SOL-GEL ENCAPSULATED ENZYME BACKGROUND
The present invention relates to a porous glass structure prepared by the sol-gel process. In particular, the invention relates to a porous glass structure which has an active biological material entrapped therein.
Enzymes are commonly used as reactants in manufacturing, catalytic and analytic processes. Encapsulated or entrapped enzymes are used with increasing frequency as micro-catalysts and analytic devices of very high sensitivity. For example, enzymes have been enclosed in membrane systems and used as high- sensitivity monitoring devices.
Such membrane systems, however, are cumbersome and difficult to miniaturize. The enzymatic reactions must be monitored by complex electronic means. Results from the systems are frequently unreliable and nonreproducible.
It would be highly advantageous to encapsulate enzymes in a porous, transparent glass structure, such as, such structures prepared by the sol-gel process. Such an encapsulation would be significantly easier to miniaturize and would be far less cumbersome and far more reliable than membrane encapsulation systems. Furthermore, enzyme encapsulation within a transparent glass structure would allow for the monitoring of many enzymatic reactions by using simple, photometric monitoring systems.
Unfortunately, a high activity enzyme encapsulation system using a porous, transparent glass structure has not as yet been demonstrated. Braun, et al. , described in "Biochemically Active Sol-Gel Glasses: The Trapping Of Enzymes," Materials Letters. Vol. 10, No.
1, September 2, 1990, pp. 1-5, the encapsulation of an enzyme in a sol-gel glass. The reported activities of the enzyme encapsulated by Braun, et al., was only about 30%, it was not reported whether or not the glass was transparent and the Braun procedure did not result in a monolith.
Accordingly, there is a need for a porous, transparent glass structure which encapsulates an enzyme in such a way that the natural activity of the enzyme is not impaired.
SUMMARY
These needs are met by the present invention.
The invention is a protein encapsulated in a porous, transparent glass prepared by the sol-gel process utilizing a unique combination of operating conditions. The process comprises initiating the acid catalyzed hydrolysis of a metal al oxide in water by applying ultrasonic energy to the metal alkoxide/water combination, buffering the solution to a pH of about 5-6, adding and dispersing the enzyme in the solution, gelling the composition, aging and drying the mixture.
Further, the invention is an optically transparent glass with an extensive, microscopic, interconnecting pore structure having virtually all of a biological material added in the preparation stage entrapped in the structure, with a high percentage of the activity of the biological material being retained.
Still further, the invention is the process for forming the sol-gel glass with entrapped active biological material, particularly thin films as small as 1000 Angstroms thick or shaped gels having dimensions in
its smallest direction of at least 0.5 centimeters (a monolith) .
The process results in a product useful for forming into sensors for qualitatively and quantitatively detecting the presence of numerous compounds, both organic and inorganic, which react with the entrapped material. Additionally, because of the optical transparency of the glass, photometric detection techniques can be utilized to monitor the changes in the entrapped enzyme or its environment resulting from its use.
DRAWINGS
These and other features, aspects, and advantages of the present invention will become better understood with reference to the following description, appended claims, and accompanying drawings, where:
Figure 1 is a flow diagram depicting an exemplary enzyme encapsulation process having features of the invention.
Figure 2 is a graph showing the pore size distribution in a sol-gel glass made according to the process depicted in Figure 1.
