Abstract:
The present invention refers to conjugated compounds of antiviral drugs having hepatotropic activity, methods of making these compounds, and compositions thereof.

Description:
This is a continuation of application Ser. No. 08/374,726, filed Mar. 17, 1995, now abandoned. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention refers to compounds with antiviral activity and, more particularly to conjugated compounds of antiviral drug with carriers having hepatotropic activity. 
     2. Description of the Related Art 
     In the treatment of the infection caused by viruses, the side effects produced by antiviral drugs can be reduced with the adoption of the chemotherapeutic lysosomotropic approach (Balboni P G, Minia A, Grossi M P, Barbanti-Brodano G, Mattioli A, Fiume L., Activity of albumin conjugates of 5-fluorodeoxyuridine and cytosine arabinoside on poxviruses as a lysosomotropic approach to antiviral chemotherapy, Nature 1976; 264: 181-183). 
     This consists in conjugating the drug to a macromolecule that is selectively captured from the infected cells and transported in the lysosomes therefrom. 
     If, as desired, the lysosomal enzymes break the linkage between the carrier and the drug, the latter results as being concentrated in a pharmacological active form within the infected cells. 
     
         AZTMP=3-azido-3-deoxythymidine 
    
     
         ACV=acyclovir 
    
     The chronic hepatitis by B (HBV) virus and by C (HCV) virus are a proper target for this chemotherapeutic approach because: (a) these viruses grow especially in the hepatocytes; (b) hepatocytes specifically bring inside and transport in the lysosomes some glycoproteins with galactose residues that can therefore function as hepatotropic vectors of drugs; (c) the conjugates of drug/glycoproteins can easily come into contact with the surface of the hepatocites inasmuch the hepatic sinusoid are not a barrier for proteins. 
     Following this approach and to reduce its neurotoxic side effects, the arabinoside adenine monophosphate antiviral drug (ara-AMP), active against HBV (Jacyna M R, Thomas H C., Antiviral therapy: Hepatitis B., Brit Med Bull 1990; 46: 369-382), has been conjugated with asialophetuin (AF) (Fiume L; Mattioli A, Busi C, Balboni P G, Barbanti-Brodano G, De Vries J, Altman R, Wieland Th., Selective inhibition of Ectromelia virus DNA synthesis in hepatocytes by adenine-9-β-D-arabinofuranoside (ara-A) and adenine-β-D-arabinofuranoside 5&#39;-monophosphate (ara-AMP) conjugated to asialofetuin, FEBS LEtters 1980; 116: 185-188) and with the lactosaminated albumin (L-SA) (Fiume L, Busi C, Mattioli A, Balboni P G, Barbanti-Brodano G., Hepatocyte targeting of adenine-9-β-D-arabinofuranoside 5&#39;-monophosphate (ara-AMP) coupled to lactosaminated albumin, FEBS Lett 1981; 129: 261-264; Fiume L, Bassi B, Busi C, Mattioli A, Spinosa G., Drug targeting in antiviral chemotherapy. A chemically stable conjugate of 9-β-D-arabinofuranosyladenine 5&#39;-monophosphate with lactosaminated albumin accomplishes a selective delivery of the drug to liver cells, Biochem Pharmacol 1986; 35: 967-972). In mice, both these two carriers have brought about a hepatic targeting of the drug. 
     The L-SA has a great advantage on AF: infact, the conjugates prepared with homologous lactosaminated albumin (that is, of the same species), when introduced intravenously, do not induce the antibodies formation (Fiume L, Mattioli A, Busi C, Spinosa G, Wieland Th., Conjugates of adenine-9-β-D-arabinofuranoside monophoshate (ara-AMP) with lactosaminated homologous albumin are not immunogenic in the mouse, Experientia 1982; 38: 1087-1089; Fiume L., Busi C., Preti P., Spinosa G. Coniugates of ara-AMP with lactosaminated albumin: a study on their immunogeneticity in mouse and rat. Cancer Drug Delivery 1987; 4: 145-150). In woodchuck with hepatitis by WHV (Ponzetto A, Fiume L, Forzani B, Song S Y, Busi C, Mattioli A, Spinelli C, Marinelli M, Smedile A, Chiaberge E, Bonino F, Gervasi G B, Rapicetta M, Verme G., Adenine arabinoside monophosphate and acyclovir monophosphate coupled to lactosaminated albumin reduce woodchuck hepatitis virus viremia at doses lower than do the unconjugated drugs, Hepatology 1991; 14: 16-24) and in patients with chronic infection by HBV, (Fiume L., Torrani Cerenzia M R, Bonino F, Busi C, Mattioli A, Brunetto M R, Chiaberge E Verme G. Inhibition of hepatitis B virus replication by vidarabine monophosphate conjugated with lactosaminated serum albumin, Lancet 1988; 2: 13-15. Torrani Cerenzia M R, Fiume L, Busi C, Mattioli A, Di Stefano G, Gervasi G B, Brunetto M R, Piantino P. Verme G, Bonino F. Inhibition of hepatitis B virus replication by adenine arabinoside monophosphate coupled to lactosaminated albumin. Efficacy, minimal effective dose and plasma clearance of conjugate. J Hepatol--1994; 20: 307-309), the ara-AMP conjugated to the L-SA has inhibited the viral replication at doses 3-6 times lower than those of the free drug. 
