CA1095444A - Encapsulated hemoglobin and method of making the same - Google Patents
Encapsulated hemoglobin and method of making the sameInfo
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- CA1095444A CA1095444A CA279,939A CA279939A CA1095444A CA 1095444 A CA1095444 A CA 1095444A CA 279939 A CA279939 A CA 279939A CA 1095444 A CA1095444 A CA 1095444A
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- hemoglobin
- cells
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61K—PREPARATIONS FOR MEDICAL, DENTAL OR TOILETRY PURPOSES
- A61K9/00—Medicinal preparations characterised by special physical form
- A61K9/10—Dispersions; Emulsions
- A61K9/127—Liposomes
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61K—PREPARATIONS FOR MEDICAL, DENTAL OR TOILETRY PURPOSES
- A61K38/00—Medicinal preparations containing peptides
- A61K38/16—Peptides having more than 20 amino acids; Gastrins; Somatostatins; Melanotropins; Derivatives thereof
- A61K38/41—Porphyrin- or corrin-ring-containing peptides
- A61K38/42—Haemoglobins; Myoglobins
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10T—TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
- Y10T428/00—Stock material or miscellaneous articles
- Y10T428/29—Coated or structually defined flake, particle, cell, strand, strand portion, rod, filament, macroscopic fiber or mass thereof
- Y10T428/2982—Particulate matter [e.g., sphere, flake, etc.]
- Y10T428/2984—Microcapsule with fluid core [includes liposome]
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- Proteomics, Peptides & Aminoacids (AREA)
- Medicines That Contain Protein Lipid Enzymes And Other Medicines (AREA)
- Medicinal Preparation (AREA)
Abstract
ABSTRACT OF THE DISCLOSURE
Synthetic cells containing hemoglobin. Hemoglobin is encapsulated in naturally occurring lipid materials to form cells which are typically 1 to 10 microns in their greatest dimension. Preferably cholesterol is also included in the cell membrane. The lipid membrane is of such character and thinness that O2 - CO2 transfer thereacross is readily accomplished. The preferred encapsulation process utilizes ultrasonic energy.
Synthetic cells containing hemoglobin. Hemoglobin is encapsulated in naturally occurring lipid materials to form cells which are typically 1 to 10 microns in their greatest dimension. Preferably cholesterol is also included in the cell membrane. The lipid membrane is of such character and thinness that O2 - CO2 transfer thereacross is readily accomplished. The preferred encapsulation process utilizes ultrasonic energy.
Description
BACKGROUND OF THE INVENTION
Our invention relates to cells consisting of hemoglobin encapsulated in lipids and more especially phospholipids and to the method of making such synthetic cells. These cells are characterized by comparable 2 - C2 conjugation and transference to that of naturally occurring red blood cells. Furthermore, our synthetic cells are of such small s;ze and flexibility t~o readily -pass through mammalian:capillars~
systems where such 2 ~ C2 transfer takes place. - Another, most --desirable feature of our cells is that their use introduces no foreign matter to the recipient.
Our synthetic cells, in terms of oxygen carrying capability, ~3 function very similarly to normal mammalian red blood cells and accordingly in suspension offer substantial utility as a transfusion liquid. Such cells appear acceptable to the mammalian host as are natural such cells, function in substantially the same manner and should be metabolized and excreted .
'', ' , . .~
~ lO9S~144 1 ~
as are naturally occurring cells. The significance of all this, we believe, will be immediately apparent to those skilled in the art.
As is known to those skilled in this art, hemoglobin is a conjugated protein having a prosthetic group - heme - affixed to the protein, globin. It is the red coloring matter of blood and is found, contained, in the red blood cells. Its essential utility stems from its ability to unite in loose combination with atmospheric oxygen to form oxyhemoglobin. In mammals this occurs in the capillaries adjacent the lung alveoli to produce so-called oxygenated blood. This is carried in the arterial system to the tissues where a portion of the oxygen is released and then the venous blood, partially depleted in oxygen is returned to the lungs ,~ for further oxygenation.
As further background we note that heme is an iron porphyrin, i. e. ,- the union of iron with four pyrrole groups. The iron is basically in the ferrous state. Hemoglobin is usually designated as ~' Heme ~ Herne * .
Heme ~ ~ Heme-Thus hernoglobin is a tetramer consisting of four-sub-units;
each sub-unit is a combination of a polypetide chain, which is the protein or globin part of hemoglobin, and a heme. The latter is the functional unit or active site to which oxygen may be bound.