DESCRIPTION
Figure 1 depicts an exemplary process embodying features of the invention. A metal alkoxide is mixed with water and an acid catalyst at station 12 to form a solution with a pH of about 2 or less and the mixture is exposed to ultrasonic energy, for example, by placement in an ultrasonic bath at station 14 to assure a uniform mixture and to initiate the polymerization process. The
mixture should be removed from the ultrasonic bath before gelation occurs, usually about one to about sixty minutes, preferably about fifteen minutes. After removal of the ultrasonic energy, the mixture, a silica sol, is aged for a short period of time, usually about one to about sixty minutes, preferably about twenty minutes, mixed with a buffer solution at station 16 to raise the pH above about 5, but below 7, preferably between 5 and 6, creating a buffered silica sol 18, and the desired active biological material, such as a protein is added to the silica sol at station 20. The extent of the aging time is not critical as long as the buffer solution is added before gelation occurs. The mixture is then placed in a plastic container and the container opening is sealed with paraffin, such as a paraffin film sold under the tradena e Parafil ® , to maintain the water content constant. Gelation occurs in about five minutes at a pH of 6, and somewhat slower at pH 5 (about ten to fifteen minutes) . The gel 21 is allowed to age in the sealed container for two to 20 or more days, the preferred period being ten to twenty days at station 22 and then dried slowly for several days (for example, 8 days to 4 weeks) at ambient conditions by piercing or removing the paraffin seal at station 24. The result is a transparent glass with entrapped protein 26.
The sol-gel process of the present invention is suitable for the preparation of many different types of oxide glasses and for the entrapment of various different active biological materials. Although, for illustrative purposes, the method is described in respect to a particular precursor compound, namely tetramethylorthosilicate (TMOS) , and a particular type of active biological material, namely proteins, it is to be understood that the method is not so limited but is also applicable to other silicon alkoxides such as tetraethylorthosilicate (TEOS) and other active silicon
compounds. Besides use of other alkoxides of silicon, the invention contemplates the use of other metal alkoxides prepared by adding methanol, ethanol, isopropanol and other similar alcohols to the oxides of various metals and non-metals, including, but not limited to aluminum, titanium, zirconium, niobium, hafnium, chromium, vanadium, tungsten, molybdenum, iron, tin, phosphorus, sodium, calcium, and boron, or combinations thereof. Additionally, the precursor material or the sol-gel may be tagged by known methods with readily detected substituents, such as optically active groups or constituents which respond to the byproducts of the action of the proteins. Alternatively, other optically active materials may be encapsulated with the protein as indicators of the results of reactions involving the proteins. Other optically active materials include luminescent amino acids, such as tryptophan or other similar materials. Silicon compounds are preferred because silicon chemistry is highly conducive to forming glasses. Among silicon compounds, TMOS is preferred over other materials, such as TEOS, because it reacts faster and does not require alcohol to form a sol.
Further, hydrochloric acid is utilized in the examples but other acids may be utilized to catalyze the reaction between TMOS and water. While HC1 is preferred, other suitable acid catalysts include other mineral acids such as sulfuric acid, nitric acid, phosphoric acid,etc. and organic acids such as acetic acid, tartaric acid, phthalic acid, maleic acid, succinic acid and the like and anhydrides of the mineral or organic acids. While acid catalysis is preferred, it is possible to use a base catalyst. However, base catalysts generate rapid gelation, thus making control of the process and the production of monoliths (shaped gels with the smallest dimension greater than a few millimeters) extremely difficult.
Suitable biological materials for encapsulation include, but are not limited to, nucleases, such as RNase A or RNase TI, proteases, such as proteinase K or chymotrypsin, oxidases, such as alcohol oxidase or glucose oxidase, esterases, such as acetylcholine esterase or phosphodiesterase II, isomerases, such as aldolase or glucose isomerase, various proteins including 0 2 binders, such as hemoglobin or myoglobin, electron transfer proteins, such as cytochrome c, metal and metal ion binders, such as aequorin, iron and bicarbonate binders, such as transferrin, free radical inhibitors, such as superoxide dis utase and other active biologicals such as ureases. One skilled in the art can readily supplement this list with other biological materials which can be entrapped by the process of the invention; the entrapped material not being a limiting factor. Additionally, the biological materials may be modified or tagged by addition of readily detected substituents such as ions, ligands, optically active groups or other constituents commonly used to tag biological or chemical compounds, suitable luminescent tag include Mn + or other rare earth metal ions.
