Ammonium salts of inositol hexaphosphate, and uses thereof

Abstract

The present invention comprises compounds, compositions thereof, and methods capable of delivering inositol hexaphospahte (IHP) to the cytoplasm of mammalian cells. In certain embodiments, the present invention relates to compounds, compositions thereof, and methods that enhance the ability of mammalian red blood cells to deliver oxygen, by delivering IHP to the cytoplasm of the red blood cells.

Description

RELATED APPLICATION INFORMATION [0001] This application claims the benefit of priority under 35 U.S.C. section 119(e) to Provisional Patent Applications 60 / 222,089, filed Aug. 1, 2000. This application is hereby incorporated by reference in its entirety.BACKGROUND OF THE INVENTION I. Ischemia [0002] Ischemic insult, i.e., the localized deficiency of oxygen to an organ or skeletal tissue, is a common and important problem in many clinical conditions. The problem is especially acute in organ transplant operations in which a harvested organ is removed from a body, isolated from a blood source, and thereby deprived of oxygen and nutrients for an extended period of time. Ischemic insult also occurs in certain clinical conditions, such as sickle cell anemia and septic shock, which may result from hypotension or organ dysfunction. Depending on the duration of the insult, the ischemia can disturb cellular metabolism and ion gradients, and ultimately cause irreversible cellular injury and d...

AI Technical Summary

Benefits of technology

[0043] Ligands for the allosteric site of hemoglobin interact with the hemoglobin molecule and impact its ability to bind oxygen. This invention is particularly concerned with the delivery of IHP, causing oxygen to be bound relatively less tightly to hemoglobin, such that oxygen is off-loaded from the hemoglobin molecule more easily.

[0044] The process of allosterically modifying hemoglobin towards a lower o...

Problems solved by technology

Ischemic insult, i.e., the localized deficiency of oxygen to an organ or skeletal tissue, is a common and important problem in many clinical conditions.

The problem is especially acute in organ transplant operations in which a harvested organ is removed from a body, isolated from a blood source, and thereby deprived of oxygen and nutrients for an extended period of time.

Depending on the duration of the insult, the ischemia can disturb cellular metabolism and ion gradients, and ultimately cause irreversible cellular injury and death.

Because of the blockage or rupture, part of the brain fails to get the supply of blood and oxygen that it requires.

As the neurons fail and die, the part of the body controlled by those neurons can no longer function.

The devastating effects of ischemia are often permanent because brain tissue has very limited repair capabilities and lost neurons are typically not regenerated.

More prolonged or complete ischemia results in infarction.

Alternatively, ischemia may be sufficiently prolonged and compensatory mechanisms sufficiently inadequate that a catastrophic stroke or heart attack results.

Septic shock as a result of hypotension and organ dysfunction in response to infectious sepsis is a major cause of death.

Extreme levels of these mediators are known to trigger many pathological events, including fever, shock, and intravascular coagulation, leading to ischemia and organ failure.

Conversely, the binding of oxygen allosterically reduces the affinity of hemoglobin for the polyanion.

In fact it is difficult to maintain hemoglobin solutions in the deoxy state, (deoxy)hemoglobin, throughout a chromatographic procedure.

Because of these difficulties, the technique of affinity chromatography has not been used in the prior art to purify hemoglobin.

When a patient suffers a trauma (i.e., a wound or injury) resulting, for example, from surgery, an invasive medical procedure, or an accident, the trauma disturbs the patient's homeostasis.

If the body's stress response is inadequate or if it occurs well after the trauma is suffered, the patient is more prone to develop disorders.

Unfortunately, the effects of bezafibrate and the urea derivatives discussed above have been found to be significantly inhibited by serum albumin, the major protein in blood serum (Lalezari et al., Biochemistry, 29, 1515 (1990)).

Therefore, the clinical usefulness of these drugs is seriously undermined because in whole blood and in the body, the drugs would be bound by serum albumin instead of reaching the red cells, crossing the red cell membrane, and interacting with hemoglobin protein molecule to produce the desired effect.

Unfortunately, IHP is unable to pass unassisted across the erythrocyte membrane.

However, the equally important parameters of the O2 release capacity, i.e., O2 half-saturation pressure of Hb and RBCs, and the amounts of high and low oxygen affinity hemoglobins in RBCs, are not routinely determined and were not given serious consideration until pioneering work by Gerosonde and Nicolau (Blut, 1979, 39, 1-7).

The acute symptoms and pathology of many cardiovascular diseases, including congestive heart failure, myocardial infarction, stroke, intermittent claudication, and sickle cell anemia, result from an insufficient supply of oxygen in fluids that bathe the tissues.

Likewise, the acute loss of blood following hemorrhage, traumatic injury, or surgery results in decreased oxygen supply to vital organs.

Without oxygen, tissues at sites distal to the heart, and even the heart itself, cannot produce enough energy to sustain their normal functions.

The result of oxygen deprivation is tissue death and organ failure.

Although the attention of the American public has long been focused on the preventive measures required to alleviate heart disease, such as exercise, appropriate dietary habits, and moderation in alcohol consumption, deaths continue to occur at an alarming rate.

This leads to inadequate oxygenation of their tissues and subsequent complications.

Often the amount of blood which can be drawn and stored prior to surgery limits the use of autologous blood.

Typically, a surgical patient does not have enough time to donate a sufficient quantity of blood prior to surgery.

As each unit requires a period of several weeks between donations and can not be done less than two weeks prior to surgery, it is often impossible to sequester an adequate supply of blood.

Although it is evident that methods of enhancing oxygen delivery to tissues have potential medical applications, currently there are no methods clinically available for increasing tissue delivery of oxygen bound to hemoglobin.

The natural regulation of DPG synthesis in vivo and its relatively short biological half-life, however, limit the DPG concentration and the duration of increased tissue PO2, and thus limit its therapeutic usefulness.

While this product could be useful as a replacement for blood lost in traumatic injury or surgery, it would not be effective to increase PO2 levels in ischemic tissue, since its oxygen release capacity is equivalent to that of natural hemoglobin (27-30%).

As are all recombinant products, this synthetic hemoglobin is also likely to be a costly therapeutic.

This product may be less expensive product than the Somatogen synthetic hemoglobin, but it does not solve problems with oxygen affinity and breakdown of hemoglobin in the body.

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