Whole blood, especially human, when drawn for transfusion purposes, is considered to have a storage life of 21 days. By present regulation such blood 21 days old must be discarded and no longer used for blood transfusion. As a practical matter upon the passage of such time the red cells break down thus making the old blood substantially useless 1~)95~44 for its intended purpose. However, such "old blood" still contains useful, functional hemoglobin and can be used as the starting material in the preparation of the present cells.
In distinction to the aging problem - 21 days - encountered with whole, natural blood, we find that the present cells when appropriately buffered, have quite an extended, useful,shelf life, as is noted below.
Our synthetic hemoglobin cells offer another advantage --because of how they are made they can be considered to be in the class of universal donor. Whole blood for transfusion purposes must be typed and extreme care taken to assure compatability with the blood type of the recipient. This is not the case with the present cells. Our starting material for encapsulation is what is commonly referred to as "stroma-free"hemoglobin. This is material free of the cell walls of the red blood cells. The walls contain protein and it is such protein which necessitates -blood-typing. The walls of our synthetic cells are formed of universally present (i. e., i~ the mammal) lipids and the like which are not subject to antigenic reactions of proteins.--. A
As further background to our invention we note that the separation of red blood cells from whole blood is an old, established common practice. And the separation of hemoglobin from its associated red cells by a multitude of techniques is similarly well-known. Such two known categories of techniques represent the starting points in forming the hemoglobin cells of this invention.
As further background we also note that some workers have been investigating the use of cell-free hemoglobin solutions as natural blood substitutes, These solutions suffer the disadvantage of being rapidly excreted by the body and thus really do not accomplish their intended purpose i~9S444 for anything but the shortest of times. In distinction to this the present lipid encapsulated hemoglobin cells will be retained by the body for extended and more useful periods.~
We also note that prior workers have formed what are generically referred to as liposomes.
Among the prior patents we note the following:
Bower, U. S. 2, 527, 210 is directed to a hemoglobin solution wherein a freezing-thawing technique is used to destroy the red cell membranes.
Childs, U. S. 3,133, 881 discloses a centrifugation method which may be employed to separate red cells from the other constituents of whole blood.
Van Dyck et al, U. S. 3, 351, 432 is directed to the washing and reconstituting of red blood cells and Ushakoff, U. S. 3, 418, 209 to making red cells storable by a combination with a glycerin solution.
Similarly, ng, Re 27, 359 is directed to the washing of red cells.
Bonhard, U. S. 3, 864, 4?8 discloses another method of making a hemoglobin solution. l.
~ The prior art teachings in no way suggest or hint at the lipid encapsulation of hemoglobin to form the present synthetic cells nor the benefit or utility of such cells. The sirnilarity of the present synthetic cells to 'I
normal red blood cells in terms of oxygen carrying capability is unexpected.
Accordingly, a principal object of our invention is to provide lipid encapsulated synthetic hemoglobin cells and a method for their manufacture. ~;ow this is accomplished is set out as this description proceeds ., . ' 1, ,' 109544g ' DESCRIPTION OF THE INVENTION
In practicing our invention hemoglobin is first separated from its associated red blood cell membranes, The basic starting material herein as noted above, is stroma-free hemoglobin; this is the material which we subsequently encapsulate in lipid. We can start with relatively freshly drawn blood which contains a vast majority of viable red blood cells through blood drawn, e. g. 21 days previously or more wherein a substantial proportion of the red cells no longer are viable, It is important to thoroughly separate the hemoglobin from its natural cell membranes to eliminate the above noted protein reactions and other adverse reactions in the recipient.
There are numerous known procedures for separating hemoglobin from blood. First the red cells are separated from the plasma constituent by centrifugation or the like. The residue consists of both broken and unbroken red blood cells. By freeze-thawing we rupture the remaining cell membranes, although other techniques may be employed, and then by filtràtion or the like~we produce stroma~free he~noglobin solution. The concentration of hemoglobin and other constituents may be`-adjusted as desired.
The resulting hemoglobin solution is then encapsulated in naturally occurring lipids to form synthetic liposome cells. Such cells are typically 1 to 10 microns in their largest dimension. We believe that the lipid membrane is approximately two molecules thick.
In the present specification and claims the term 'liposome" is used. By this is meant a capsule wherein the wall or membrane thereof is formed of lipids, especially phospholipid, with the optional addition therewith of a sterol, especially cholesterol.
1095~44 In the preferred method hereof a thin lipid fllm is first formed on the interior surface of a container. In the laboratory such container is usually a flask of the round bottom type. A small amount of lipid in an organic solvent is placed in the flask and it is both shaken and spun to deposit a thin lipid film on the interior surface. Such film is permitted to dry. Then a small amount of the purified hemoglobin solution is deposited in the flask.