     The conjugate with L-SA should be administered intravenously owing to the high volume needed for the injection and because, by other ways antibodies are produced, and this results in a not good patient compliance in long-lasting treatments. 
     A hepatotropic carrier of ara-AMP and of other antiviral drugs allowing the intramuscular administration of the corresponding conjugates would therefore be a remarkable improvement from the therapeutic point of view. 
     It is also known that a basic polyaminoacid, the poly-L-lysine, with one third of the amino-groups substituted with galactose residues, if intravenously administered, performs a hepatic targeting of ara-AMP (Fiume L, Bassi B, Busi C, Mattioli A, Spinosa G, Faulstich H., Galactosylated poly(L-lysine) as a hepatotropic carrier of 9-β-D-arabinofuranosyladenine 5&#39;-monophosphate, FEBS Letters 1986; 203: 203-206). Moreover, the poly-L-lysine, when all or large part of its ε-amino groups are substituted, does not form antibodies even when administered by ways different from the intravenous injection (Levine B B, Studies on antigenicity. The effect of succinylation of ε-amino groups on antigenicity of benzylpenicilloyl-poli-L-lysine conjugates in random-bred and in strain 2 Guinea pig, Proc Soc Exptl Biol Med 1964; 116: 1127-1131; Sela M. Immunological studies with synthetic polypeptides, Advan Immunol, 1966; 5: 29-129). 
     It has now been found that if in the poly-L-lysine most of the ε-amino groups are substituted with the galactose and with one of the antiviral drugs known for performing their activity against hepatic viruses, three very important therapeutic effects are produced in mice: 
     (i) the conjugate loses the poly-L-lysine high toxicity which distinguished the previous galactosylated poly-L-lysine-ara-AMP conjugates (Fiume et al, FEBS Letters 1986, 203, 203-206) in which most the ε-amino groups remained unsubstituted; 
     (ii) the antiviral drug hepatic targeting is brought on even if the conjugate is not administered intravenously, and particularly, by intramuscular injection. 
     (iii) the repeated conjugate administration by intramuscular and intravenous injection does not produce antibodies. 
     The therapeutic importance of this property will be evident if it is considered that the possibility to achieve the hepatic targeting by intramuscular injection not only involves to utilize its interesting peculiar characteristics already previously mentioned in relation to the lysosomotropic approach (i.e. drastic reduction of the side effects relevant to the toxicity of the antiviral drugs), but also as much as important to make much more comfortable for the patient to undergo the chemotherapeutic-treatment which, as a rule in the viral chronic hepatitis, is long lasting. 
     In the preferred definition, the basic poliaminoacid is selected between poly-L-lysine and poly-L-ornithine and the drugs among those known for their activity against the hepatic viruses, and particularly among ara-AMP, acyclovir, ribavirin, azidothymidine, and the like. 
     The present invention refers therefore to the use, as carrier of antiviral drugs, of a basic, galactosylated polyaminoacid, said polyaminoacid being characterized in that most of the amino groups are substituted with molecules of the drug and with galactose molecules. 
     This high degree of substitution eliminates the acute toxicity of both the basic polyaminoacids and the conjugates of poly-L-lysine previously published (Fiume et al. FEBS Letters 1986; 203: 203-206) in which less than 50% of ε-amino groups were substituted by the drug and by the galactosyl residues. 
     The preparation of the conjugated compounds according to the present invention provides a two-steps procedure: 
     (a) conjugation of the basic polyaminoacid with antiviral drug or with galactose residues and 
     (b) subsequent conjugation of the conjugate resulting from step (a) with galactose residues or antiviral drugs residues, respectively. In the previous general definition it can be noticed that the two conjugation steps may be inverted. 
