Title of Invention

"A COMPLEX FOR ORAL DELIVERY OF DRUGS, THERAPEUTIC PROTEINS AND PEPTIDES AND VACCINES"

Abstract This invention relates to a complex for oral delivery of injectable drugs, therapeutic protein/peptides, vaccines, which are loaded in Vitamin B12 coupled particulate carriers system with spacers in between. Typically, VB12 acts as ligand for endocytosis through intestine and the particulate systems will act as a cargo protecting the intestinal labile drugs to deliver them to systemic destination and/or to the specific site required.
Full Text Technical Field
This invention relates to a complex for oral delivery of injectable drugs, therapeutic protein/peptides, vaccines, which are loaded in Vitamin B12 coupled particulate carriers system with spacers in between. Typically, VB12 acts as ligand for endocytosis through intestine and the particulate systems will act as a cargo protecting the intestinal labile drugs to deliver them to systemic destination and/or to the specific site required. Background Art
Although many peptide/proteins, pharmaceutical and vaccines are currently administered by injection, this method of delivery has a number of disadvantages which has led the scientific community to strive to develop an alternative oral delivery system for these bioactives. The inherent llimitations to parenteral delivery include (1) patient compliance (there is a need for repeated injections due to the short half-life of these molecules) (2) discomfort from this form of delivery caused by the need for repeated prolonged dosage regimen (3) highly variable bioavailability both within and between subjects for molecules such as subcutaneous insulin and (4) the non-physiological delivery pattern particularly of subcutaneous injections. Further, small increases in actual drug delivered due to changes in dosage and/or mode of delivery may cause down-regulation of the desired response to most of these bioactives. In contrast most often a pulsatile or flat delivery profile is required which mimics the normal physiological rhythm. Apart from the problem described, parenteral vaccines are of limited efficacy due to the need for repeated vaccination and due to the fact that they elicit only humoral immunity.
To address the above problems, various non-invasive delivery systems have
been attempted. The major delivery barriers common to these routes are (1) poor
intrinsic permeability due to large size and hydrophilicity of the bioactive (2)
enzymatic degradation in the hostile environment of GIT by limenal proteases
and cellular peptidases, unlike some of the traditional drugs.
Although these odds are formidable for the per oral route,
it enjoys advantages in terms of convenience and patient
compliance as well as safety, less stringent quality control, cost of therapy and for vaccines, the potential for unlimited frequency of boosting. Furthermore, oral vaccines offer the potential to protect against not only enteric pathogens (by producing localized slgA), but also a wide range of pathogens infecting other mucosa (respiratory and genital) by producing a common disseminated mucosal immune response. Furthermore oral vaccines may prove particularly useful in the elderly because mucosal immunity, unlike systemic immunity does not seem to be an age associated dysfunction. This mode of immunization may also be beneficial in the very young, because mucosal immunity develops earlier in ontogeny than systemic immunity. Over the past few decades significant efforts have been made to develop oral protein / vaccine systems using permeation enhancers (ZOT, which has proven to be toxic on long term use), enzyme inhibitors, surfactants, emulsions, colon targeted systems, bioadhesive systems and particulate systems. Although the challenges to develop oral systems are numerous, the potential therapeutic need remains high, particularly with increased identification of novel peptides and increased production of existing protein drugs from the biotechnology arena.
Peptide/protein drugs and vaccines are mostly given by parenteral routes. The problems for the oral delivery are:
1) Degradation of the above bioactives in the harsh environment of intestine and by gut proteases.
2) Their large size and hydrophilicity causes permeability problem across the intestine.
3) The fragility of these bioactives precludes to be formulated as oral dosage forms.
4) And finally their short in-vivo half lives.
Over the past 3-4 decades efforts have been made to deliver them by oral route using various formulation approaches such as emulsions, microspheres, nanoparticles, vasicular carriers such liposomes, using permeation enhancers and protease inhibitors and by protein-carrier conjugates.
Recently it has been shown that the problem of poor intrinsic permeability can be possibly overcome by delivery via a specific carrier mechanism that transports pharmaceuticals from the intestine into the circulation. In this regard, Russell-Jones
and co workers [1994] have found the possibility of coupling these bioactives with Vitamin B12 (VB12) in a manner that does not interfere with intrinsic factor (IF) mediated uptake of the VB12 carrier to the systemic circulation. Some interesting results have been achieved with oral VB12 conjugates of LHRH (Russell - Jones 1998), interferon (Habberfield and Jensen-Pippo PPO, 1996) G-CSF and erythropoietin (Habberfield, 1996). However, such successful oral delivery of conjugates cannot be obtained with many other bioactives because of the limited uptake of VB12 (1 nmol/dose), the loss of bioactivity due to covalent linkage, loss of IF affinity of VB12 (steric factor) and finally the liability of such conjugates to GIT degradation. To address the above problems we have made endeavors to make an oral delivery system (VB12-sphere conjugate) that could be targeted to the systemic circulation through VB12-IF-IFR ligand-mediated endocytosis via ileocytes of the intestine following oral administration. In vitro transport of VB12 coated polystyrene nanoparticles (non-biodegradable, hydrophobic) has been demonstrated across Caco-2 cell cultures (Russell Jones, 1997, 1999). However, the level of transport cannot be extended to other polymeric particulates in general. This can be explained by the differing physicochemical characteristics of polymers such as hydrophobicity, as hydrophobic materials may be more readily taken up by cell surface lipid bilayers. Also one of the prerequisites for drug delivery is that the polymer used to make the nanoparticles should readily or slowly be degraded in the systemic environment or by enzymes which release the pharmaceutical molecule and thereby initiate its bioactive response. Hence, the use of nonbiodegradable polymers for transport studies is not necessarily indicative, of uptake by other biodegradable polymers in general. Further, developing a system of-loading of hydrophilic peptide / protein or vaccine bioactives into hydrophobic polymeric carriers is definitely not obvious.
Among all these approaches, there was some enhancement of delivery, but major
break through of achieving therapeutically relevant dose delivery is not achieved. In
the recent past, a delivery system was invented by one of the co-inventors using VB12
as carrier molecule which is coupled with protein drug to be delivered i.e. VB12-
protein conjugates.
VB12 binds with intrinsic factor of the intestine (VB12 + IF→VB12 IF) in the
duodenum and the whole VB12 IF complex binds to intrinsic factor receptor (IFR) at
the ileum of the small intestine. From there, it is endocytosed and subsequently
transcytosed by transcobolamin (Tcll) to reach systemic circulation.
Therefore, if protein is coupled with VB12, it will be co-transported along with VB12
molecule to reach systemic circulation.
Two conditions are to be satisfied for this approach i.e.
Case 1: VB12 molecule must retain its IF affinity after being coupled to protein to be
delivered.
Case 2: Also protein molecule must retain its bioactivity after coupling to VB12.
For case 1: Native VB12 (cynocobolamin) cannot be directly coupled to protein, i.e.
VB12 losses its IF affinity by such coupling.
Therefore, in the above technology VB12 is hydrolyzed, where it forms 3 isomers (a, b
and e isomers). Among the 3 isomers, the 'e' isomer retains considerable IF affinity
after coupling to other molecules.
Case 2: For the ease of coupling to provide suitable groups and to retain full
bioactivity of protein drug, various derivatives of e-VB12 using various spacers. These
derivatives are coupled to protein drugs to be delivered. Such spacers also increases
IF affinity of e isomer. About this technology, one of the inventors of the present
application namely Dr. Gregory Russell Jones written a chapter in a book in 1995
(peptide based drug design Chapter 8). In this chapter, the author elaborated this
technology and summarized the results of VB-LHRH analogs and VB12 vasopressin
and also mentioned the possibility of conjugating other bioactives such as EPO and
G-CSF. Later in 1995, two research papers appeared in bioconjugate chemistry (1)
VB12-LHRH analogs (Volume 6, No. 1, 1995, 34-42), (2) VB12-EPO and VB12-G
CSF (Volume 6, No.4, 1995, 461-465). Later in 1996, one of the authors patented
VB12-EPO and VB12-G CSF conjugates (US patent 548068, August 1998. In this
patent he claimed any derivative of VB12 which retains IF affinity after being coupled
protein drug to be delivered. Later, in November 1996 there is another patent (US
5,574,018) on the similar system (Habber Field, who is associated D. Russell on some
research paper works earlier) i.e. VB12-EPO, VB12-G SCF and VB12-Interferon. But
the derivative used is different i.e. at hydroxy site of ribose of VB12. This
derivatization at this site and derivatives coupled to protein drug also retain IF affinity
of VB12. But in the earlier patent any derivative of VB12, which retains IF affinity
after being coupled to protein drugs is claimed. Protein drugs used in the other patent
are also same with exception of interferon.
Two US patent 5,589,463 and 5,807,832 wherein, the one of the coinventor of the present application is also main inventor describe VB12-bioactive chemical (covalent) conjugate. The bioactive may be protein, vaccine or antigen (may be of polysaccharide nature) or other biopharmaceutical (heparin) or traditional drug (neomycin). The above chemical complexes they claim to formulate in known dosage forms suitable for oral delivery gels, dispersions, emulsions, capsules, tablets etc. Technology of both these patents is somewhat similar to other patents, 5,548,064 and 5,574,018, which are, referred above. In spite of all these, the conjugates of VB12 have the following drawbacks.
1) Protein is not protected from degradation by proteases in gut.
2) All proteins cannot be coupled, as some protein bioactives may loose active molecular confirmation due to its coupling to bulky VB12 (steric factors).
3) Uptake of VB12 transport system (1 nano gram g/dose) is not sufficient for proteins which have very short half lives i.e. therapeutically relevant dose cannot be achieved.
The present invention is entirely different in that bioactive (protein/vaccine or drug) is
not directly coupled to VB12 or its analogue. Instead, VB12 or its analogues are
covalently coupled to micro/nano particle surface in which bioactive is loaded. The
micro and nano particles are made up of biodegradable and pharmaceutically
acceptable polymers.
Detailed description of the invention
The conjugation of various peptides and proteins to the Vitamin B12 molecule has
been shown to facilitate the in-vitro and in-vivo transport of these moieties across the epithelial cells of the intestine. However, pharmaceutically relevant oral delivery of many vitamin B12-pharmaceutical conjugates does not occur with many of these