While other encapsulation techniques may be employed we prefer the following:
The flask is placed in a water bath maintained at 37C and the bath subjected to ultrasound at a frequency of 50, 000 Hertz. In the presence of the hemoglobin solution and as a result of such mixing the lipid material forms a continuous membrane about the hemoglobin solution and forms the cells of the present invention. The cells are then separated from the extracellular hemoglobin solution and suspended in an appropriate carrier liquid.
The film forming rnaterials useful herein are selected from the -group-phospholipi'd ge'nerically. i~Representative'of the-useful phos'pholipi~s~
ar'e compounds of the types-lecithins, cephalins and sphingomyelins. As --noted above we limit such phospholipids to those which naturally occur in the mammalian body to eliminate the problems resulting from foreign body reactions. Among such phospholipids the following materials exemplify, but are not exhaustive of the herein useful materials:
phosphatidic acid, phosphatidyl serine, phosphatidyl inositol, phosphatidyl choline and phosphatidyl ethanolamine.
In addition to the use of phospholipid alone, we find that the use therewith of a sterol compound such as cholesterol greatly enhances those properties of the cell membrane that are desirable for the present application~
We prefer to use both cholesterol and one or more phospholipids jtogether as the encapsulating material. We have found that a preferred .
109~444 ll . ..
encapsulant is 3 parts (by weight) lecithin ex ovo to 1 part cholesterol, In the examples presented below this is referred to as the '~:1 material".
As to the hemoglobin solution as used herein, we prefer a solution containing ions normally present in plasma. ~owever, other ions may be present. The pH is preferably 7. 4 and the solution is preferably isoosmotic with normal plasma.
In order to prepare the encapsulating film the cholesterol/
phospholipid is first dissolved in an inert, highly volatile organic liquid such as chloroform. This is evaporated to leave the film on the flask wall.
Examples of how the present cells are produced are as follows:
Example 1 60 mg. of the 3:i material was dissolved in 30 ml of reagent grade chloroform in a 1 liter round bottom flask under sterile co nditions.
Temperature was 25~. The material was swirled around the flask walls under vacuum for approximately 15 minutes and a thin, transparent film wàs formed coating the bottom two-thirds of the flask.-- Into such coated ~
nas-k was then deposited 10 ml. of hemoglobin solution containing l6 gram_ per cent of hemoglobin as well as other normal soluble intracellular components of red blood cells. Such solution had a pH of 7. 4 and was isoosmotic with normal plasma. The flask was then immersed up to its neck in a water bath maintained at 37 C and ultrasound at a frequency of 50 KHz was applied through the bath for 15 minutes. There resulted 10 ml. of encapsulated hemoglobin dispersion having a particle size spectrum ranging between 1 and 10 microns. This dispersion was washed three times with normal saline by centrifugation and decantation to produce the final product.
Any unencapsulated hemoglobin may be utilized in a subsequent encapsulation.
1095444 1 ~
Example 2 14. 4 mg. of cholesterol, 43. 2 mg. of lecithin ex ovo, and 2. 4 mg. of phosphatidic acid were dissolved in 25 ml. of reagent grade chloroform in a 1 liter round bottom flask under sterile conditions.' Temperature was 25C. The material was swirled around the walls, under vacuum, for approximately 15 minutes and a thin, transparent film was formed coating the bottom two-thirds of the flask. Into such coated flask was then deposited 10 ml. of hemoglobin solution containing 15, 7 gm per cent hemoglobin (plus other normal soluble intracellular components) ir~ is~Eonic saline. The rest of the procedure follows Example 1.
Example 3 20 mg. of cholesterol and 100 mg. of lecithin ex ovo were dissolved in 25 ml. of reagent grade chloroform in a 1 liter round bottom flask under sterile conditions, The rest of the procedure follows Example lj with the~exception -thatthe- hemoglobin solution-contained--14. 71 gin~per cent hemoglobir~ ~plus other normal soluble intracellular components) in isotonic salin'e'. -.
Example 4 =
30 mg. of cholesterol, 80 mg. of lecithin ex ovo, and 10 mg.
v; phosphatidyl serine were dissolved in 25 ml. of reagent grade chloroform ~ 1 liter round bottom flask under sterile conditions. The rest of the procedure follows Example 3.
Example 5 The procedure follows Example 1, with the exception that the hemoglobin solution contained 22 gm per cent hemoglobin (plus other normal soluble intracellular components) in isotonic saline.
. .