     As a rule, the choice is suggested by the polyaminoacid molecular weight in a sense that, with lower molecular weights, it is preferred to carry out first the conjugation with the drug and the conjugation with galactose thereafter. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The following determinations are referred to the enclosed figures in which: 
     FIG. 1 shows the chromatographic diagram on Bio Gel P 10 of the Lac-poly-L-lysine-ara-AMP (compound 4 of table 1). 
     FIGS. 2A-2H show the radioactivity distribution in liver (▪), in spleen (), in intestine (◯) and in brain (□) of female Swiss mice (28-30 g) to which the compounds of the invention (Table 1) and the unconjugated compounds for comparison have been administered by intramuscular injection. 
     FIG. 3 shows the chromatographic diagram on Bio Gel P 2 of liver extracts of mice injected with the compound 14 of Table 1. 
     FIG. 4 shows the organ radioactivity distribution in mice after intramuscular injection of LAT-  3  H!poly-L-ornithine-ara-AMP. 
     FIG. 5 shows the gel permeation chromatography of compound 9. 
     FIGS. 6A-6E show the organ distribution of compounds having high molecular weight conjugates. 
    
    
     DESCRIPTION OF PREFERRED EMBODIMENTS 
     In the preferred embodiment of the process according to the present invention the drug conjugation is carried out in a way known by itself through the imidazolate of the antiviral drug in its monophosphate form and by performing the conjugation at alkaline pH (Fiume L, Busi C, Di Stefano G, Mattioli A, Coupling of antiviral nucleoside analogs to lactosaminated human albumin by using the imidazolides of their phosphoric esters--Analyt Biochem 1993, 212: 407-411). 
     The galactose residues are preferably conjugated (step b) by reductive lactosamination in the presence of sodium cyanoborohydride (Schwartz B A, Gray G R Proteins containing reductively aminated disaccharides Synthesis and chemical characterization--Arch Biochem Biophys 1977; 181: 542-549). 
     As a non limiting example, the examples of preparation related to the use of poly-L-lysine and of poly-L-ornithine as a carrier, and of ara-AMP, acyclovir ribavirin and azidothymidine as antiviral drugs are reported, being understood that similar procedures are followed for preparing conjugates with other known antiviral drugs. 
     Conjugates with both low and high molecular weight basic polyaminoacids have been prepared. 
     I. LOW MOLECULAR WEIGHT CONJUGATES 
     A. Conjugates with poly-L-lysine 
     A.1. Preparation 
     In a commercial composition (Sigma) of poly-L-lysine with a molecular weight of 1000-4000 Da and with an average polymerization grade of 14, the polymers with a molecular weight lower than 1800 were removed by means of gel filtration on a P2 Bio Gel column eluted with 0, 2 M NH 4  HCO 3 . The polymers excluded from the column, after lyophilization, have been utilized to prepare the compounds shown in the following table 1. 
     In all the conjugates the galactose residues have been linked to the ε-amino groups by reductive lactosamination in the presence of sodium cyanoborohydride (Schwartz B A, Gray G R., Arch. Biochem Biophys 1977; 181: 542-549). 
     Compound 1 
     The poly-L-lysine has been labeled with   3  H!formaldehyde following the Jentoft and Dearborn method (Jentoft N, Dearborn D G., Protein labelling by reductive alkylation, Methods Enzymol 1983; 91: 570-579). The reaction mixture contained 44 μCi of   3  H!formaldehyde/ml. The   3  H!poly-L-lysine has been isolated by means of gel filtration on a P2 Bio Gel column and subsequent lyophilization. 