bioactives due to the limited uptake capacity of the VB12 transport system, loss of
bioactivity of native protein during conjugation to VB12, loss of intrinsic factor (IF)
affinity of the conjugates and finally due to the liability of the bioactives to GI degradation. In order to overcome these shortcomings we have endeavoured to develop vitamin B12- particulate (both microspheres and nanospheres) systems that
could be taken up by the natural uptake mechanism for VB12- Different
biodegradable particulate systems (microspheres and nanospheres) were prepared.
These particles were surface modified with vitamin B12 and these preformed sphere conjugates were loaded with therapeutic proteins (insulin, hepatitis 'B' vaccine). In some cases the loading step was altered. In-vitro studies showed that insulin was protected from degradation by gastric enzymes. These systems, of different sizes, were fed to diabetic rats, whose blood glucose levels were monitored over time. The pharmacological bioavailabililty of systems was 5-25%, which showed not only oral bioactivity but also evidence of controlled release of these biopharmaceuticals. These systems showed interesting results with vaccine loaded VB12 microspheres and nanospheres. Thus the above carrier system and various strategies mentioned herein, upon further testing and optimization, may make per oral protein delivery a reality.
The present invention relates to the field of pharmaceitucal preparation of traditional injectable drugs given parenterally, peptide and protein pharmaceuticals including vaccines, particularly in the field of such pharmaceutical preparations, which are suitable for oral delivery.
Accordingly, the present invention provides a complex for oral delivery of drugs, therapeutic proteins and peptides, and vaccines, which are loaded in a Vitamin B12 (VB12) coupled particulate carrier system having one or more spacers in between, and having the formula VB12-R7R"-N, wherein each of R' and R" is a spacer for the derivative of said VB12 to provide NH2 or COOH, or SH group; N is a micro or nano particle carrier for the delivery of injectable drugs, therapeutic
proteins and peptides, and vaccines; and said VB12 retains its intrinsic factor (IF) affinity after couping to said carrier through said spacer.
In accordance with the present invention there is provided a drug delivery system comprising a protein drug (insulin and hepatitis 'B' vaccine) incorporated within the biodegradable polymeric particulates, which are coated with VB12 on their surface as shown in Figure 1, wherein D is the injectable drug, SP- is the long chain spacer to retain IF affinity of Vitamin B12 and /or for ease of coupling, BDC is the biodegradable carrier particle (microsphere/nano particle).
For the purpose of successful oral drug delivery, VB12 acts as targeting ligand for initial transport across the intestinal epithelium the circulation or for site-specific delivery of the vaccines. The VB12 carries the particulate spheres (micro and nano) along with it until the desired site reached.
In the embodiment of the present invention, VB12 - microsphere and VB12 nanoparticle systems delivery the traditional parenteral drugs, peptides/proteins including vaccines by oral route. Various biodegradable microspheres and nanoparticles are prepared with existing natural, semi synthetic and synthetic polymers. These particulates systems (micro and nano) can be surface modified to provide groups suitable for VB12 conjugation.
Vitamin B12 derivates or their various derivatives with numerous spacers (Russell Jones et al 1995a and 1995b) were coupled to particulate carriers. Different linkages, both biodegradable (cleaved by systemic enzymes) and nonbiodegradable covalent
linkages are used to link the VB12 to the particulate. The coupling also involves ionic,
coordinate covalent and strong physical adsorptive bounds.
In an embodiment, the drugs to be delivered are the traditional drugs administered
exclusively by parenteral routes, therapeutic peptides / proteins, other
biopharmaceuticals such as heparin and vaccines for immunization.
In another embodiment of the present invention, the drugs to be delivered are the
traditional drugs administered exclusively by parenteral routes selected from
gentamycin and Amikacin, therapeutic peptides / proteins selected from insulin, EPO,
G-CSF, GM-CSF, Factor VIII, LHRH analogues and Interferons, other
biopharmaceuticals such as heparin and vaccines selected from Hepatitis 'B' surface
antigen, typhoid and cholera vaccine for immunization.
In yet another embodiment, the carrier system is a pharmaceutically acceptable carrier
comprising VB12 or its analogs or their derivatives to be coupled to biodegradable
polymeric particulate carriers, which are, loaded with drugs/vaccines given parentally.
In yet another embodiment, the carrier system is transcytosed after receptor mediated
endocytosis at or around ileum by the natural uptake VBI2.
In yet another embodiment, VBI2 is the targeting ligand for the intestine to systemic
and/or lymphatic destiny.
In yet another embodiment, VB12 is native cynocobalamine (VB12) or various analogs
of VB12 viz., aquocobalimin, adenosylcobalamin, methylcobalamin,
hydroxycobalamin and/or their derivatives or alkylcobalamines in which alkyl chain
is linked to cobalt of VB12 or cynocobolamin with chloro, sulphate, nitro, thio or their
analide, ethylamide, propionamide, monocarboxylic and dicarboxylic acid derivatives
of VB12 and its analogues or monocarboxylic, dicarboxylic and tricarboxylic acid
derivatives and prominamide derivatives of 'e' isomer of monocarboxy VB]2 and
analogues of VBi2 in which cobalt is replaced by other metals (zinc or nickel etc) and
various spacers attached to these derivatives or any derivatives which retains IF
affinity after coupling to biodegradable particulate carriers.
In yet another embodiment, the derivatives of VB12 also include derivatization at
primary 5 -hydroxyl and 2 - hydroxy 1 groups of ribose moiety of VB12 and various
spacers attached at this site useful for coupling with particulate carriers.
In yet another embodiment, R '- R"- the spacers and / or agents for derivatization of
VB12 to provide either NH2 or COOH or SH groups and combination thereof are
selected from diacids or alkyl diacids (COOH-COOH, (COO(CH2)nCOO)) alkyl diamines (NH2(CH2)n-NH2) or alkyl diamides (NHCO (CH)n CONH2) or hydrazides (NH2NH2) or alkyl dihydrazides (NH2NHCO(CH2)n CONHNH2 or substitution SH group containing agents (N-succinymidyl3-(2-pyridyldithio) propionate or its long chain alkyl derivatives or acid anhydrides [(CH)n CO CO O)] or acid halide spacers (R(CH2)n COC1) or anhydroxy activated ester functional groups (NHS) which are used for the peptide bonds or surfactant derivatives or polymeric spacers, and in all cases 'n' is an integer from 1,2,3.. .infinite.
In yet another embodiment, the microspheres or nanoparticles are made up of biodegradable and pharmaceutically acceptable polymers.
In yet another embodiment, the drug loaded polymeric particulates degrade in-vivo to release and deliver a protein pharmaceutical / vaccine for its bioactive response. In yet another embodiment, the particulate carriers are biodegradable, hydrophobic or hydrophilic polymeric microspheres / nanoparticles containing surface COOH, anhydride, NH2, SH groups and combination thereof.
In yet another embodiment, the particulate carriers systems are of both monolithic (matrix type, cross-linked) and / or reservoir type (microcapsule and nanocapsule or multi particulate type (particles within the particles) or particles formed by co-addition the ligand VB12 to the polymer i.e., conjugate polymer particulates. In yet another embodiment, the particulate carriers include polysaccharide polymers viz., starch and their derivatives, pectin, Amylose, guar gum and their derivatives, dextran of different molecular weights and their derivatives, chitosan and their derivatives, chondriotan
sulphate and their derivatives and finally other natural and semi synthetic derivatives of polysaccharides and such polymers thereof.
In yet another embodiment, the cross linking agents for polysaccharides include epichlorohydrin, POCl3, borax (guar gum), aldehydes (e.g., glutaraldehyde) and other cross linking agents thereof which cross links polysaccharide polymers to give particulate carriers.
In yet another embodiment, less hydrophilic to hydrophobic particulate carriers include biodegradable polymers of poly(methylmethacrylate), poly(hydroxybutyrate), polylactide(coglycolic acid), poly(anhydride) microspheres of (fumaric acid : sebacic acid and poly fumaric acid) and poly (lactide co-glycolide), fatty acylated particulates (hydrophilic core surrounded by fatty acyl layer), LDL carriers, multiparticulate
systems (polymeric particles encapsulated in polymers of different hydrophilicity or
hydrophobicity) and finally different compositions of these polymers.
In yet another embodiment, the particulate carriers also include natural protein
polymers such as albumin, gelatin, semi synthetic or peptide based synthetic polymers
and derivatives thereof.
In yet another embodiment, the cross-linking agents such as terephthloyl chloride,
glutaraldehyde and such cross linkers which cross-links protein polymers to give
particulate carriers.
In yet another embodiment, the particulates, which are formed by polymerization of
monomers such as glutaraldehyde to poly (glutaraldehyde), and such particles formed
by polymerization of monomers and their coupling to VB12.
In yet another embodiment, the size of the system for the systemic delivery of drugs,
proteins and vaccines are ranging from few nanometers to 10 µm or more.
In yet another embodiment, these particulate systems which are modified or activated
on the surface to suit VB12 linkage and/or complexation.
In yet another embodiment, the particulate system is surface modified with VB12 and
includes coupling of VB12 to biodegradable particulate carriers.
In yet another embodiment, coupling of VB12 derivative and particulates include both biodegradable and non biodegradable bonds with and without spacers in between. In yet another embodiment, coupling between VB12 derivative and particulate carriers or surface modified / activated particulates is by amide bond with carbodiimides such as 1-ethyl 3-3dimethyl amino propyl carbodiimide (EDAC) or 1,1' carbonyl diimidazole (CDI) or N, N' diisopropyl carbodiimide (DIPC) and other peptide coupling agents or N-hydroxy succinimide activated coupling (NHS) or periodate coupling or glutaraldehyde activated coupling or CNBR mediated coupling or acid halide induced amide coupling or by the use of hydrophilic spacer ethylene glycol bis (succinimidyl succinate) (EGS) or hydrophobic spacers disuccinimidyl suberate (DSS) or via a thiol cleavable spacer with N-succinimidyl 3-(2-pyridyldithio) propionate (SPDP) and any such conjugates which retains IF affinity for VB12. In yet another embodiment, the coupling involves physical adsorptive type or complexation.
In yet another embodiment, the drugs, therapeutic peptides/proteins and vaccines are entrapped within the highly dense VB12 coupled biodegradable particulate carriers.
In yet another embodiment, the loading step of the bioactive agent in question is in the
preformed particulate carrier conjugate or within the carrier during the preparation of
the particulate spheres or during the coupling between the particles and VB12
derivative.
In yet another embodiment, the bioactives to be delivered are 1) physically entrapped
with in the particles before / after / or during the conjugation or 2) adsorbed or 3)
