Cerebral adenosine triphosphate-sensitive K+ channels may be impaired during acute cerebral ischemia in spontaneously hypertensive rats

Patents related to therapeutic activation of K(ATP) and K(2P) potassium channels for neuroprotection: ischemic/hypoxic/anoxic injury and general anesthetics

BACKGROUND

Mechanisms of neuroprotection encompass energy deficits in brain arising from insufficient oxygen and glucose levels following respiratory failure; ischemia or stroke, which produce metabolic stresses that lead to unconsciousness and seizures; and the effects of general anesthetics. Foremost among those K(+) channels viewed as important for neuroprotection are ATP-sensitive (K(ATP)) channels, which belong to the family of inwardly rectifying K(+) channels (K(ir)) and contain a sulfonylurea subunit (SUR1 or SUR2) combined with either K(ir)6.1 (KCNJ8) or K(ir)6.2 (KCNJ11) channel pore-forming alpha-subunits, and various members of the tandem two-pore or background (K(2P)) K(+) channel family, including K(2P)1.1 (KCNK1 or TWIK1), K(2P)2.1 (KCNK2 or TREK/TREK1), K(2P)3.1 (KCNK3 or TASK), K(2P)4.1 (KCNK4 or TRAAK), and K(2P)10.1 (KCNK10 or TREK2).

OBJECTIVES

This review covers patents and patent applications related to inventions of therapeutics, compound screening methods and diagnostics, including K(ATP) channel openers and blockers, as well as K(ATP) and K(2P) nucleic/amino acid sequences and proteins, vectors, transformed cells and transgenic animals. Although the focus of this patent review is on brain and neuroprotection, patents covering inventions of K(ATP) channel openers for cardioprotection, diabetes mellitus and obesity, where relevant, are addressed.

RESULTS/CONCLUSIONS

Overall, an important emerging therapeutic mechanism underlying neuroprotection is activation/opening of K(ATP) and K(2P) channels. To this end substantial progress has been made in identifying and patenting agents that target K(ATP) channels. However, current K(2P) channels patents encompass compound screening and diagnostics methodologies, reflecting an earlier 'discovery' stage (target identification/validation) than K(ATP) in the drug development pipeline; this reveals a wide-open field for the discovery and development of K(2P)-targeting compounds.

Acetazolamide and enalapril combination offers complete protection from nitric oxide-deficient stroke in stroke-prone spontaneously hypertensive rats

Chronic oral administration of l -NAME precipitates stroke in stroke-prone spontaneously hypertensive rats (SHRSP). The present study investigated whether acetazolamide (an acidotic agent) given alone or in combination with an angiotensin blocker (enalapril maleate) offers any protection from NO-deficient stroke in SHRSP. We also examined whether protection from NO-deficient stroke involves activation of K(+)channels. Five-week-old SHRSP drank saline (group I), l -NAME (group II), l -NAME+enalapril (group III), l -NAME+acetazolamide (group IV), and l -NAME+enalapril+acetazolamide (group V). Within a few hours following onset of stroke, rats were attached to a blood pressure recorder. In subsequent experiments, to investigate the involvement of K(+)channels, glibenclamide and BaCl(2)(K(+)channel blockers) were included in the drinking solutions that were given to the SHRSP groups receiving l -NAME, acetazolamide and enalapril. Group I of SHRSP did not develop stroke. Group II, III and IV developed stroke in 12+/-2, 29+/-2 and 20+/-2 days, respectively. SHRSP from group V did not develop stroke. However, they died in 70+/-2 days. The glibenclamide and BaCl(2)administration failed to prevent this protection from stroke. In conclusion, concurrent administration of acetazolamide and enalapril prevents onset of NO-deficient stroke in SHRSP. These stroke-protective effects are independent of reductions in mean or systolic blood pressures and do not involve an activation of K(+)channels.

Role of potassium channels in the central neurogenic neuroprotection elicited by cerebellar stimulation in rat

Electrical stimulation of the cerebellar fastigial nucleus (FN) in spontaneously hypertensive (SHR), Wistar-Kyoto (WKY) and Fisher rats reduced, by approximately 50%, the infarctions produced by occlusion of the middle cerebral artery. Blockade of ATP-dependent potassium (K-ATP) channels with glibenclamide (i.c.v.) abolished salvage only in the SHR rat. While blockade of K-ATP channels failed to abolish salvage in WKY and Fisher rats, participation of potassium channels in neurogenic neuroprotection cannot be excluded.