     
                                           TABLE 1__________________________________________________________________________CHARACTERISTICS OF LOW MOLECULAR WEIGHT POLY-L-LYSINE CONJUGATES.                          % ε-NH.sub.2 groups                                   Specific            μg lactose                   μg drug                          substituted by                                   ActivityCompounds        mg compound                   mg compound                          Lactose                               Drug                                   (dpm × 10.sup.3 /mg)__________________________________________________________________________1)  .sup.3 H!poly-L-lysine            0      0      0    0   12002)  .sup.14 C!LAC-poly-L-lysine            721    0      92   0   8603)  .sup.14 C!LAC-poly-L-lysine            540    206    72   28  5004) LAC-poly-L-lysine-ara-AMP            493    240    66   33  05) LAC- .sup.3 H!poly-L-lysine-ara-AMP            573    147    72   20  360006) LAC-poly-L-lysine-ara- .sup.3 H!AMP            613    176    73   22  75007) LAC-poly--L-lysine- .sup.3 H!ACVMP            638    81     80   12  440__________________________________________________________________________ 
    
     Compound 2 
     The galactose has been linked to polylysine by reductive lactosamination in the presence of sodium cyanoborohydride. 20 mg of poly-L-lysine were dissolved in 2 ml of a 0.1 M boric acid/borax buffer (pH 8.5). 80 mg of alpha-lactose, conteining 50 μCi of  D-glucose-1- 14  C! lactose (Amersham), and 50 mg of NaBH 3  CN have been added. The mixture has been incubated at 37° C. for 48 hours and the   14  C!Lac-poly-L-lysine isolated as for the compound 1. The lactose contents was measured with the Dubois et al. method (Dubois M, Gilles K A, Hamilton J K, Rebers P A, Smith F., Colorimetric method for determination of sugar and related substances, Anal Chem 1956; 28: 350-356) and referred to the dry weight of the compound. 
     Compounds 3 and 4 
     The ara-AMP has been conjugated by means of its imidazolate (Fiume L, Busi C, Di Stefano G, Mattioli A., Analyt Biochem--1993; 212:407-411). 
     This procedure is more effective than that employing the water soluble carbodiimides and avoids the chemical side reactions produced by these substances. 
     The ara-AMP imidazolate has been prepared with the Lohrmann and Orgel method (Lohrmann R, Orgel L E, Preferential formation of (2&#39;-5&#39;)-linked internucleotide bonds in non-enzymatic reactions, Tetrahedron 1978; 34: 853-855). Poly-L-lysine was dissolved (50 mg/ml) in a 0.1 M NaHCO 3  /Na 2  CO 3  buffer, pH 9.5. After the addition of the ara-AMP imidazolate (75 mg/ml), the pH was readjusted at 9.5 with HCl and the mixture incubated for 48 hours at 37° C. The conjugates have been isolated as the compound 1; the ara-AMP content was determined spectrophotometrically and referred to the dry weight of the conjugates, which were further lactosaminated (for compound 4 using unlabelled lactose). 
     Compound 5 
     The poly-L-lysine/ara-AMP conjugate, obtained as indicated for compounds 3 and 4, has been labelled with   3  H!formaldehyde (100 mCi/mmole). 
     The reaction mixture contained 2800 μCi   3  H!formaldehyde/ml. The labeled conjugate has been then lactosaminated as described above. This conjugate was used as antigen in determining the antibodies with the Minden and Farr method (Minden P, Farr R S, The ammonium sulphate method to measure antigen-binding capacity, Weir D M ed., Handbook of Experimental Immunology, Blackwell, Oxford 1973; 15.1-15.21;). 
     Compound 6 
     The conjugation of tritiated ara-AMP in this compound was performed using 1-ethyl-3-(dimethyl aminopropyl)carbodiimide (ECDI), since the ara-  3  H!AMP conversion in its imidazolate causes an almost complete loss of tritium. The poly-L-lysine was first lactosaminated as described above (compound 2), but reducing the reaction period from 48 to 24 hours in order to substitute with the sugar only 2/3 of the ε-amino groups. 
     Afterwards, the ara-  3  H!AMP was conjugated according to the above procedure (Fiume L, Bassi B, Busi C, Mattioli A, Spinosa G, Faultstich H, FEBS Letters 1986; 203: 203-206). In the preparation of this conjugate the first step was the lactosamination to reduce the number of the free ε-amino groups at the time of use of the ECDI and, therefore the possibility of polymerizing the poly-L-lysine molecules by means of this compound. 
     Compound 7 
     The   3  H!ACVMP employed to produce this conjugate was obtained by phosphorylation (Yoshikawa M, Kato T, Takenishi T., A novel method for phosphorylation of nucleosides to 5&#39;-nucleotides, Tetrahedron Lett 1967; 50: 5065-5068) of   3  H!ACV(triziate at the position 2 of the side chain) (NEN). The conjugate was prepared as for compounds 3 and 4, with the difference that the incubation of the poly-L-lysine with imidazolated   3  H!ACVMP lasted only 6 hours. The   3  H!ACVMP imidazolate was made with the above cited Lohrman and Orgel method. 
     The conjugated product of this invention obtained in the previous examples underwent chemical-physical determinations and biological tests aimed at finding the experimental confirmation of the therapeutical properties of the compounds themselves. 