covalently coupled or 4) by ionic interaction or 5) complexation and any other
methods there off to load VB12 particulate systems.
In yet another embodiment, the use of surfactants, aggregation minimizers, protease
inhibitors and permeation enhancers as adjuvants in the formulations.
In yet another embodiment, the delivery systems are co-administered with exogenous
intrinsic factor (IF) of VB12, especially for IF deficient species.
In yet another embodiment, the said delivery systems are formulated into dosage
forms suitable for oral delivery.
In yet another embodiment, the oral dosage forms include solutions, suspensions,
gels, pastes, elixirs, viscous colloidal dispersions, tablets, capsules and/or oral control
release types and finally any such delivery forms for oral route.
Oral delivery of peptide and proteins has proven an elusive target for the
pharmaceutical industry over the past few decades. In the present invention a model
therapeutic protein, insulin and vaccine hepatitis 'B' vaccine were selected as model
protein. The presence of various groups on VB12 derivatives were assigned by
comparing IR spectra with that of native VB12. The 'e' carboxylate of VB12, which
has highest affinity for IF affinity, was separated and covalently linked to various
spacers to give various VB12 derivatives (Fig. 2). Various VB12 particulate systems of
different sizes were prepared and their surface was modified by various means to
suit VB12 conjugation (sizes were illustrated in the text). These VB12 coupled
particulate systems (Fig. 1) were loaded with insulin and hepatitis 'B' vaccine. It is
assumed, even if some of the carrier systems delivers sub therapeutic doses of protein
(insulin), its relevance would be adequate to trigger immune response. Consequently
the problem is far less complicated for traditional drugs that are exclusively given
parenterally (hence model drug was not chosen) and will be loaded at a later stage.
For these studies permeation enhancers were not taken along with delivery systems,
as the main objective is to study uptake mechanism of this carrier system. It is
assumed that the above additives may probably potentiate the efficacy of the carrier
system by allowing absorption through other mechanisms. In-vitro enzymatic study
showed that insulin was protected against digestive action of intestinal enzymes when
entrapped within the spheres, whereas free insulin solutions were completely
degraded under the same experimental conditions (Fig. 3). Various nanoparticles
VB12 conjugates in the size range of 160-250 nm showed interesting results with
model protein insulin. Antidiabetic activities of some representative insulin delivery
systems are shown in Figures 4-8. These systems showed maximum blood glucose
reduction of 48.4 ± 4.1 (% initial) at 5 hours. The onset of action was observed 2
hours after administration for all the delivery systems. Maximum % decrease in
glucose level (tmax) was found at the 5th hour for all the systems microparticulate
conjugates, which was maximal at the 6th hour. The above results show similar
uptake kinetics to that observed for VB12 absorption in the rat, and suggest that the
uptake be due to specific VB12 mediated absorption, which takes several hours.
During preliminary assessment of the different systems the duration of action was
studied for 7 hours for all the systems (n=3 animals), but in later studies the uptake
was continued for up to 12 hours (n=5) (Fig. 9). The Antidiabetic activity of plain
insulin was estimated following intravenous (IV) and subcutaneous administration
(Fig. 10). The pharmacological availability was assessed by the above results. The
AUC0-7 values were significantly higher (p higher size nanoparticle conjugates (p route. With microparticulate conjugates there was little difference in AUC's when
compared to i.v. route but there was reduction in blood glucose levels at 3rd, 4th, 5th
and 6th hours whereas i.v. injection of insulin showed no activity at these times. The
pharmacological availability of various particulate conjugates was from 5% to as
much as 23%. It is expected that microparticle conjugates may give good results
with vaccines for mucosal immunity, as dose to trigger immune response will not be
more than therapeutic proteins (work with hepatitis 'B' is under progress.
Nanoparticle conjugates containing 10 I.U./kg showed best results. Uptake studies
showed that the absorption is a VB12 specific carrier-mediated type (Fig. 9).
This carrier system and the various strategies described in the present invention have
potential to replace the current need for injectable protein drugs/vaccines and other
traditional drugs that are given exclusively by parenteral route. These preliminary
findings provide a sound platform for further testing and optimizing a delivery technology for peroral delivery of injectable drugs.
For easier understanding of this present invention, schematic representation of earlier patents and the present invention is shown in Figure 11 wherein the Vitamin B12 is covalently linked to the bioactive materials and administered as a solution, dispersion, paste and tablet forms. In the present invention, bioactive (protein/vaccine or drug) is not directly coupled to Vitamin B12 or its analogues, instead Vitamin B12 or its analogues are covalently coupled to micro-nanoparticle surface in which bioactive ingredient is loaded. The micro and nano particles are made up of biodegradable and pharmaceutically acceptable polymers. The drug is delivered by different modes of oral dosage forms such as tablets, capsules, pastes, gels, dispersions and emulsions. In figure 11, D is bioactive material, SP is long chain spacer to retain IF affinity of Vitamin B12 and/or for case of coupling BDC is biodegradable carrier particle (microsphere/nanoparticles) and VB12 is Vitamin B12
Brief description of the drawings
Figure 1 shows VB12 coupled particulate systems.
Figure 2 shows structure of VB12 and sites of linkage for IF affinity.
Figure 3 graphical representation which shows effect of pH and proteolysis on plain
insulin and insulin containing VB12-microsphere conjugates. Figure 4 graphical representation which shows hypoglycemic effect of oral
administration of insulin loaded VB12 -sphere conjugates in streptozotocine
induced diabetic rats. Figure 5 graphical representation which shows hypoglycemic effect of oral
administration of insulin-loaded VB12 coated microsphere/nanoparticle
conjugates in streptozoticin induced diabetic rats (n=3). Figure 6 graphical representation which shows hypoglycemic effect of oral
administration of insulin-loaded VB12 coated microsphere/nanoparticle
conjugates in streptozoticin induced diabetic rats (n=3). Figure 7 graphical representation which shows hypoglycemic effect of oral
administration of insulin-loaded VB12 coated microsphere/nanoparticle
conjugates in streptozoticin induced diabetic rats (n=3).
Figure 8 graphical representation which shows hypoglycemic effect of oral
administration of insulin-loaded VB12 coated microsphere conjugates in
streptozoticin induced diabetic rats (n=3). Figure 9 graphical representation which shows dose response relation of effective
delivery system (DDN1 CO-NH 'e' VB12) and its uptake studies. Figure 10 graphical representation which shows hypoglycemic effect of plain
conjugate and insulin given by I.V., S.C. and oral routes in streptozotocine
induced diabetic rats. Figure 11 shows schematic representation of present invention in comparison with
earlier inventions. Various VB12 sphere conjugates were prepared as follows. The following are given by
the way of illustration of the present invention and therefore should not be
construed to limit the scope of the invention.
Section I
1.0 Synthesis of VB12 analogues suitable for conjugation:
Native VB12 (Fig. 2, la) was subjected to mild acid hydrolysis (0.4 ,M, HC1 ; 72h, RT) to produce a monoacid derivative from one of the three propionamide side chains (b, d and e) of the corrin ring. The 'e' monocarboxylate of VB12 (lb), which has the highest affinity for IF (Kolhouse and Allen, 1977) was separated from b and d isomeric mixture by a combination of DOWEX AG 1x2 (Biorad) chromatography and semi-preparative C18-RP-HPLC (with a gradient of 5-100% acetonitrile in 0.1% trifluoroacetic acid) (Anton et al., 1980).
1.1 Synthesis of amino derivatives of 'e' VB12 (Russell Jones et al., 1995):
Amino derivatives of 'e' VB12 were prepared by reacting the 'e' isomer of VB12 (lb) with various spacers such as 1,2 diaminoethane, 1,6-diaminohexane, 1,12 diaminododecane, l,3-diamino-2-hydroxypropane, and l,6-diamino-3, 4-dithiahexane (a.k.a cystamine) to produce amino 'e' VB12 derivatives of l'c, Id, le, If and lg respectively. These reactions were carried out at pH 6.5 using 20 fold molar excess of diamine and l-ethyl-3- [3-(dimethyl amino) propyl] carbodiimide (EDAC) respectively.
In a separate reaction 1,12 diaminododecane was coupled to native VB12 (la) to produce amino-dodecyl-5'0-VB12 (lh) following activation of VB12 with 1,1'-
carbonyl diimidazole in dry DMF containing diisopropyl ethyl amine. Other amine derivatives can also be prepared at this site (data not shown).
All amino derivatives of VB12 were purified by RP-HPLC (semi-preparative C4 column) with a gradient of 5-100% acetonitrile in 0.1% TFA. Eluted material was further purified by adsorption to S-Sepharose and elution with 0.1 M HC1. The amino derivatives were further purified by extraction into phenol and back extraction into water after the addition of methylene chloride to the phenol phase. Finally each of the products was lyophilized and recovered as a red-powder.
1.2 Synthesis of dithiopyridyl (DTP) amino VB12 derivatives:
Three dithiopyridyl (DTP) amino-eVB12 derivatives were prepared by reacting succinimidyl 3-(2-pyridyldithio) propionate (SPDP) with 2-aminoethyl-eVB12 (lc) 6-aminohexyl-eVB12 (1d) and 12-aminododecyl-5'0 VB12 (lh) to give the respective derivatives of (li), (lj) and (1k). Typically the reaction was carried out by dissolving the amino-VBn derivative (50 mg/ml) in 0.1 M P04 buffer, pH 7.5 containing 0.1 M NaCl, followed by the addition of 800 µl of solution of SPDP (50 mg/ml in acetone) to the amino-eVB12 derivative. After overnight reaction at room temperature the DTP-amino-eVBi2 product was purified by RP-HPLC on a semi-preparative C4 column and then lyophilized.
1.3 Synthesis of long chain dithiopyridyl (DTP) amino-VBn derivatives:
These derivatives were prepared from the 6-aminohexyl-e VB12 (1d) by sequential reaction with disuccinimidyl suberate (DSS) (to give [[(monosuccinimidyl) suberyl] hexyl]-e VB12) and 1,12-diaminododecane to give [[(12-aminododecyl)suberyl]hexyl]-e VB12 (1 1). This product obtained was derivatized at the terminal amino group with SPDP, purified on RP-HPLC, and lyophilized to give derivative (1 m).
1.4 Synthesis of hydrazidyl derivatives of e-VB12 carboxylate:
These derivatives were prepared to couple to COOH particulates. Hydrazido-e VB12 (1 n) was prepared by a two-step synthesis involving the coupling of tertiary-butyl carbazate to eVB12 carboxylate and subsequent removal of the t-Boc group to generate the free hydrazide. Cys-hydrazido-eVB12 was synthesized from eVB12 cystamine' (1 g). The conversion of this material to eVB12 Cys-hydrazide (1 o) proceeded by succinylation of the e VB12 cystamine and subsequent conversion of the resultant terminal carboxyl group to a hydrazide by the procedure outlined above for eVB12 hydrazide. The (adipylhydrazido)-eVB12 reagent (1 p) was readily prepared in
one step from eVB12 carboxylate and a 20-fold excess of adipylhydrazide by the addition of EDAC.
1.5 Anilido derivative of eVB12:
eVB12 carboxylate (lb) was activated with NHS and EDAC and than coupled to para-aminopheyl acetic acid to give the VB12 anilide (lq).