.`
The encapsulated hemoglobin cells resulting from Example 1 were tested as follows:
Gas mixtures consisting of varying proportions of oxygen, nitrogen, and carbon dioxide, at one atmosphere total pressure, were .
equilibrated with samples of the present encapsulated hemoglobin, and the relative oxygen saturation of the hemoglobin was determined by spectrophotometry. The results were as follows:
pO" (mmHg) pCO~ tmmHg) %2 saturation 44 14. 9 28. 7 42 46. 3 gO 42 62. 3 41 72~ 0 41 85. 7 70 - 40 . . 89. 5 90 - 40 90. 7 These results, obtained at 22C and a pH of 6.;35,-~closely.follow'.:-~; ~-what would be obtained for normal whole blood under the same conditions. -In the practice of the present invention we prefer to useultrasonic energy as the means for encapsulation. However, other means of providing vigorous stirring of the hemoglobin--lipid--cholesterol may be employed. Intimate mixing of the hemoglobin and cell membrane material is required.
The resulting cell size can be fairly closely controlled, the aim of course being to have cells capable of unhindered capillary passage.
Cell size is dependent upon factors such as: temperature, viscosity, 10954~4 stirring frequency, interfacial tension as between membrane material and the aqueous phase hemoglobin being encapsulated, and other physical properties. Lower stirring energy levels than we have used would likely result in reduced cell forming efficiency.
It is interesting to note that cell size in the present invention is substantially self-governing, ~ells larger than 10 microns appear somewhat unstable and break down into smaller units. And, of course, liposomes too big for intended use may readily be filtered out.
There is another aspect of the present hemoglobin liposomes that should be noted. Normally occurring red blood cells are characterized by slight surface electronegativity commonly measured in terms of "zeta potential" Under conditions comparable to those used in the oxygenation study described above, red blood cells are characterized by zeta potentials in the range of -8 to -17 millivolts. By controlling the relative proportions of the cell membrane forming materials hereof we '_ can vary the zeta potential measurements of our synthetic cells across this range and in fact have found that' cells`formed fro'm Example 3 have - -a zeta potential of -22 millivolts. -The various phospholipids' used herein are~--characterized by varying electronegativities, Such electronegativity'in both natural and our cells is believed to be physiologically significant inter alia to both keep the cells separated from each other in the blood stream and from the blood vessel walls.
In the present hemoglobin liposomes the cell membrane is preferably a bi'layer although multilayers may be used. Within the limit of providing adequate hemoglobin encapsulation it is preferred that the cell wal be as thin as possible to enhance 2 ~ C2 exchange.
. 1~95444 . ,1 It will be evident to those skilled in the art associated with the present invention that the present hemoglobin liposomes contain only materials naturally occurring in the mammalian host, Suc h cells may be used for blood transfusion purposes (e. g. in isotonic saline solution or synthetic plasma) with a comparative long life in the body of the ' host, as compared with free hemoglobin, and also will be naturally metabolized for subsequent excretion.
Furthermore, our cells appear sturdier than normal red blood cells which should pr ove useful in extracorporeal function such as in conjunction with heart-lung machines or artificial kidney machines, In addition to this, such synthetic cells are expected to have a reasonably good shelf life beyond the 21 days of whole blood. At a pH of 6. 5 we found that after two and six weeks respectively of storage there still remained 50%
and 25% of active''hemoglobin in our liposomes. At a pH of 7. 4-the results would be expected- to be better.
It will be understoo'd that various modifications and variations -mày be expected without depàrting from the spirit` or scope o the novel- ~1 concepts of our invention.-.~
.
Our invention relates to cells consisting of hemoglobin encapsulated in lipids and more especially phospholipids and to the method of making such synthetic cells. These cells are characterized by comparable 2 - C2 conjugation and transference to that of naturally occurring red blood cells. Furthermore, our synthetic cells are of such small s;ze and flexibility t~o readily -pass through mammalian:capillars~
systems where such 2 ~ C2 transfer takes place. - Another, most --desirable feature of our cells is that their use introduces no foreign matter to the recipient.
Our synthetic cells, in terms of oxygen carrying capability, ~3 function very similarly to normal mammalian red blood cells and accordingly in suspension offer substantial utility as a transfusion liquid. Such cells appear acceptable to the mammalian host as are natural such cells, function in substantially the same manner and should be metabolized and excreted .
'', ' , . .~
~ lO9S~144 1 ~
as are naturally occurring cells. The significance of all this, we believe, will be immediately apparent to those skilled in the art.