The resultant product 26 is a porous, transparent glass (a xerogel) with virtually all of the biological material entrapped inside its pores. Because of the preparation conditions selected, the biological material retains a significant portion of its activity, usually in excess of 80%. During the drying process, the mixture shrinks in size resulting in a volume decrease to about 10% to about 15% of its wet state volume. Based on the initial quantity of solids in the mixture, the calculated pore volume of the dried product is from about 20% to about 80%. The properties of the resultant glasses indicate that the process of the invention results in a highly porous structure which, at the same time, has an extensive network of very small diameter
interconnecting channels. If the channels were not small, at least a portion of the entrapped biological material would elute from the matrix. If an extensive interconnected structure did not exist the substrate would not be able to reach the active material, thus exhibiting what would appear to be a decrease in the activity of the active material. Additionally, the dimensions of the channels in the porous network must be relatively small, at most no more than about 0.4 microns, or the optical transparency of the glass would be compromised. Figure 2 is a pore size distribution curve of a typical sol-gel glass with encapsulated protein (myoglobin) . Another significant property of the resultant glasses with entrapped biologicals is the storage life of the product. When compared to the storage life of active biological materials not encapsulated, the sol-gel glass entrapped materials have a significantly extended shelf life. Entrapped materials remain active, without significant reduction of activity, for at least seven months as demonstrated by superoxide dismutase entrapped in a sol-gel made according to the process herein described. Other examples include a shelf life in excess of three months for myoglobin and hemoglobin.
As a result of the extremely small pore dimensions, the glasses produced by the process described hereinabove are optically transparent. This property is highly significant when the active biological material is an enzyme and the partially or fully dried sol-gel glass with entrapped enzyme is used as a sensor. The optical clarity of the glass allows optical analytical means to be used to characterize and monitor changes in the enzyme or substrate when exposed to the enzyme. These changes can be directly monitored or fiber optics can be utilized to observe the changes and to transmit optical information to a remote spectroscopic instrument for
analysis. For example, enzymes were found to have no change in their spectroscopic properties when entrapped by the described process and the spectroscopic characteristic of the reaction of the enzyme with a substrate were the same as elicited by unbound enzymes. Because of the light transmission characteristics of the glasses, UV, IR and visible light optical spectroscopy as well as fluorescence, luminescence, absorption, emission and reflection techniques are all suitable for quantitative and/or qualitative monitoring of chemical changes produced by the sol-gel glasses with entrapped enzymes prepared according to the invention and sensors utilizing the sol-gel glass entrapped enzymes.
The invention will be further described in connection with the following examples which are set forth for purposes of illustration only.
EXAMPLE 1 Cytochrome c , Myoglobin. Hemoglobin or
Superoxide Dismutase 15.22g of tetramethoxysilane (TMOS), 3.38g of deionized water, and 0.22g of 0.04N HCl were added to a plastic beaker, placed in an ultrasonic bath (BRANSON Model 2200 having a well with a 3 1/2 inch diameter and a 3 1/2 inch depth or a BRANSON Model 3 with a well measuring 5 1/2 x 9 1/2 x 4 inch well) and stirred for about 15 minutes. The resultant single phase sol was aged at room temperature for twenty minutes and a buffered sol was then prepared by mixing equal amounts of buffer solution and silica sol, i.e., 2mL of 0.01M sodium phosphate or 2mL of 0.001M sodium acetate with 2mL of the silica sol. The desired amount of active biological material (cytochrome c, myoglobin, hemoglobin or
superoxide dismutase) was then added to, and dispersed in the buffered sol in the quantities listed in Table 1. For example, Sample 5, Table 1 specifies 4.Oml sol, 4.0ml buffer and 2.0ml of O.OlmM cytochrome c. The biological containing buffered sol was poured into a 4mL polystyrene cuvette and the opening in the cuvette was sealed using a paraffin film. The material was allowed to age in the sealed container for 7 to 21 days. The paraffin film was then pierced and the mixture was allowed to dry for 10 to 60 days. The resultant product was a transparent colored porous glass with the biological material entrapped therein. The sol-gel glass containing superoxide dismutase was blue-green in color, the sol-gel glass containing cytochrome c was colored deep red, and the sol-gel glass containing myoglobin was colored beige or pale orange. A typical mixture contained about O.lOg of solid material
(TMOS, phosphate from the buffer and active biological material) and about 0.9g of evaporatable liquid (10 to 15% solids) . Upon drying, the mixture shrinks to about 12.5% of its original volume resulting in about 50% voids and an apparent density of 1.2g/cc.