1.6 Formation of VB12 derivatives containing hindered thiol groups:
Amino ethyl eVB12 (lc) was coupled with 4-[(succinimidyl oxy)- carbonyl] - -
methyl--(2 pyridyldithio) toluene using standard literature conditions (Blackey et al.,
1987).
The product -methyl--(2 pyridyldithio) tolyl]-hexyl] e-VB12 (lr) was purified by
RP-HPLC.
1.7 Formation of Iodoacetamido derivative of VB12:
Amino ethyl eVB12 was converted to iodoacetamido derivative by reaction with NHS ester of iodoacetic acid. The product (1s) was purified by RP-HPLC.
1.8 Formation of tetra peptide spacer derivative of eVB12:
eVB12 carboxylate (lb) was activated with EDAC and NHS, as previously described, was added to solution of tetrapeptide GGEA-OMe in bicarbonate buffer, pH 9.5. The product VB12-GGEA-OMe (It) was purified by RP-HPLC.
Structure of VB12 and sites of linkage for IF affinity as shown in Figure 2, wherein,
(Structure Removed)
Particulate carriers for drug loading are prepared by using natural, semi-synthetic and synthetic polymers of biodegradable nature. The polymeric particulate carriers prepared by various techniques are elaborated in this section.
2.0 Preparation of cross-linked polysaccharide cores
Polysaccharide (PC) microparticles / nanoparticles of starch (DSM/DSN) and dextran (DDM/DDN were prepared by both emulsion and gel methodologies.
2.1.1 Preparation of PC cores by sonication of the cross-linked polymer gel:
PC polymer cores were prepared according to the method of Samain et al (1989) with some modifications. 2 gm of polymer starch (Potato, soluble) / dextran (Mol. wt. 66,000 and 10,000) was dispersed (hydrolyzed) homogeneously in 1 M NaOH by vigorous shaking. Epichlorohydrin (0.18 - 0.4 ml) was then added under constant stirring for cross-linking. Shaking was stopped and the reaction was left to proceed at 70-80°C until (usually 2-6 hrs) until a soft gel (white to pale yellow) was obtained. The resulting gel was diluted with water, mechanically ground and subjected to sonication with a probe sonicator (M/s Branson ultrasonified). The particulates so obtained were fractioned into different sizes by centrifugation and the precipitate (aggregates and larger particulates) was discarded.
Finally, the chosen fractions were dried by lyophilization (DDM1, DDM2 and DDM3) or spray dried (DSM1 and DSM2) [mini spray dryer: Inlet
temperature 200°C, out let temperature 140°C; pump control 3, aspirator control 19, heating control 12, flow indicator 700] to get fine powder particulates.
2.1.2 Cross-linking hydrolyzed starch with POCb:
This was carried out according to method of Ignacio De Miguel et al., 1995 with some modifications. In this procedure, 5 gm of soluble starch (potato) was solubilized by
homogenization in 2 M NaOH (10-12 ml). The temperature was adjusted to 4°C by immersing in an ice bath then POCl3 (2.5 gm 0.33 M) was added drop-wise together with a solution of 7.5 ml of 10 M NaoH under stirring. After addition of cross-linking agent it was further stirred at level 3 for 15 minutes (homogenizer). Then pH of the preparation was adjusted 7 with dil HC1. The resulting gel was diluted with water and
subjected to sonication, centrifugation followed by spray drying (conditions same as above) to get fine powder (DSN1 and DSN2).
2.2 Interfacial cross-linking by emulsion method:
2.2.1 Cross-linking with epichlorohydrin:
Some of the PC cores prepared by the above method showed some irregularities in shape, and so fresh microparticles were prepared by an emulsion method. Typically polysaccharide (2gm Dextran mol. wt. 10,000 or soluble starch 5 gm) was solubilized in 1 M NaOH (5-10 ml). The polymer aqueous phase was emulsified in liquid paraffin (20-30 ml) containing span 80 (2%) by stirring at 15,000-22,000 rpm for 10 to 15 minutes to disperse the polymer droplets to a fine state. Then epichlorohydrin (0.5 -1.0 ml) was added under agitation at 1000-5000 rpm with constant stirring at 70-
80°C for 2-3 hrs followed by addition of water (2-5 ml) and stirred for further 2-3 hrs with intermittent addition of water. The stirring was stopped until the white emulsion turned pale yellow with visible separation of colloidal particulate system (when agitation is stopped). The resultant particles were washed thrice with equal volume of petroleum ether / hexane and sufficient water. The organic phase was separated to remove oil phase from the aqueous particulate system. The aqueous particulate system was freeze dried / spray dried as described previously to get DDN1/DDN2 and DDN3 / DSN3.
2.2.2 Cross-linking with POCl3 by emulsion method:
5 gm of starch (potato soluble) was solubilized in 2 M NaOH (12.5 ml) and emulsified in liquid paraffin (40 ml) containing 2% span 80 by stirring at 22,000 rpm
for 15 minutes. The temperature of dispersed aqueous polymer was brought to 4°C (ice bath immersion), and cross-linking was carried out by adding POCl3 (0.66 M 2.5 gm) drop wise together with a solution of 10 M NaOH (7.5 ml). This step was carried out under stirring at low rpm. The oil phase removed by washing three times with equal volumes of hexane / petroleum ether (separating funnel). The aqueous phase was diluted sufficiently, pH to 7.0 and finally spray dried as above to get fine powder DSN4.
2.3 Preparation of cross-linked guar gum (GG) and chitosan hydrogels: (Kabir et
al., 1998)
5 gm of chitosan solubilized in 0.5 M acetic acid solution (300 ml). Similarly 4 gm of guar gum was dispersed for 2 hrs at 45°C in 800 ml water. Cross-linking was carried
out by addition of 25% w/v glutaraldehyde. The reaction mixtures were homogenized for 30 at 22,000 rpm by the addition of 0.5 M concentrated H2SO4 followed by 25% w/v glutaraldehyde for chitosan emulsions and guar gum emulsions under the stirring at the same rpm. The reaction mixture was stirred for an additional 30 minutes at 15,000 rpm and kept in sealed container (separating funnel) for 48 hrs. The oil phase was removed by washing repeatedly with equal volumes of hexane. The aqueous phases were mixed with 5% w/v NaHCO3 by stirring for 3-4 hrs and then rinsed with 1 litre of water until no traces of aldehyde were found. Then the particulate systems were spray dried to get chitosan products (DCN1 and DCN2) and guar gum products (DGM1 and DGM2) respectively.
2.4 Preparation of nanoparticles by solvent evaporation method:
Procedure of Ando et al., 1999 (with some modification)
Microspheres and nanoparticles of poly (methylmethacrylate) (PMAM/PMAN), poly (hydroxybutyrate) (PHBM/PHBN), poly (D,L lactide) (PLAM/PLAN) and poly (DL lactide Co-glycolic acid) (85:15) of different ratios (PLGAM/PLGAN) were prepared by water-oil-water double emulsion solvent evaporation process. Due to the fragility of the protein bioactives encapsulation was carried out through cryopreparation (cold temperature) and carbohydrate (lyophilization and osmotic balance - in emulsion). The typical procedure is out-lined for the PLGA polymer. 500 µl (500 µg) of hepatitis 'B' surface antigen or 100-200 µl 100IU insulin containing 80-100 mM trehalose was emulsified in 9-10 ml dichloromethane containing 100 mg PLGA by sonication for 10 seconds at 4-6°C. The primary emulsion temperature was than lowered below the freezing point of inner aqueous phase (dry ice / acetone) and then emulsified with 50-60 ml of 5% PVA (88% hydrolyzed) solution containing 100 mM trehalose (4-7°C) at 6000-9000 rpm for 30-50 sec. The resulting secondary emulsion was diluted in 100 ml of 1% PVA and the system was stirred magnetically for 6-9 hrs to allow for evaporation of organic phase. The colloidal particles were finally collected by centrifugation and washing thrice with water to remove excess of PVA as well as protein bioactive. Particle size was controlled by changing level of sonication / agitation and also by centrifugation step to yield microspheres and nanoparticles and finally dried by lyophilization.
2.5 Preparation of Albumin microspheres:
2.5.1 Terephthaloyl chloride cross-linking:
3-4 ml solutions of (20-25% w/v) human serum albumin (HSA) in carbonate buffer (pH 9.8) were emulsified separately in chloroform: cyclohexane (1:4 w v/v) mixtures (15 ml) containing 4-5% v/v sorbitan trioleate. Then 20-35% solutions of terephthaloyl chloride were added (0.5, 1, 1.25 and 2.5% w/v) respectively. After 5-30 minutes of reaction time, the microspheres were washed, centrifuged, resuspended in PBS 7.4 and finally freeze-dried.
Microspheres made in the conditions 1) pH 9.8, TC 2.5%, time 5 min and 2) pH 9.0, TC 2.5% and time 30 minutes were taken for conjugation.
2.5.2 Glutaraldehyde cross-linking using an emulsion method:
0.5 ml of 100 mg HSA was homogenized in 100 ml of cottonseed oil by slowly
adding aqueous polymer phase drop wise to get w/o emulsion. 0.1 ml of an aqueous solution of glutaraldehyde (25% w/v) was added to the stabilized emulsion and stirring was continued for 1 hr, then 50 ml of acetone was added. After 1 minute microspheres were collected by centrifugation, washed with water, quenched with 10% w/v glycine solution (to remove reactive aldehyde groups), centrifuged appropriately, washed with water and lyophilized. Two centrifugation fractions were chosen HSAM and HSAN.
2.6 Preparation of gelatin nanoparticles:
These were prepared according to a modification of the procedure of Lig et al., 1997. 1 ml of aqueous gelatin solution 7% w/v was added to 90 ml of cotton seed oil at 40°C. This biphasic system was homogenized at a speed of 22,000 rpm for 7 - 9 minutes to form w/o emulsion.
The emulsion was cooled to a temperature of 4°C (gelling point of gelatin) by keeping in a refrigerator when the emulsion turned to a suspension with the formation of gelatin nanoparticles, the oil phase was washed with hexane / petroleum ether. The aqueous particulate phase was then lyophilized to get DGN1.
* Where ever cross-linking is involved, drug loading is carried out at different stages i.e. either after preparation of particulate cargo or after coupling of VB12 derivative.
2.7 Preparation of poly (anhydride) nanoparticles: Phage inversion nano-
encapsulation (PIN) method.
Poly(anhydride) WP were prepared according to the procedure of Mathiowitz et al (1997). Protein (100 IU/mg, insulin / HBsAg 500 µg/mg) to be encapsulated (0.5 - 1 ml containing appropriate quantities to be encapsulated) was sonicated with 2-4%
w/v of dichloromethane containing anhydride polymers of poly fumaric acid and sebacic acid and poly (FA:SA, 20:80) and poly fumaric acid : polylactide-co-glycolic
acid [poly (FA:PLGA)50:50] for 10-20 sec at 4-6°C. The resulting dispersion was
then poured rapidly into an unstirred bath of non-solvent such as petroleum ether
(polymer solvent - non solvent ratio 1:100) to get polymeric nanoparticles. Desired
particle size can be tailored by changing initial polymer %, solvent - non-solvent ratio
and selection of non-solvent. The optimized formulations chosen were poly [FA:SA]
80:20 ® AFSN and poly [FA:PLGA] 50:50 ® AFPLGAN.
2.8 Poly glutaraldehyde nanoparticles:
Margel, etal., (1979) processes with some modifications. 10 N NaOH was added
drop wise to solution of to aqueous glutaraldehyde (3-25%) solution 100 ml
containing surfactants (Guar C13 (1% and poly ethylene oxide mol wt. 10, 000 (s) / or
Aerosol 604 (1%)) until alkaline pH was reached (7-14, preferably 9-11). The mixture
was de-aerated with N2 gas in a tightly closed container and agitated on a mechanical
shaker for 24 hrs at ambient temperature. On hourly intervals for 4-6 hrs the pH was
adjusted to 11. Finally the system was dialyzed extensively with water and
centrifuged to get PGL spheres (nanoparticles), particles of varying sizes that can be
tailored by varying the concentration of monomer, surfactant or pH.
