm is the most important phenomenon for the appearance of cell death (see Non-Patent Document 7). DIDS has also been reported to rescue apoptosis induced by staurosporine (STS) in cultured rat neurons (Tanabe S, Maeno E, Okada Y (2002) Prevention of staurosporme- induced apoptotic cell death by DI DS and SITS in rat cardiomyocytes in primary culture. "Jpn. J. Physiol. 52 (Suppl): S 34).

 [0111] In the hippocampal cytoplasm after induction of transient cerebral ischemia, an increase in cytochrome c (cyt-c) was observed (Fig. 7, vehicle administration group (1 to 4 lanes)). 15 minutes before induction of transient cerebral ischemia C1—channel blocker (Figure 7, 5th to 8th lanes (DIDS (12mg / kg))) or PTK inhibitor (Figure 7, 9th to 12th) In the brain hippocampus region of mice administered lane (genistein (30 mg / kg))), the increase in cytochrome c was suppressed. These results indicate that the C1-channel blocker DIDS or the PTK inhibitor genistein has a rescue action against apoptosis following transient mouse cerebral ischemia.

 [0112] [6: Decrease in cerebral blood flow during mouse cerebral ischemia and reperfusion is suppressed by PTK inhibitors]

PP1, which is one of the inhibitors of PTK, has been reported to show vasodilatory effects during cerebral ischemia (see Non-Patent Document 11). Local cerebral blood flow was measured using a laser Doppler blood flow meter. As shown in Fig. 8, the local blood flow in the cerebral cortex during ischemia is reduced to 25% compared to before cerebral ischemia (100%). Return to the vicinity (in the figure, Genistein administration group (black circle), vehicle group (white circle) and control mouth (vehicle non-administration group)). However, when genistein (30 mgZkg) was administered for 15 minutes before cerebral ischemia, it increased to 30-35% of cerebral blood flow during ischemia, and the local cerebral blood flow after reperfusion was approximately 2%. Recover in minutes. In particular, it recovers 50% in 30 seconds immediately after reperfusion and recovers to 80% before ischemia. However, in the vehicle group, only about 20% (recovered to 40% before ischemia) can be recovered. This result may be caused by the PTK inhibitor genistein, which causes circulatory improvement such as vasodilation during transient mouse cerebral ischemia 'reperfusion, thereby suppressing the decrease in cerebral blood flow Demonstrate that it has a remedy against late neuronal death Yes.

 [0113] Thus, the present invention reveals the presence of volume-sensitive C1-channel in hippocampal primary cultured neurons, and suppresses the volume-sensitive C1-channel force 厂 channel blocker or PTK inhibitor that controls cr channel. It was completed on the basis of finding that Furthermore, based on the knowledge found in the primary neuronal cultured cells, the inventor's original “Evaluation system for cerebral ischemia in individuals” is used to circulate by dissolving the drug in a solvent containing a solubilizing agent. It would have been impossible to develop a new method to improve the pharmacokinetics of the drug and to repeatedly administer the drug over several days as well as before cerebral ischemia.

 [0114] It should be noted that the specific embodiments or examples made in the section of the best mode for carrying out the invention are merely to clarify the technical contents of the present invention. Various modifications can be made within the spirit of the present invention and the following claims, which should not be construed as narrowly limited to only examples. Industrial applicability

 [0115] By using the present invention, it is possible to suppress neuronal cell death in an individual, particularly delayed neuronal cell death caused by cerebral ischemia / reperfusion. When the administration route in the present invention is intravenous administration, application to clinical treatment becomes relatively easy. Furthermore, the method of the repeated administration method used in the present invention is useful for the development of a useful technique for more efficiently applying the present invention. In addition, by applying this invention during cerebral infarction or myocardial infarction, or at the time of cerebral ischemia or reperfusion after cerebral ischemia in heart transplantation or cerebrovascular anastomosis, It is possible to reduce damage to the organ brain, especially nerve cells.

 [0116] Since an effective drug or method for protecting or relieving delayed neuronal death due to ischemia / reperfusion of nerve cells has not been developed so far, according to the present invention, It is possible to protect and Z or rescue delayed neuronal cell death, and greatly assist in the development of techniques for effective treatment and Z or prevention for various brain disorders caused by delayed neuronal cell death.

Claims

 The scope of the claims

 [I] An agent for protecting or relieving neuronal cell death after cerebral ischemia, comprising a Cl_ channel blocker or a protein tyrosine kinase (PTK) inhibitor.