It has also been found that the entrapped active biological material has an improved shelf life over that of the comparable free biological material stored at room temperature. An encapsulated superoxide dismutase has been demonstrated to have a shelf life in excess of 210 days without any significant decrease in activity or spectroscopic changes. In contrast thereto, the same material stored at room
temperature in solution will show a much greater loss of activity for the same time period.
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Figure 2 is a graph showing the pore size and distribution of pore sizes in the dried sol-gel glass (xerogel) encapsulating myoglobin determined using gas adsorption techniques, the y axis being dimensionless numbers, experimentally derived, which show the relative concentration of pores of different sizes. The mean of the radii is about 15 Angstroms, a high percentage (80% or more) of the pores have radii below 30 Angstrom in size and the maximum pore radii is about 100 Angstroms. The apparent density of the glass is 1.2g/cc and the specific surface area, derived mathematically from Figure 2, is between 400 and 800m 2 /g. Xerogels containing other active biological materials prepared as described above showed similar properties. This combination of properties is believed to be unique and to be a result of the processing conditions described above.
EXAMPLE 2 Peroxidase or Glucose Oxidase
A single phase sol was prepared in an ultrasonic bath using (a) the quantities listed in Example 1, or (b) 30.44g TMOS, 7.2g 0.04M HC1 and 7.2g double deionized water and aged following the procedure of
Example 1. In accordance with Table 1, a quantity of the single phase sol was then cooled to 10°C, mixed with a buffering solution of sodium phosphate cooled to about the same temperature, the mixture was aged for 2 min in an ice bath, and an amount of buffered peroxidase or glucose
oxidase solution in quantities and concentrations listed in Table 1 and cooled to 2°C was added to the cold buffered sol. The cold mixture was aged for 7 to 20 days in a refrigerator at about 4°C, the paraffin film was punctured and the sol was allowed to dry for 10 to 60 days while being held either 4°C or room temperature. The resultant product, was a catalytically active, transparent porous glass having the peroxidase or glucose oxidase entrapped in the porous structure.
EXAMPLE 3
Trinder ® (Glucose) Reagent A single phase sol was prepared and aged following the procedure of Figure 1 and then cooled to less than 10°C. Trinder (glucose) reagent was reconstituted in doubly deionized water (50mL) . The reconstituted solution contained 4- aminoantipyrine (1.Ommol/L) , p- hydroxybenzene sulfonate (40mmol/L) , peroxidase from horseradish (20,000 units/L) and buffer at pH 7.0. The pH of the Trinder (glucose) reagent was then adjusted to a pH between 5 and 6, using 1.5N phosphoric acid, cooled to 4°C, and the desired amount (see Table 1) was added to the chilled single phase sol at a ratio of three parts reagent to 2 parts silica sol. The cold mixture was placed in a cuvette, sealed with a paraffin film, and aged for 7 to 20 days in a refrigerator at
4°C. The paraffin film was then punctured to allow the mixture to dry while being
held for 10 to 60 days at 4°C. The resultant product, a transparent, colored porous glass with the biological material entrapped in the porous structure underwent a color change with an increase in absorption at 500nm when exposed to glucose.
The enzymatic activity of glucose oxidase in combination with peroxidase as well as the activity of the Trinder reagent was tested by exposing the entrapped glucose oxidase to /3-D-glucose and o-dianisidine. It is known that glucose oxidase catalyzes the oxidation of β- D-glucose to D-gluconic acid and hydrogen peroxide. The peroxidase then uses hydrogen peroxide to catalyze the oxidation of o-dianisidine resulting in a colorimetric change at 500nm (red solution) . The identical color change (both quantitatively and qualitatively) was observed in aged, dried glucose oxidase-peroxidase gels.