Two preparations of various optimized conditions PGLN1 (200 nm) (COOH) and
PGLN2 (400 nm) (CHO) were taken for coupling.
Section III 3.0 Particulate sphere surface derivitazation suitable for VB12 coupling:
Different methods of surface activation of the particulate carriers (microspheres /
nanospheres) are illustrated as follows:
3.1.1 Activation by periodate oxidation:
The particulate fractions used for periodate oxidation were DSM1, DSM2, DSN1,
DSN2, DSN3, DSN4, DCN1, DGN1 and DGN2.
The weighed quantity (250-500 mg) of microparticles was suspended in distilled water (5-10 ml) and was agitated by magnetic stirrer. Then sodium periodate (equal weight to particles) was added and mixing was continued for 45-50 minutes in the dark. The oxidized particulate system was thoroughly washed either by dialysis or centrifugation and finally lyophilized.
3.1.2 Coupling of VB12 with oxidized particles.
The oxidized particulate system (100-150mg) was then reacted with amino VB12
derivative (20-30 mg) for 18-24 hrs at 4°C in the dark. The conjugate was reduced by
sodium borohydride (4mg) for 2 h at 4°C, dialyzed and finally lyophilized as a powdered conjugate.
The VB12 derivatives and particulates used were:
(Schematic representation of the reaction as mentioned in the following table.)
(Table Removed)
3.2.1 Surface derivatization of the particulates to provide COOH groups suitable
for coupling with VB12.
Surface derivatization of spheres to provide a functional group for VB12 linkage: Particulates were succinylated using the method reported by Peyrot et al, (1994) to provide a functional group for linkage to amino VB12 derivatives. The polysaccharide cores were first completely dried and then dispersed in dichloromethane (100 mg/ml) containing 50 mg/ml triethylamine. Succinic anhydride (30% w/w was added and the reaction was carried out under anhydrous conditions at (35 ± 2°C) for 20 hrs. Finally the chosen fractions DDM3, DDM2, DSM1, DDN1, DDN2 and DDN3, were dialyzed against distilled water and lyophilized.
3.2.2 Coupling of succinylated particles with VB12 derivatives:
VB12-sphere conjugates were prepared by a direct amide linkage of the succinylated cores (DDM/DDN) with amino-derivatives of VB12. In general, coupling was carried out by dispersing succinylated dextran cores in 0.15M NaCl solution (pH 4.5) and
mixing it thoroughly with NH2-Spacer VB12 and l-ethyl-3[(dimethylamino)propyl]
carbodoiimide (EDAC) in a total of 3 ml. The pH was then adjusted to 7.5 with
NaHCO3. The reaction mixture was stirred at 30 ± 2°C for 2 hours and incubated at
4°C for 20 hours and finally freeze-dried as dark pink to red powders. Typically 100
mg of succinylated cores were coupled with molar excess of (with respect to
COOH) equal quantities of amino VB12 and EDAC.
3.2.3 Alternative method for formation of VB12 spheres using aminohexyl-5'OVB12:
1. Succinylated dextran cores were dispersed in solution (pH 4.5) at 100 mg/ml and mixed thoroughly with an equal volume of 50 mg/ml N-hydroxysuccinimide (50 mg/ml in DMF).
2. l-ethyl-3{-3(dimethylamino)propyl} carbodiimide (EDAC) (equal weight to spheres) was added at 100 mg/ml, and allowed to react for 15 minutes.
3. An equal weight of Aminohexyl-5'OVB12, (to spheres) dissolved at 100 mg/ml in 0.025 M K2C03 was added and the reaction mixture was stirred at RT for 20 hours and finally dialyzed extensively against, before being lyophilized.
(Table Removed)
3.3.1 CNBR mediated coupling:
2 gm of CNBR was dissolved in 25 ml of PBS, pH 11.5 in a fume cup board. Then
CNBR solution was added to particulate suspension under vigorous agitation for 10-15 minutes. In the above reactions pH was maintained by addition of NaOH.
Particulates were centrifuged and thoroughly washed with ice-cold distilled water and
sodium bicarbonate.
3.3.2 Coupling
25 mg of amino VB12 was added to CNBR activated particles (100 mg) suspended in
3 ml bicarbonate buffer pH 7.5 and mixed by rotation for 72 hours at 4°C and finally
washed by centrifugation and extensive dialysis against buffer.
S.No. VB12 + Particle -> Conjugate (Size)
derivative
16) le +DSM2 -> DSM2NH (CH2)12eVB12 (6.6 ± 0.7 urn)
3.4.1 Derivitization of polysaccharide particulates to provide amino groups:
One of the amino groups of the diamine (1,2 diamino ethane) was protected by adding slowly 50% v/v benzyl oxychloride / acetic anhydride and purified by dowex chromatography. The mono protected diamine was treated with periodate activated particles / succinylated particulates. The protective group on the NH2 group was removed to produce amino group of the particles on the surface.
3.4.2 Surface modification to provide thiol groups:
The amino groups modified particulate system was dispersed in phosphate buffer, pH
7.5 (50 mg/ml). SPDP was dissolved in acetone (50 mg/ml). Both the phases were mixed thoroughly and left to proceed at room temperature over night and excess of the reagent removed by dialysis. A free thiol was introduced by reduction with p-mercaptoethanol and finally lyophilized.
3.4.3 Formation of VBn - polysaccharide conjugates by disulfide linkage:
SPDP treated particles (25 mg/ml; 50 mg/ml) were suspended in sodium acetate
buffer, pH 4.5. Then 2.5 ml of DTP amino ethyl derivative (10 mg/ml) dissolved in
acetate buffer, pH 4.5. Both phases were mixed and the reaction allowed to proceed
for 48 hours at 4°C. The conjugates were dialyzed and finally lyophilized. The various
derivatives used and their conjugates from the above reaction are given below:
(Table Removed)
3.5.0 Formation of noncleavable VB12 - polysaccharide core conjugates:
1) Micro particles containing NH2 groups (DGN1-previously modified with
monoprotected diamine) on the surface were treated with 1.5 fold molar excess of ethylene glycol bis (succinimidyl succinate) [EGS] for 20 minute at room temperature. Amino eVB12 (lc) was added and the coupling carried out over night. The product was dialyzed / centrifuged and lyophilized.
2) Similarly, a particulate system (DDN2-previously modified with mono-protected diamine) was treated with disuccinymidyl suberate (DSS). The reaction intermediate was treated with amino VB12 (1d) and the conjugate washed and lyophilized.
3) To SPDP modified particles (DSM1), a solution of iodoacetemido hexyl eVB12 (1s) in diisopropyl ethylamide / diethyl formamide (1:20 v/v) was added under vigorous stirring (at inert atmosphere) for 30 minutes at room temperature and the thioether conjugate was washed and lyophilized.
4) The tetrapeptide eVB12 (1t) was conjugated to amino group containing particles ((DCN1-previously modified with mono-protected diamine, 3.4.1) in the presence of EDAC/NHS in bicarbonate buffer, pH 9.5 for 30 minutes at room temperature and was mixed with 2% acetic acid washed and lyophilized.
5) The anilido derivative of eVB12 (lq) was coupled with amino group containing particles (DSN3-previously modified with mono-protected diamine, 3.4.1) in the presence of EDAC/NHS in bicarbonate buffer, pH 9.5 for 30 minutes at room temperature and diluted with 2% acetic acid, washed and lyophilized.
(Table Removed)
3.6 Amide conjugates of amino VB12 / hydrazide and micro particles prepared by solvent evaporation by ED AC:
20 fold molar excess of amino VB12 / hydrazide VB12 and EDAC were used to couple
to particles containing COOH in bicarbonate buffer, pH 7.5 and conjugation was
carried out overnight at 4°C, washed and lyophilized. Particulates used and their VB12
derivatives are given below:
(Table Removed)
3.6.1 VB12 particulate systems coupled by disulfide linkages:
The nanoparticles PLGAN1, PLGAN2, PHBN1 and PLAN1 were surface modified
with monoprotected diamine and treated with SPDP as described previously (section
3.2.1 and 3.2.2) to give SH containing particles.
3.6.1 Derivatization of particulates to provide amino groups:
One of the amino groups of the diamine (1,2 diaminoethane) was protected by adding
slowly 50% v/v benzyl oxychloride / acetic anhydride and purified by DOWEX chromatography. The mono protected diamine was treated with particulate systems, and the protective group on the NH2 group was removed to produce amino group of the particles on the surface.
3.6.3 Surface modification to provide thiol groups:
The amino groups modified particulate system was dispersed in phosphate buffer, pH
7.5 (50 mg/ml). SPDP was dissolved in acetone (50 mg/ml). Both the phases were mixed thoroughly and left to proceed at room temperature over night and excess of the reagent removed by dialysis. A free thiol was introduced by reduction with B-mercaptoethanol and finally lyophilized.
3.6.4 Coupling:
SPDP treated particles (25 mg/ml, 50 mg/ml) were suspended in sodium acetate buffer, pH4.5. Then 2.5 ml of DTP amino ethyl derivative (10 mg/ml) dissolved in acetate buffer, 4.5. Both phases were mixed and the reaction allowed to proceed for 48 hours at 4°C. The conjugates were dialyzed and finally lyophilized.
6.6.5 Co-incorporation of surface functional groups for linkage into nanospheres
(PLGA):
Surface functional groups suitable for VB12 linkage are co-administered to the nano sphere matrix during preparation. Nanospheres containing (L-alpha-phosphatidyl ethanolamine) were prepared by mixing a chloroform solution of lipid to a polymer solution in dichloromethane (lipid to polymer ratio 1:5). Emulsification was then carried out as above (PLGA solvent evaporation process) PGLAN2. The formed particles were modified with SPDP to make them suitable for coupling. These systems were designed for conjugation to dithiopyridyl derivate of VB12.
(Table Removed)
3.6.6 Adsorption of VB12 derivative copolymers on colloidal particulates:
This was done by the method of Neal et al., with some modifications by VB12
coupling on poloxamers Neal et al., 1998.
STEP 1:
The terminal hydroxyl groups in poloxamer 407 and poloxamine - 908 were
substituted with amino groups followed by coupling of the amino copolymers with VB,2.
1) e-carboxylate of VB12 (lb) in presence of ED AC as above. The reactions were slightly modified to include an organic solvent, tetrahydrofuran instead of aqueous solvents as used previously.
2) In another reactions the amino copolymers were modified with SPDP, followed by linkage with dithiopyridyl derivatives of eVB12 (li) as described previously.
The procedure for amino derivatization of copolymers is out-lined briefly (Ref: Neal, J.C. et al., 1998). 20% w/v solution of copolymer in CH2C12 was reacted with a 2-fold molar excess of p-toluenesulfonyl chloride and pyridine at room temperature for 24 h. The p-toluenesulfonate ester product was extracted by first washing with 3 M HC1, followed by washing the organic layer with NaHCO3, with rotary evaporation used to obtain the copolymer. In the second step, the p-toluenesulfonate ester product was reacted with 25% w/v NH3 in H2O for 6 h at 120°C in a pressurized reaction vessel, to produce the aminated copolymer. The reaction products were cooled to room temperature and extracted with CH2C12 to separate the ammonium toluenesulfonate salt from the aminated copolymer. The product was then washed with base (NaOH/H2O) to produce the free amino product.
STEP 2:
The aminated copolymers of VB12 were adsorbed onto nanoparticle surface. Briefly
VB12 derivatized copolymer 0.5% w/v solutions were incubated for 12 hr with equal volume and concentration of microparticle suspension. Conjugates adsorbed on nanoparticles.
(Table Removed)
Surface adsorption
Particulate systems containing surfacial COOH groups are anionic in nature, mixing them with cationic agents gives their adsorption by ionic bond on the nanoparticle surface. The required quantity of the surface-modifying agent can be adsorbed. Typically for particles with 5-10% DMAD, 5-10 mg of this agent dissolved in 10-20