     The following determinations are referred to the enclosed figures in which: 
     FIG. 1 shows the chromatographic diagram on Bio Gel P 10 of the Lac-poly-L-lysine-ara-AMP (compound 4 of table 1). 
     FIGS. 2A-2H show the radioactivity distribution in liver (▪), in spleen (), in intestine (◯) and in brain (□) of female Swiss mice (28-30 g) to which the compounds of the invention (Table 1) and the unconjugated compounds for comparison have been administered by intramuscular injection. 
     FIG. 3 shows the chromatographic diagram on Bio Gel P 2 of liver extracts of mice injected with the compound 4 of table 1. 
     FIG. 4 shows the organ radioactivity distribution in mice after intramuscular injection of LAC-  3  H!poly-L-ornithine-ara-AMP. 
     FIG. 5 shows the gel permeation chromatography of compound 9. 
     FIG. 6 shows the organ distribution of compounds having high molecular weight conjugates. 
     A.2. Experimental Observations 
     a) Average Molecular Weight of Compound 4 
     FIG. 1 shows the chromatography of the Lac-poly-L-lysine-ara-AMP (compound 4 of Table 1) on a Bio Gel P 10 (1.6×92) column calibrated with dextran blue 2000 (void volume), ribonuclease (Mr 13,700) and aprotinin (Mr 6.500). 
     25 mg of conjugate were loaded on a 1.6×92 cm column equilibrated and eluted 0.2 M with NH 4  HCO 3 . The fractions were of 2 ml. The elution volumes both of the conjugate and the markers (the latter indicated by arrows) were determined. 
     With the Whitaker method (Whitaker J R, Determination of molecular weights of proteins by gel filtratin on sephadex, Analyt Chem 1963; 35: 1950-1953) it was calculated that the conjugate average molecular weight is 9100 corresponding to a carrier with 19 lysine residues and an average molecular weight of 2400. 
     b) Distribution of the Compounds in the Organs 
     As already mentioned, FIGS. 2A-2G show the radioactivity distribution in the mice organs after the intramuscular injection of: A,   3  H!poly-L-lysine (24 μg/g); B,   14  C!Lac-poly-lysine (24 μg/g); C, ara-  3  H!AMP (5 μg/g); D,   14  C!Lac-poly-L-lysine-ara-AMP (24 μg/g); E, Lac-poly-L-lysine-ara-  3  H!AMP (28 μg/g corresponding to 5 μg/g of ara-  3  H!AMP; F,   3  H!ACVMP (4 μg/g); G, Lac-poly-L-lysine-  3  H!ACVMP (50 μg/g corresponding to 4 μg/g of   3  H!ACVMP). All the compounds were injected in a volume of 10 μl/animal in the leg&#39;s posterior muscles using a 25 μl Hamilton microsyringe. 
     The radioactivity contribution afforded by the plasma contained in the organs has been calculated (Fiume L, Busi C, Mattioli A. Lactosaminated human serum albumin as hepatotropic drug carrier-Rate of uptake by mouse liver, FEBS Letters 1982; 146: 42-46) and substracted. 
     Each datum represents the average of results achieved on 2-3 animals. 
     The standard error varied from 0.1 to 2% of the average values. 
     As illustrated after administration of   3  H!poly-L-lysine (2A), ara-  3  H!AMP (2C) and   3  H!ACVMP (2F) the radioactivity quantities in liver, spleen, intestine and brain are practically equivalent. And instead, after injection of   14  C!Lac-poly-L-lysine (2B) and of conjugates of the Lac-poly-L-lysine with ara-AMP and ACVMP, labeled in the lactose (2D) or in the drugs (2E, 2G), the radioactivity levels in liver are higher than those of the other organs. 
     The percentages of radioactivity measured in 1 gr of liver after ara-  3  H!AMP and   3  H!ACVMP (2C,2F) administration are similar to those calculated after injection of an equal dose of these drugs conjugated to the Lac-poly-L-lysine (2E,2G). 