As is known to those skilled in this art, hemoglobin is a conjugated protein having a prosthetic group - heme - affixed to the protein, globin. It is the red coloring matter of blood and is found, contained, in the red blood cells. Its essential utility stems from its ability to unite in loose combination with atmospheric oxygen to form oxyhemoglobin. In mammals this occurs in the capillaries adjacent the lung alveoli to produce so-called oxygenated blood. This is carried in the arterial system to the tissues where a portion of the oxygen is released and then the venous blood, partially depleted in oxygen is returned to the lungs ,~ for further oxygenation.
As further background we note that heme is an iron porphyrin, i. e. ,- the union of iron with four pyrrole groups. The iron is basically in the ferrous state. Hemoglobin is usually designated as ~' Heme ~ Herne * .
Heme ~ ~ Heme-Thus hernoglobin is a tetramer consisting of four-sub-units;
each sub-unit is a combination of a polypetide chain, which is the protein or globin part of hemoglobin, and a heme. The latter is the functional unit or active site to which oxygen may be bound.
Whole blood, especially human, when drawn for transfusion purposes, is considered to have a storage life of 21 days. By present regulation such blood 21 days old must be discarded and no longer used for blood transfusion. As a practical matter upon the passage of such time the red cells break down thus making the old blood substantially useless 1~)95~44 for its intended purpose. However, such "old blood" still contains useful, functional hemoglobin and can be used as the starting material in the preparation of the present cells.
In distinction to the aging problem - 21 days - encountered with whole, natural blood, we find that the present cells when appropriately buffered, have quite an extended, useful,shelf life, as is noted below.
Our synthetic hemoglobin cells offer another advantage --because of how they are made they can be considered to be in the class of universal donor. Whole blood for transfusion purposes must be typed and extreme care taken to assure compatability with the blood type of the recipient. This is not the case with the present cells. Our starting material for encapsulation is what is commonly referred to as "stroma-free"hemoglobin. This is material free of the cell walls of the red blood cells. The walls contain protein and it is such protein which necessitates -blood-typing. The walls of our synthetic cells are formed of universally present (i. e., i~ the mammal) lipids and the like which are not subject to antigenic reactions of proteins.--. A
As further background to our invention we note that the separation of red blood cells from whole blood is an old, established common practice. And the separation of hemoglobin from its associated red cells by a multitude of techniques is similarly well-known. Such two known categories of techniques represent the starting points in forming the hemoglobin cells of this invention.
As further background we also note that some workers have been investigating the use of cell-free hemoglobin solutions as natural blood substitutes, These solutions suffer the disadvantage of being rapidly excreted by the body and thus really do not accomplish their intended purpose i~9S444 for anything but the shortest of times. In distinction to this the present lipid encapsulated hemoglobin cells will be retained by the body for extended and more useful periods.~
We also note that prior workers have formed what are generically referred to as liposomes.
Among the prior patents we note the following:
Bower, U. S. 2, 527, 210 is directed to a hemoglobin solution wherein a freezing-thawing technique is used to destroy the red cell membranes.
Childs, U. S. 3,133, 881 discloses a centrifugation method which may be employed to separate red cells from the other constituents of whole blood.
Van Dyck et al, U. S. 3, 351, 432 is directed to the washing and reconstituting of red blood cells and Ushakoff, U. S. 3, 418, 209 to making red cells storable by a combination with a glycerin solution.
Similarly, ng, Re 27, 359 is directed to the washing of red cells.
Bonhard, U. S. 3, 864, 4?8 discloses another method of making a hemoglobin solution. l.
~ The prior art teachings in no way suggest or hint at the lipid encapsulation of hemoglobin to form the present synthetic cells nor the benefit or utility of such cells. The sirnilarity of the present synthetic cells to 'I
normal red blood cells in terms of oxygen carrying capability is unexpected.
Accordingly, a principal object of our invention is to provide lipid encapsulated synthetic hemoglobin cells and a method for their manufacture. ~;ow this is accomplished is set out as this description proceeds ., . ' 1, ,' 109544g ' DESCRIPTION OF THE INVENTION
In practicing our invention hemoglobin is first separated from its associated red blood cell membranes, The basic starting material herein as noted above, is stroma-free hemoglobin; this is the material which we subsequently encapsulate in lipid. We can start with relatively freshly drawn blood which contains a vast majority of viable red blood cells through blood drawn, e. g. 21 days previously or more wherein a substantial proportion of the red cells no longer are viable, It is important to thoroughly separate the hemoglobin from its natural cell membranes to eliminate the above noted protein reactions and other adverse reactions in the recipient.