ml water containing 95-90 mg of preformed particles, was suspended by sonication on an ice bath and dried by lyophilization.
(Equation Removed)
Epoxy activation of nanoparticles: Vinod et al., 1998
A sample of (80) of pre-formed nanoparticles was suspended in 10 ml of borate buffer (50 MM, pH5) over in an ice bath. Then, zinc tetrafluroborate hydrate (catalyst 24 mg) and Denacol solution (24 mg in 4-ml borate buffer) were added while stirring at 37 ± 1°C for 30-50 minutes. The nanoparticles were separated by centrifugation and washed extensively with H20 to remove unreacted impurities.
44. Particle COOH + DeOH ----Particle COO-De-OH
Amino derivatives VB12 are coupled by 1,1'carbonyl diimidazole activation.
3.6.7 Conjugation of anhydride particles prepared by PIN method:
Weighed quantities of polyanhydride nanoparticles [ASSN1, AFPLGAN2; 50 mg each] were suspended in borate buffer [0.20 M, pH 9.0, 10ml] then a hydrazide derivative of eVB12 was added in molar excess over anhydride groups of nanoparticles. After 30 minutes acetate buffer [0.2 M, pH 5.0, 25 ml] was added. The conjugated nanoparticles were washed with 2 M NaCl, distilled water and lyophilized.
(Table Removed)
3.6.8 Disulfide conjugates of anhydride particles and eVB12:
The particles (AFSN1, AFPLGAN2) were surface modified with mono-protected
diamine and the protecting agent cleaved as described previously (Section 3.6.2). In another reaction nanoparticles (AFSN1) were surfaced modified with arginamide Ref. (Gao, J. et al., 1998). Briefly 50 mg of nanoparticle were suspended in a solution containing 12 mM arginamide in borate buffer (0.20 M, pH 9.0, 3 ml at R.T.). After
15 minutes the suspension was acidified by adding acetate buffer (0.20 M, pH 5.0, 9 ml). The particles were washed with 2M NaCl, distilled water and lyophilized. The above amino derivatized particles were coupled to SPDP to give particles containing SH groups as described previously (section 3.6.3). The coupling is carried out as described in 3.6.4.
(Table Removed)
3.6.9 Conjugation of protein polymer based micro / nanoparticles to VB12:
Different fractions of microparticles and their conjugates are given below:
In this reaction HSAM particles (100 mg) were activated with 0.25-0.5 ml, 25%w/v
glutaraldehyde in borate buffer that forms Schiff s base and gives CHO groups for
conjugation. The disulfide coupling between particulates and VB12 derivative is
carried out as described in 3.6.2., 3.6.3 and 3.6.4.
(Table Removed)
3.7 Coupling of poly glutaraldehyde nanoparticles to eVB12:
An aqueous particulate suspension (PGLN2, 100 mg/ml; 5 ml) was diluted with PBS
(pH 7.4, 15 ml). Then hydrazide VB12 derivative (10 ml, 15-20 mg) solution was
added under stirring for 2 hrs at 4°C then glycine (200 mg) was added to remove the
reactive aldehyde groups and agitation was continued for another 1 hr at R.T. The
particles were dialyzed / centrifuged and finally lyophilized. PGLN1 was coupled
with amino hexyl eVB12 (1d) by carbodiimide chemistry.
(Table Removed)
3.8 Degradable hydrogel by covalent coupling of VB12 derivatives:
Ref: Zhao, X. and Harris, J. (1998)
Two step hydrogel preparation - A two-Step Gel made from difunctional double-Ester
PEG-fifty milligrams of difunctional PEG-CM-HBA-N-hydroxysuccinimide (NHS)
2000 (vide infra) was dissolved in 0.25 mL of deionized water. To the solution was
added 0.5 mL of a buffered solution with or without FITC-BSA (10 mg/mL) and 0.25
mL of 8-arm PEG-amine solution (250 mg/mL). After vigorous shaking, the solution
was allowed to sit. The gel formed in a few minutes. A suitable pH range was 5.5 to 8.
A two-step gel made from difunctional PEG-succinimidyl carbonate containing an
ester in the fifty milligrams of difunctional ester containing PEG-succinimidyl
carbonate 6800 (vide infra) was dissolved in 0.3 mL of deionized water. To the
solution was added 0.3 mL of 8-arm PEG amine (250 mg/mL). After vigorous
shaking, the solution was allowed to sit. The gel formed in a few minutes. A suitable
pH range was 5.5-8.
Conjugates 59 and 60: Amino and hydrazide derivatives are coupled during the preparation.
Section - IV
Protein loading (insulin) into the preformed conjugate:
Typically 1001.U. of plain bovine insulin solution (40 I.U./ml) or a solution of 500 µg
hepatitis 'B' vaccine was mixed with preformed conjugates containing 100 mg of polysaccharide cores. The gel was freeze-dried and a dark pink to pale red powder and stored at 4-8°C until use.
• Wherever, cross-linking is involved drug loading is carried out at different
stages i.e. either after preparation of particulate cargo or after coupling of VB12 derivative. Specific advantages:
The delivery system described in this invention has advantages over the other reported VB12 based conjugated systems (1) The pharmaceutical to be delivered is loaded in the biodegradable polymeric carriers. (2) Particulate carriers prepared in this invention are made up of biodegradable and pharmaceutically acceptable carriers and hence degrade in-vivo to release and deliver the bioactive for its pharmacological response, which is a prerequisite for drug delivery. (3) Peptide/protein pharmaceuticals or vaccines or drugs given exclusively by parental groups can easily be loaded within the biodegradable polymers for pharmaceutical purpose. (4) Polymeric particles afford protection against harsh environment of the intestine and gut enzymes. (5) Uptake is amplified many times as compared to VB12 protein conjugated system. (6) The pharmaceutical to be delivered is not chemically modified and hence retains its full bioactivity. In-vivo performance:
Various insulin loaded drug delivery systems prepared were tested for antidiabetic activity in Streptozotocin induced diabetic rats and the results are briefed in summary section. These insulin drug delivery systems are orally administered to diabetic rats (n=number of animals). At various time intervals after feeding the rats were bled and their blood glucose levels determined.