     In kidneys, the radioactivity levels reach the same values as in liver one hour after the injection of the labeled conjugates (compound 3 in Table 1) or 1.5-2 times higher (compounds 6 and 7) In the subsequent times, the radioactivity levels of kidneys are equal or lower as compared with those of liver. The high radioactivity levels in kidneys might be explained by the remark that various polypeptides, after glomerular filtration, are endocytized by the cells of kidneys proximal tubules (Maack Th, Johnson V, Kau S T, Figueiredo J, Sigulem D., Renal filtration, transport and metabolism of low molecular weight proteins, Kidney Int 1979; 16: 251-270). The penetration into renal cells should not have any effect on the chemotherapeutic index of the Lac-poly-L-lysine/antiviral drugs conjugates. In fact, excluding acyclovir that tends to precipitate in the kidneys tubules (Balfour H H., Acyclovir and other chemotherapy for herpes group viral infections, Ann Rev Med 1984; 35: 279-291), the antiviral nucleosides are not particularly toxic for the cell of this organ. 
     c) Digestion of Compound 3 in Liver 
     The rupture of the linkage between ara-AMP and the ε-amino groups of the galactosylated poly-L-lysine within hepatic cells was demonstrated by previous researches (Fiume L, Bassi B, Bongini A., Conjugates of 9-β-D-arabinofuranosyladenine 5&#39;-monophosphate (ara-AMP) with lactosaminated albumin: characterization of the drug-carrier bonds, Pharm Acta Helv 1988; 63 137-139). FIG. 3 shows the chromatographic profiles on Bio Gel P 2 of the mice liver extracts, 2 and 6 hours after the intramuscular injection of   14  C!Lac-poly-L-lysine-ara-AMP (24 μg/g). 
     Female Swiss mice of 28-30 gr received by intramuscular injection the conjugate (24 μg/g in a total volume of 10 μl). 
     After 3 (□) or 6 () hours the mice were sacrificed (two animals for each time) and the livers have been homogenized with 4 volumes of cold water; 5 volumes of perchloric acid were immediately added and after centrifigation the supernatants were neutralized with KOH. 
     After 2 hours in the cold the potassium perchlorate was centrifuged and the supernatants freeze-dried. 
     The freeze-dried material has been redissolved with 2 ml of H 2  O and, after centrifugation to clarify the solution, 1 ml was chromatographed on a Bio Gel P 2 (1.6×92 cm) column equilibrated and eluted with 0.2 M NH 4  HCO 3 . 
     The radioactivity present in the fractions, wherein molecules included in the gel and having dimensions larger than those of lactose have been eluted, demonstrates that the poly-L-lysine is fragmented in liver even though its ε-amino groups are still linked to the sugar. 
     The symbol ◯ in the figure relates to the chromatographic profile of the extract of a homogenized liver obtained from two untreated mice and to which the conjugate (14 μg/ml) was added just before the precipitation with perchloric acid. 
     d) Production of Antibodies in Mice Treated with Compound A 
     Twelve female Swiss mice (weight of 28-30 g at the start of test) received the conjugate No. 4 (Table 1) administered in the posterior leg&#39;s muscles for five days a week for four weeks in succession (daily single dose=700 μg/animal in 10 μl 0.9% NaCl). 
     The mice were bleeded form the retroorbital plexus with ethereal anaesthesia a week after the last injection. 
     The antibodies were measured in 50 μl of serum and in triplicate by means of the precipitation method with ammonium sulphate according to the Minden and Farr procedure. 
     As antigen the conjugate 5 (table 1) was used. 
     In the presence of 50 μl of serum of 5 untreated mice, the precipitated dpm have been 78±11 (SE.) In the presence of 10 μl of a mice serum able to link either the ara-A(938 pmoles of ara-A linked by 1 ml of serum) or the ara-AMP conjugated to the L-HSA (Fiume L, Bassi B, Busi C, Mattioli A, Wieland Th., A study on the pharmacokinetics in mouse of adenine-9-β-D-arabinofuranoside 5-monophosphate conjugated with lactosaminated albumin, Experientia 1985; 41, 1326-1328), the precipitated dpm have been 1599±21. 
     In the presence of the serums of the twelve mice treated with the Lac-poly-L-lysine-ara-AMP conjugate, the precipitated dpm ranged from a minimum of 41±5 to a maximum of 80±6 dpm. 
     This result showed that none of the treated mice produced antibodies measurable with the employed method, the sensitivity of which was of about 0.5 μg/IgG/ml of serum. 
     e) Acute Toxicity of Compound 4 
     The Lac-poly-L-lysine-ara-AMP conjugate (No. 4), dissolved in 0.9% NaCl, was administered to female Swiss mice of 28-30 g intravenously (5 animals) or subcutaneously (5 animals) with a single injection of 0.4 ml/animal and in a 1.3 mg/g dose. 
     It did not show any toxicity evidence. 