In order to determine if the active biological material was evenly distributed throughout the gel, the sol-gel with entrapped material was sliced into several pieces. All slices showed the same response — an intense red color when exposed to the solutions described above. In order to determine if the active biological material was, in fact, encapsulated into the glass and would not leach out of the porous material, the glucose oxidase-peroxidase gels were repeatedly washed with buffered solution and the activity of the wash solutions were tested by addition of β-D-glucose and o-dianisidine. No color change was observed in any of the wash solutions.
Trinder solutions were tested in a like manner.
Gels prepared from a Trinder reagent having a pH=7 showed no color change when exposed to glucose. Additionally,
when these gels were washed with buffer the Trinder solution was shown to be leached from the sol-gel glass as evidenced by a red color in the wash solution when exposed to glucose. However, preparation of the sol-gel glass with a Trinder solution buffered to either pH=5 or 6 resulted in glasses which showed the red color response when exposed to glucose and washing solutions were unable to leach the active material from the glass as shown by an absence of the red color response in the wash solutions.
To determine the effectiveness of the encapsulation process on other biological materials the following tests were performed:
a. A gel was prepared from l.OmM bovine CuZnSOD (copper zinc superoxide dismutase) in ImM NaOAc buffer (pH 5.8). A portion of the aged gel was then dried to form a xerogel. The visible absorption spectra for an aged gel with entrapped material as well as the glass resulting from drying the gel was unchanged from the spectra of the same CuZnSOD in solution and exhibited the characteristic d-d transition (680nm) and the imidazolate-to-Cu charge transfer transition (420nm shoulder) . After treatment of the xerogel with lOOmM EDTA solution (pH=3.8) the copper absorption band disappeared. This is the same response seen when CuZnSOD in solution is dialyzed against EDTA. The original gel spectra can be restored by treating the gel with several aliquots of lOOmM CuS0 4 at pH=5.5 followed by several aliquots of 1M ZnS0 4 at pH=5.5. A similar response was seen when a xerogel was exposed to EDTA and then treated with CuS0 4 followed by ZnS0 4 .
b. The visible absorption spectra of cytochrome c in aged gels and xerogels had no
detectable difference from the same materials in solution. In addition, the entrapped cytochrome c can be reduced by the addition of sodium dithionite in the same manner as cytochrome c in solution. On exposure to air the encapsulated material spontaneously reoxidized without any deterioration of its spectroscopic properties.
c. Encapsulated myoglobin and hemoglobin prepared in accordance with the procedures set forth above have been compared to the same biological materials in solution. Spectroscopic analysis has shown that the myoglobin and hemoglobin retain their native structure and react with 0 2 and CO in the same manner as free myoglobin and hemoglobin.
Although the present invention has been described in considerable detail with reference to certain preferred versions and uses thereof, other versions and uses are possible. For example, the time and temperature for various steps in the process can be varied. In particular, the time and temperature in the ultrasonic bath, the aging step prior to buffering the solution, and the aging of the gel after addition of the active biological material can be eliminated, shortened or extended. Additionally, the drying step can be performed more rapidly or slower depending on the temperature and exposed surface area of the gel. However, if drying is performed too rapidly optically useful monoliths can be difficult to produce as the xerogel can develop cracks. The most critical factor limiting the time allotted for aging and drying is the surface area and volume of the gel. Additionally, it is not necessary for the xerogel to be fully dried to be used as sensors or in other applications. Partially dried xerogels prepared by the process described exhibit the same or similar properties as fully dried gels.
The process described has utility for preparing porous, transparent glasses with various different active materials or combinations of materials entrapped therein, the process not being limited to proteins. In addition, while the products have a primary utility as sensors or catalysts, they are useful for preparing unique optical materials for other applications. Glasses prepared as described above have utility as lasers, when suitable dyes, such as rhodamine or coumarins, are incorporated in the xerogel. The process also has utility to prepare photoelectrochemical cells. Therefore, the spirit and scope of the appended claims should not be limited to the description of the preferred versions contained herein.