claim :
1. A complex for oral delivery of drugs, therapeutic proteins and peptides, and vaccines, characterized in that the said drugs , therapeutic proteins and peptides and vaccines are loaded in a Vitamin B12 (VB12) coupled particulate carrier system having one or more spacers in between, and having the formula VB12-R7R"-N, wherein each of R' and R" is a spacer for the derivative of said VB12 to provide NH2 or COOH, or SH group; N is a micro or nano particle carrier for the delivery of injectable drugs, therapeutic proteins and peptides, and vaccines; and said VB12 retains its intrinsic factor (IF) affinity after couping to said carrier through said spacer, optionally along with pharmaceutically accepted additives.
2. A complex as claimed in claim 1, wherein said drugs, therapeutic proteins and peptides, and vaccines are selected from the group consisting of drugs, therapeutic proteins and peptides, and vaccines heretofore administered by parenteral routes.
3. A complex as claimed in claim 1, wherein said drug is gentamycin or
amikacin.
4. A complex as claimed in claim 1 wherein said carrier system is a
biodegradable polymeric particulate carrier.
5. A complex as claimed in claim 1, wherein said VB12 is a native
cyanocobalamin (VB12) or its analog selected from the group consisting of: aquocobalamin, adenosylcobalamin, methylcobalamin,hydroxycobalamin and their derivatives, alkylcobalamine in which alkyl chain is linked to cobalt of a VB12,cyanocobolamine with chloro, sulphate, nitro, thio or its analide, ethylamide propionamide, monocarboxylic and dicarboxylic acid derivatives of a VB12 or its analog, monocarboxylic, dicarboxylic and tricarboxylic acid derivatives and prominamide derivatives of 'e' isomer of monocarboxy VB12, and analogues of VB12 in which cobalt is replaced by other metals.
6. A complex as claimed in claim 1, wherein said at least one spacer link the primary 5'-hydroxyl and /or 2'-hydroxyl of the ribose moiety of the derivative of VB12 to said particulate carrier.
7. A complex as claimed in claim 1, wherein said spacer is the residue after linking of a compound selected from the group consisting of diacids (COOH-COOH), alkyl diacids (COO(CH2)nCOO)), alkyl diamines (NH2 (CH.2)n-NH2), alkyl diamides (NHCO (CH)n CONH2) hydrazides (NH2 NH2), alkyl dihydrazides (NH2 NHCO(CH2)n CONHNH2), SH group containing agents (N-succinymidyl2(2-pyridyidithio), propionate or its long chain alkyl derivatives or acid anhydrides [(CH)nCOCOO)], acid halide spacers (R(CH2)nCOCI), and anhydroxy activated ester functional groups (NHS) which are used for the peptide bonds or surfactant derivatives or polymeric spacers.
8. A complex as claimed in claim 1 wherein, the microspheres or nanoparticles are made up of biodegradable and pharmaceutically acceptable polymers.
9. A complex as claimed in claim 1 wherein, the drug loaded polymeric particulates degrade in-vivo to release and deliver a protein pharmaceutical/vaccine for its bioactive reponse.
10. A complex as claimed in claim 1, wherein said polymeric microsphere or nanoparticle having one or more functional groups selected from the group consisting of COOH, anhydride, NH2 and SH groups on its surface which are used for linkage to said spacer.
11. A complex as claimed in claim 1, wherein said particulate carrier is a monolithic particle, reservoir particle, multi particulate particle, or conjugate polymer particle.
12. A complex as claimed in claim 1 wherein said particulate carrier comprises a polysaccharide polymer selected from the group consisting of starch and its derivatives, pectin, amylose, guar gum and its derivatives, dextran and its derivatives, chitosan and its derivatives, chondroitin sulphate and its derivatives, and the natural and semisynthetic derivatives of polysaccharides.
13. A complex as claimed in claim 12, wherein said polysaccharide is crosslinked with an agent selected from the group consisting of epichlorohydrin, POCL3, borax, and aldehydes.
14. A complex as claimed in claim 10, wherein said biodegradable polymer is selected from the group consisting of poly methylmethacrylate,
polyhydroxybutyrate, polylactidecoglycolic acid, polyanhydride microspheres of fumaric acid:sebacic acid, poly fumaric acid, poly lactide co-glycolide, fatty acylated particulates, LDL carriers, and multiparticulate systems.
15. A complex as claimed in claim 1, wherein said particulate carrier is a natural protein polymer selected from the group consisting of albumin, gelatin, a semi synthetic or peptide based synthetic polymer and their derivatives.
16. A complex as claimed in claim 1, wherein the size of said complex ranges from about a few nanometers to about 10. nanometers to 20 n m.
17. A complex as claimed in claim 1 wherein the particulate systems used are modified or activated on the surface to suit VB12 linkage and/or complexation.
18. A complex as claimed in claim 16 wherein, the particulate system is surface modified with VB12 and includes coupling of VB12 to biodegradable particulate carriers.
19. A complex as claimed in claim 16, wherein coupling of VB12 derivative and particulates include both biodegradable and non biodegradable bonds with and without spacers in between.
20. A complex as claimed in claim 1, wherein said VB12 derivatve and said particulate carrier are coupled by amide bond of a carbodimide selected
from the group consisting of 1-ethyl 3,3 dimethyl amino propyl carbodiimide (EDAC), 1,1'carbonyl diimidazole (CDI), N,N'diisopropyl carbodiimide (DIPC), and other peptide coupling agents or N-hydroxy succinimide activate coupling (NHS) or periodate coupling or glutaraldehyde activated coupling or CNBR mediated coupling or acid halide induced amide coupling or by the use of hydrophilic spacer ethylene glycol bis (succinimidyl succinate)EGS) or hydrophobic spacers disuccinimidyl suberate (DSS) or via a thiol cleavablespacer with N-succinimidyl 3-(2-pyridyidithio) propionate (SPDP).
21. A complex as claimed in claim 1 wherein, the coupling involves physical adsorptive type or complexation.
22. A complex as claimed in claim 1, wherein said drugs, therapeutic peptide and proteins, or vaccines are entrapped with the highly dense VB12 coupled biodegradable particulate carriers.
23. A complex as claimed in claim 1, wherein the loading step of said drugs, therapeutic proteins and peptides, and vaccines to said carrier is performed during the preparation of said particle carrier, or during the coupling process between said particle carrier and said VB12 derivative.
24. A complex as claimed in claim 22, wherein said drugs, therapeutic peptides and proteins, or vaccines are entrapped within said carrier before, after, or during the process of conjugation, adsorption, covalent
coupling, ionic interaction or complexation between said carrier and said VB12.
25. A complex as claimed in claim 1 wherein the additive used are selected from the group consisting of a surfactant, an aggregation minimizer, a protease inhibitor, and a permeation enhancer.
26. A complex as claimed in claiml, wherein said delivery system is coadministered with an exogenous intrinsic factor (IF) of VB12.
27. A complex as claimed in claiml, wherein said delivery system is formulated into a dosage form suitable for oral delivery.
28. A complex as claimed in claim 27, wherein said oral dosage form is solution, suspension, gel, paste, elixir, viscous colloidal dispersion, tablet, capsule, or oral control release type.
29. A complex as claimed in claim 1, wherein said therapeutic peptides and proteins are selected from the group consisting of insulin, EPO, G-CSF, GM-CSF, Factor VIII, LHRH analogues and Interferons.
30. A complex as claimed in claim 1 wherein said vaccines are selected from the group consisting of Hepatitis 'B' surface antigen vaccine, typhoid vaccine and cholera vaccine.
31. A process for the preparation of a complex characterized in that the said complex is obtainable by a method wherein the said drug ,
therapeutic protein or peptide or vaccine is loaded by an emulsion method into a preformed conjugate of polysaccharide carrier and thus formed loaded particles are coupled to vitamin B12, either directly or via said spacers in between by a physical absorbtion method or a complexation method.
32. A novel complex for oral delivery of injectable drugs substantially as herein describe with reference to examples and figures accompanying this specification.