 [2] The drug according to claim 1, wherein the neuronal cell death is delayed neuronal cell death in an individual.

 [3] The agent according to claim 1 or 2, wherein the neuronal cell death is accompanied by fragmentation of DNA in the nucleus.

 [4] The drug according to any one of claims 1 to 3, wherein the neuronal cell death is accompanied by a marked decrease in the release of cytochrome c mitochondria.

[5] C1—Cyanenoreblocker force 4, 4, diisothiocyanostilbene-2, 2, disul fonic acid (DIDS), characterized in any one of claims 1 to 4 Drug.

 [6] The drug according to any one of claims 1 to 4, wherein the PTK inhibitor is genistein.

 [7] The above-mentioned neuronal cell death occurs during cerebral infarction or myocardial infarction, or at the time of cerebral ischemia or reperfusion after cerebral ischemia in heart transplantation or cerebral vascular anastomosis The drug according to any one of 1 to 6.

[8] A method for protecting or relieving neuronal cell death, comprising a step of administering a C1-channel blocker or a PTK inhibitor to neurons under reperfusion conditions after ischemia.

 [9] The method according to claim 8, wherein the neuronal cell death is delayed neuronal cell death.

 10. The method according to claim 8 or 9, wherein the neuronal cell death is accompanied by fragmentation of nuclear DNA.

 [II] The method according to any one of claims 8 to 10, which is accompanied by a significant decrease in the activity of releasing cytochrome c from mitochondria causing cell death.

[12] Characteristically associated with improvement in cerebral blood flow reduction during cerebral ischemia and post-ischemic reperfusion Claims 8 to: The method according to any one of LI.

[13] The force according to any one of claims 8 to 12, wherein the C1-Cyanenore blocker is 4, 4'-diisothiocyanostilbene-2, 2, one disul fonic acid (DIDS). the method of.

 [14] The method according to any one of claims 8 to 12, wherein the PTK inhibitor is genistein.

 [15] The scope of claim wherein the neuronal cell death occurs during cerebral infarction or myocardial infarction, or during reperfusion after cerebral ischemia or cerebral vascular anastomosis The method according to any one of 8 to 14, wherein force.

[16] A method for evaluating neuronal cell death under reperfusion conditions after ischemia using an individual,

 Measuring cell death when using C1-channel blockers or protein tyrosine kinase inhibitors; and

 A method comprising the step of comparing a measured value obtained by the above measurement with a reference value obtained by measuring cell death in the case where a C1-channel blocker or a protein tyrosin kinase inhibitor is not used.

17. The method for evaluating neuronal cell death according to claim 16, wherein the neuronal cell death is cerebral ischemic delayed neuronal cell death.

[18] Evaluating the survival rate of nerve cells during cerebral ischemia or myocardial infarction, or during reperfusion after cerebral ischemia or cerebral ischemia The method for evaluating neuronal cell death according to claim 16 or 17.

[19] The method for evaluating neuronal cell death according to any one of [16] to [18], wherein the step of measuring cell death is performed using the activity of mitochondrial dehydrogenase as an index.

[20] The method for evaluating neuronal cell death according to any one of [16] to [18], wherein the step of measuring cell death is performed using fragmentation of nuclear DNA as an index.

[21] The method further comprising the step of measuring a change in cerebral blood flow.

The evaluation method for neuronal cell death according to any one of -20.

[22] The nerve cell death according to any one of [16] to [21], further comprising a step of temporarily blocking both common carotid arteries of the mouse and then reopening them. of Evaluation methods.

 [23] A method for screening in vitro for a factor that protects or rescues delayed cell death of neurons,

 Preparing cells for culturing;

 A hypoxic treatment step of culturing the cells under hypoxic or anoxic conditions in a medium not containing glucose;

 A reoxygenation step of culturing cells subjected to the ischemia treatment under aerobic conditions in a medium containing glucose; and

 Measuring cell death

 Including

 Compare cell death measured at the hypoxia treatment step or reoxygenation treatment step or before and after adding a candidate factor into the medium with cell death measured without adding the candidate factor. Process

 A screening method, further comprising:

[24] Process power for measuring cell death The activity of mitochondrial dehydrogenase, fragmentation of nuclear DNA, caspase activity, and mitochondrial force can also be measured using cytochrome c release into the cytoplasm or nuclear morphological changes as indicators. 24. A screening method according to claim 23.