There are numerous known procedures for separating hemoglobin from blood. First the red cells are separated from the plasma constituent by centrifugation or the like. The residue consists of both broken and unbroken red blood cells. By freeze-thawing we rupture the remaining cell membranes, although other techniques may be employed, and then by filtràtion or the like~we produce stroma~free he~noglobin solution. The concentration of hemoglobin and other constituents may be`-adjusted as desired.
The resulting hemoglobin solution is then encapsulated in naturally occurring lipids to form synthetic liposome cells. Such cells are typically 1 to 10 microns in their largest dimension. We believe that the lipid membrane is approximately two molecules thick.
In the present specification and claims the term 'liposome" is used. By this is meant a capsule wherein the wall or membrane thereof is formed of lipids, especially phospholipid, with the optional addition therewith of a sterol, especially cholesterol.
1095~44 In the preferred method hereof a thin lipid fllm is first formed on the interior surface of a container. In the laboratory such container is usually a flask of the round bottom type. A small amount of lipid in an organic solvent is placed in the flask and it is both shaken and spun to deposit a thin lipid film on the interior surface. Such film is permitted to dry. Then a small amount of the purified hemoglobin solution is deposited in the flask.
While other encapsulation techniques may be employed we prefer the following:
The flask is placed in a water bath maintained at 37C and the bath subjected to ultrasound at a frequency of 50, 000 Hertz. In the presence of the hemoglobin solution and as a result of such mixing the lipid material forms a continuous membrane about the hemoglobin solution and forms the cells of the present invention. The cells are then separated from the extracellular hemoglobin solution and suspended in an appropriate carrier liquid.
The film forming rnaterials useful herein are selected from the -group-phospholipi'd ge'nerically. i~Representative'of the-useful phos'pholipi~s~
ar'e compounds of the types-lecithins, cephalins and sphingomyelins. As --noted above we limit such phospholipids to those which naturally occur in the mammalian body to eliminate the problems resulting from foreign body reactions. Among such phospholipids the following materials exemplify, but are not exhaustive of the herein useful materials:
phosphatidic acid, phosphatidyl serine, phosphatidyl inositol, phosphatidyl choline and phosphatidyl ethanolamine.
In addition to the use of phospholipid alone, we find that the use therewith of a sterol compound such as cholesterol greatly enhances those properties of the cell membrane that are desirable for the present application~
We prefer to use both cholesterol and one or more phospholipids jtogether as the encapsulating material. We have found that a preferred .
109~444 ll . ..
encapsulant is 3 parts (by weight) lecithin ex ovo to 1 part cholesterol, In the examples presented below this is referred to as the '~:1 material".
As to the hemoglobin solution as used herein, we prefer a solution containing ions normally present in plasma. ~owever, other ions may be present. The pH is preferably 7. 4 and the solution is preferably isoosmotic with normal plasma.
In order to prepare the encapsulating film the cholesterol/
phospholipid is first dissolved in an inert, highly volatile organic liquid such as chloroform. This is evaporated to leave the film on the flask wall.
Examples of how the present cells are produced are as follows:
Example 1 60 mg. of the 3:i material was dissolved in 30 ml of reagent grade chloroform in a 1 liter round bottom flask under sterile co nditions.
Temperature was 25~. The material was swirled around the flask walls under vacuum for approximately 15 minutes and a thin, transparent film wàs formed coating the bottom two-thirds of the flask.-- Into such coated ~
nas-k was then deposited 10 ml. of hemoglobin solution containing l6 gram_ per cent of hemoglobin as well as other normal soluble intracellular components of red blood cells. Such solution had a pH of 7. 4 and was isoosmotic with normal plasma. The flask was then immersed up to its neck in a water bath maintained at 37 C and ultrasound at a frequency of 50 KHz was applied through the bath for 15 minutes. There resulted 10 ml. of encapsulated hemoglobin dispersion having a particle size spectrum ranging between 1 and 10 microns. This dispersion was washed three times with normal saline by centrifugation and decantation to produce the final product.
Any unencapsulated hemoglobin may be utilized in a subsequent encapsulation.
1095444 1 ~
Example 2 14. 4 mg. of cholesterol, 43. 2 mg. of lecithin ex ovo, and 2. 4 mg. of phosphatidic acid were dissolved in 25 ml. of reagent grade chloroform in a 1 liter round bottom flask under sterile conditions.' Temperature was 25C. The material was swirled around the walls, under vacuum, for approximately 15 minutes and a thin, transparent film was formed coating the bottom two-thirds of the flask. Into such coated flask was then deposited 10 ml. of hemoglobin solution containing 15, 7 gm per cent hemoglobin (plus other normal soluble intracellular components) ir~ is~Eonic saline. The rest of the procedure follows Example 1.