     The injected dose was 50 times higher as compared with that administered by intramuscular injection in the distribution experiments of the conjugate in the organs (FIG. 2). 
     The LD 50  for female Swiss mice of the poly-L-lysine utilized for producing this conjugate, injected in the form of a hydrochloric acid salt intravenously, resulted to be within 30 and 60 μg/g. 
     f) Solubility of the Compound 4 
     In patients with chronic hepatitis B the unconjugated ara-AMP is administered at 2.5 or 5 mg/kg doses with two injections a day. 
     The Lac-poly-L-lysine-ara-AMP (No. 4) conjugate readily dissolves in a physiological solution at the concentration of 400 mg/ml. 
     A 24 mg/kg, dose corresponding to 5 mg/kg of ara-AMP, can be therefore administered to a patient of 70 Kg weight in a volume lower than 5 ml. 
     B. Conjugate with Poly-L-Ornithine 
     B.1 Preparation 
     Compound 8 
     This compound was prepared using a poly-L-ornithine HBr (Sigma) with a molecular weight of 5,300-7,600. Poly-L-ornithine (25 mg) was labelled with   3  H!formaldehyde (100 mCi/mmole)(NEN) according to Jentoft and Dearbon (Methods Enzymol 1983, 91: 570-579). The reaction mixture contained 98 μCi   3  H!formaldehyde/ml.   3  H!poly-L-ornithine was isolated from the reaction mixture by gelfiltration on a Bio Gel P2 column eluted with 0.5 M NH 4  HCO 3  and was subsequently lyophilized. Ara-AMP imidazolate was coupled to the labelled polymer using the procedure followed for compounds 3 and 4. 
     For subsequent lactosamination 10 mg   3  H!poly-L-ornithine-ara-AMP were dissolved in 1 ml 0.1 M borax/NaOH buffer, pH 10, together with 80 mg L-lactose and 50 mg NaBH 3  CN. The solution was incubated for 72 h at 37°. The lactosaminated conjugate (Lac-  3  H!poly-L-ornithine-ara-AMP) was recovered by gel filtration on a Bio Gel P2 column eluted with 0.5 M NH 4  HCO 3  and was subsequently lyophilized. 1 mg compound (specific activity 668 dpm/μg) contained 134 μg ara-AMP (spectrophotometrically determined) and 604 μg lactose (measured according to Dubois et al. Anal Chem 1956; 28: 350-356). About 90% of polymer ε-amino groups were substituted: 17% with the drug, 73% with lactose. 
     B.2. Experimental Observations 
     a) Organ Distribution of Compound 8 
     FIG. 4 shows the organ distribution of radioactivity in mice after intramuscular injection of Lac-  3  H!poly-L-ornithine-ara-AMP (36.5 μg/g, corresponding to 5 μg/g ara-AMP). Experimental procedure was as described for the similar experiments with the at-poly-L-lysine conjugates. The levels of radioactivity in liver were higher than in the other organs. Radioactivity values in kidney were 3-4 times higher than in spleen, intestine and brain. 
     II. HIGH MOLECULAR WEIGHT CONJUGATES 
     In patients with viral hepatitis the clearance of galactosyl terminating macromolecules is much slower than in mice, rats and normal humans, probably because of a slower penetration into hepatocytes (Marshall J S, Williams S, Jones P. Serum desialylated glycoproteins in patients with hepatobiliary dysfunctions. J Lab Clin Med 1978; 92: 30-37; Torrani Cerenzia M R et al. J Hepatol 1994; 20: 307-309). As a consequence, in these patients the renal elimination of the conjugates prepared with low molecular weight polyaminoacids is expected to be even greater than that measured in mice. 
     To overcome this drawback we prepared conjugates using a high molecular weight poly-L-lysine. In these conjugates also most of the ε-amino groups of poly-L-lysine were substituted by drug and galactose molecules. 
     We observed that: 
     1) High molecular weight conjugates also specifically penetrate liver cells after intramuscular administration. 
     2) The renal loss of these conjugates is very low and, consequently, the percentage of injected dose entering hepatocytes is higher than that measured after administration of low molecular weight conjugates. 
     3) High molecular weight conjugates are also devoid of acute toxicity and, after repeated intramuscular or intravenous administration, do not induce antibodies. 
     4) Due to their high solubility (more than 150 mg/ml) and heavy drug load, a pharmacologically active dose could be administered in a small volume, well compatible with the intramuscular route. 