Documents:

1350-delnp-2003-abstract.pdf

1350-delnp-2003-claims.pdf

1350-delnp-2003-complete specification(as files).pdf

1350-delnp-2003-complete specification(granted).pdf

1350-delnp-2003-correspondence-others.pdf

1350-delnp-2003-correspondence-po.pdf

1350-delnp-2003-description (complete).pdf

1350-delnp-2003-drawings.pdf

1350-delnp-2003-form-1.pdf

1350-delnp-2003-form-13.pdf

1350-delnp-2003-form-19.pdf

1350-delnp-2003-form-2.pdf

1350-delnp-2003-form-3.pdf

1350-delnp-2003-form-4.pdf

1350-delnp-2003-petition-137.pdf


Patent Number 242195
Indian Patent Application Number 1350/DELNP/2003
PG Journal Number 34/2010
Publication Date 20-Aug-2010
Grant Date 18-Aug-2010
Date of Filing 25-Aug-2003
Name of Patentee COUNCIL OF SCIENTIFIC & INDUSTRIAL RESEARCH
Applicant Address RAFI MARG, NEW DELHI-110001, INDIA.
Inventors:
# Inventor's Name Inventor's Address
1 KISHORE BABU CHALASANI INDIAN INSTITUTE OF CHEMICAL TECHNOLOGY HYDERABAD-500007 INDIA
2 SANJAY KUMAR JAIN DR. H. S. GOUR VISHWAVIDYALAYA, SAGAR-470003 M.P. INDIA
3 GREGORY JOHN RUSSEL-JONES BIOTECH AUSTRALIA, ROSEVILLE NSW, AUSTRALIA-2069
4 PRAKASH VAMANRAO DIWAN INDIAN INSTITUTE OF CHEMICAL TECHNOLOGY HYDERABAD-500007 INDIA
5 KONDAPURAM VIJAYA RAGHAVAN INDIAN INSTITUTE OF CHEMICAL TECHNOLOGY HYDERABAD-500007 INDIA
6 KOLLIPARA KOTESHWARA RAO SAKET BIOTECHNOLOGIES, HYDERABAD - INDIA
PCT International Classification Number A61K 47/48
PCT International Application Number PCT/IN01/00027
PCT International Filing date 2001-02-26
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 PCT/IN01/00027 2001-02-26 PCT