Example 3 20 mg. of cholesterol and 100 mg. of lecithin ex ovo were dissolved in 25 ml. of reagent grade chloroform in a 1 liter round bottom flask under sterile conditions, The rest of the procedure follows Example lj with the~exception -thatthe- hemoglobin solution-contained--14. 71 gin~per cent hemoglobir~ ~plus other normal soluble intracellular components) in isotonic salin'e'. -.
Example 4 =
30 mg. of cholesterol, 80 mg. of lecithin ex ovo, and 10 mg.
v; phosphatidyl serine were dissolved in 25 ml. of reagent grade chloroform ~ 1 liter round bottom flask under sterile conditions. The rest of the procedure follows Example 3.
Example 5 The procedure follows Example 1, with the exception that the hemoglobin solution contained 22 gm per cent hemoglobin (plus other normal soluble intracellular components) in isotonic saline.
. .
.`
The encapsulated hemoglobin cells resulting from Example 1 were tested as follows:
Gas mixtures consisting of varying proportions of oxygen, nitrogen, and carbon dioxide, at one atmosphere total pressure, were .
equilibrated with samples of the present encapsulated hemoglobin, and the relative oxygen saturation of the hemoglobin was determined by spectrophotometry. The results were as follows:
pO" (mmHg) pCO~ tmmHg) %2 saturation 44 14. 9 28. 7 42 46. 3 gO 42 62. 3 41 72~ 0 41 85. 7 70 - 40 . . 89. 5 90 - 40 90. 7 These results, obtained at 22C and a pH of 6.;35,-~closely.follow'.:-~; ~-what would be obtained for normal whole blood under the same conditions. -In the practice of the present invention we prefer to useultrasonic energy as the means for encapsulation. However, other means of providing vigorous stirring of the hemoglobin--lipid--cholesterol may be employed. Intimate mixing of the hemoglobin and cell membrane material is required.
The resulting cell size can be fairly closely controlled, the aim of course being to have cells capable of unhindered capillary passage.
Cell size is dependent upon factors such as: temperature, viscosity, 10954~4 stirring frequency, interfacial tension as between membrane material and the aqueous phase hemoglobin being encapsulated, and other physical properties. Lower stirring energy levels than we have used would likely result in reduced cell forming efficiency.
It is interesting to note that cell size in the present invention is substantially self-governing, ~ells larger than 10 microns appear somewhat unstable and break down into smaller units. And, of course, liposomes too big for intended use may readily be filtered out.
There is another aspect of the present hemoglobin liposomes that should be noted. Normally occurring red blood cells are characterized by slight surface electronegativity commonly measured in terms of "zeta potential" Under conditions comparable to those used in the oxygenation study described above, red blood cells are characterized by zeta potentials in the range of -8 to -17 millivolts. By controlling the relative proportions of the cell membrane forming materials hereof we '_ can vary the zeta potential measurements of our synthetic cells across this range and in fact have found that' cells`formed fro'm Example 3 have - -a zeta potential of -22 millivolts. -The various phospholipids' used herein are~--characterized by varying electronegativities, Such electronegativity'in both natural and our cells is believed to be physiologically significant inter alia to both keep the cells separated from each other in the blood stream and from the blood vessel walls.
In the present hemoglobin liposomes the cell membrane is preferably a bi'layer although multilayers may be used. Within the limit of providing adequate hemoglobin encapsulation it is preferred that the cell wal be as thin as possible to enhance 2 ~ C2 exchange.
. 1~95444 . ,1 It will be evident to those skilled in the art associated with the present invention that the present hemoglobin liposomes contain only materials naturally occurring in the mammalian host, Suc h cells may be used for blood transfusion purposes (e. g. in isotonic saline solution or synthetic plasma) with a comparative long life in the body of the ' host, as compared with free hemoglobin, and also will be naturally metabolized for subsequent excretion.
Furthermore, our cells appear sturdier than normal red blood cells which should pr ove useful in extracorporeal function such as in conjunction with heart-lung machines or artificial kidney machines, In addition to this, such synthetic cells are expected to have a reasonably good shelf life beyond the 21 days of whole blood. At a pH of 6. 5 we found that after two and six weeks respectively of storage there still remained 50%
and 25% of active''hemoglobin in our liposomes. At a pH of 7. 4-the results would be expected- to be better.
It will be understoo'd that various modifications and variations -mày be expected without depàrting from the spirit` or scope o the novel- ~1 concepts of our invention.-.~
.
Claims (18)
- The embodiments of the invention in which an exclusive property or privilege is claimed are defined as follows:
lo A process for the preparation of synthetic hemoglobin cells which comprises the steps of: (a) bringing stroma-free hemoglobin in a physiologically compatible solution into proximity with a film of naturally occurring lipid, (b) vigorously agitating to break up the lipid film and encapsulate the hemoglobin therein, and (c) separating out the resulting lipid-encapsulated hemoglobin as cells from the solution. - 2 A process for the preparation of synthetic hemoglobin cells which comprises the steps of: (a) bringing stroma-free hemoglobin in a physiologically compatible solution into proximity with a film of naturally occurring lipid, (b) subjecting the components of step (a) to ultrasonic energy to break up the lipid film and encapsulate the hemoglobin therein, and (c) separating out the resulting lipid-encapsulated hemoglobin as cells from the solution.
- 3. The process of claim 2, wherein the ultrasonic energy has a frequency of 500,000 Hertz.
- 4. The process of claim 2, wherein said lipid includes a sterol.
- 5. The process of claim 2, wherein said sterol is cholesterol.
- 6. The process of claim 2, wherein said lipid includes a phospholipid.
- 7. The process of claim 6, wherein said phospholipid is selected from the group consisting of lecithins, cephalins, sphingomyelins and mixtures thereof.
- 8. The process of claim 2, wherein said lipid includes, in combination, lecithin, phosphatidic acid and cholesterol in a ratio by weight of combined lecithin and phosphatidic acid to cholesterol of approximately 3 to 1.
- 9. The process of claim 2, wherein the synthetic hemoglobin cells range from 1 to 10 microns in greatest dimension.
- 10. Synthetic hemoglobin cells whenever produced by the process of claim 1, or by an obvious chemical equivalent thereof.
- 11. Synthetic hemoglobin cells whenever produced by the process of claim 2, or by an obvious chemical equivalent thereof.
- 12. Synthetic hemoglobin cells whenever produced by the process of claim 3, or by an obvious chemical equivalent thereof.
- 13. Synthetic hemoglobin cells whenever produced by the process of claim 4, or by an obvious chemical equivalent thereof.
- 14. Synthetic hemoglobin cells whenever produced by the process of claim 5, or by an obvious chemical equivalent thereof.
- 15. Synthetic hemoglobin cells whenever produced by the process of claim 6, or by an obvious chemical equivalent thereof.
- 16. Synthetic hemoglobin cells whenever produced by the process of claim 7, or by an obvious chemical equivalent thereof.
- 17. Synthetic hemoglobin cells whenever produced by the process of claim 8, or by an obvious chemical equivalent thereof.
- 18. Synthetic hemoglobin cells whenever produced by the process of claim 9, or by an obvious chemical equivalent thereof.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US69490376A | 1976-06-10 | 1976-06-10 | |
US694,903 | 1976-06-10 |
Publications (1)
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CA1095444A true CA1095444A (en) | 1981-02-10 |
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ID=24790735
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Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CA279,939A Expired CA1095444A (en) | 1976-06-10 | 1977-06-06 | Encapsulated hemoglobin and method of making the same |
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US (1) | US4133874A (en) |
JP (1) | JPS6026092B2 (en) |
BE (1) | BE855481A (en) |
CA (1) | CA1095444A (en) |
DE (1) | DE2725696A1 (en) |
FR (1) | FR2354095A1 (en) |
GB (1) | GB1578776A (en) |
NL (1) | NL7706417A (en) |
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- 1977-06-03 GB GB23586/77A patent/GB1578776A/en not_active Expired
- 1977-06-06 CA CA279,939A patent/CA1095444A/en not_active Expired
- 1977-06-07 BE BE178277A patent/BE855481A/en not_active IP Right Cessation
- 1977-06-07 DE DE19772725696 patent/DE2725696A1/en not_active Withdrawn
- 1977-06-09 JP JP52068368A patent/JPS6026092B2/en not_active Expired
- 1977-06-09 FR FR7717721A patent/FR2354095A1/en active Granted
- 1977-06-10 NL NL7706417A patent/NL7706417A/en not_active Application Discontinuation
-
1978
- 1978-02-10 US US05/876,717 patent/US4133874A/en not_active Expired - Lifetime
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DE2725696A1 (en) | 1977-12-22 |
NL7706417A (en) | 1977-12-13 |
JPS6026092B2 (en) | 1985-06-21 |
FR2354095B1 (en) | 1980-04-25 |
FR2354095A1 (en) | 1978-01-06 |
JPS52151718A (en) | 1977-12-16 |
US4133874A (en) | 1979-01-09 |
BE855481A (en) | 1977-12-07 |
GB1578776A (en) | 1980-11-12 |
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