     II.1. Preparation 
     These conjugates were prepared using a poly-L-lysine HBr with a molecular weight of 30-70,000 and a polymerization degree of 145-335 (Sigma). As in the preparation of low molecular weight poly-L-lysine conjugates drugs were coupled via the imidazolate of their phosphoric esters and lactose was linked by reductive amination in the presence of NaBH 3  CN. However, the procedure was modified: the pH, temperature, length of reaction time as well as the imidazolate concentration were all increased in the drug conjugation step. Moreover lactosamination was performed before drug coupling since at high pH high molecular weight poly-L-lysine precipitated unless a part of ε-NH 2  groups were substituted with galactose residues. 
     Compound 9 
     Reductive lactosamination of ε-NH 2  groups was carried out by dissolving 200 mg poly-L-lysine in 20 ml 0.4 M potassium phosphate buffer pH 7, together with 800 mg L-lactose and 500 mg NaBH 3  CN. After incubation at 37° C. for 24 h the pH was raised to 8 with 5 M KOH and the solution was left at 37° C. for a further 6 h. 
     Lac-poly-L-lysine was diafiltered with 0.9% NaCl and concentrated to 100 mg/ml. Lactose was measured by the phenol-sulphuric acid method of Dubois et al. (AnaI Chem 1956; 28: 350-356) using galactose as a standard; poly-lysine was determined by measuring the nitrogen according to Kjeldahl. 2 ml Lac-poly-L-lysine solution (=200 mg) were diluted with 2 ml 1 M sodium carbonate buffer, pH 11. 800 mg ara-AMP imidazolate, synthesized according to Lohrmann and Orgel (Tetrahedron, 1978; 34: 853-855), were dissolved and the pH was re-adjusted to 11 with 5 M NaOH. 
     After incubation at 50° C. for 96 h, the conjugate was diafiltered with 0.9% NaCl. Chemical characterization of the complex was performed by assaying the coupled drug spectrophotometrically and by measuring lactose as described. The interference of ara-AMP in the colorimetric analysis was subtracted. The poly-L-lysine content of conjugate was calculated from the amount of lactose, knowing the weight ratio lactose/poly-L-lysine determined before drug coupling (see above). This was possible because the bond between the sugar and lysine ε-NH 2  groups did not break down during drug conjugation, as we verified experimentally. The conjugate was concentrated in saline (0.9% NaCl) to 150 mg/ml and lyophilized after freezing to about -80° C. The concentration of conjugate was calculated without taking account of contra-ions. 
     Prior to use, Lac-poly-L-lysine-ara-AMP was dissolved with water at the concentration of 150 mg/ml. It easily dissolved provided the freezing was rapid. When necessary, the conjugate was diluted with 0.9% NaCl. 
     Compound 10 
     Prior to coupling with ara-AMP, Lac-poly-L-lysine was labelled with  3H!formaldehyde (NEN) according to Jentoft and Dearbon (Methods Enzymol. 1983; 91: 570-579). The reaction mixture contained 78 μCi   3  H!formaldehyde/ml. After diafiltration with 0.9% NaCl Lac-  3  H!poly-L-lysine was conjugated with ara-AMP as described above. 
     Compound 11 
     Ribavirin (RIBV)(1-β-D-ribofuranosyl- 1,2,4-triazole-3-carboxamide) was first phosphorylated (RIBVMP) according to (Allen L B, Boswell K H, Khwaja T A, Meyer R B, Sidwell R W, Witkowski J T. Sinthesis and antiviral activity of some phosphates of the broad-spectrum antiviral nucleoside, 1-β-D-Ribofuranosyl-1,2,4-triazole-3-carboxamide (Ribavirin) J Med Chem 1978; 21: 742-746). 
     The pyridinium salt of the phosphorylated derivative was then converted to the imidazolate (Lohrmann and Orgel, Tetrahedron 1978; 34: 853-855), which was coupled to Lac-  3  H!poly-L-lysine as described for the conjugate with ara-AMP. In this conjugate coupled RIBVMP was assayed by measuring the organic phosphate according to (Ames B N. Assay of inorganic phosphate. Total phosphate and phosphatases. Methods Enzymol 1966; 8: 115-118). 
     Due to the strong interference of RIBV with the colorimetric assay of sugar, we could not measure lactose as described for Lat-poly-L-lysine-ara-AMP and therefore we determined Lac-  3  H!poly-L-lysine content of the conjugate by counting the radioactivity. 
     Compound 12 
     3&#39;-azido-3- 2- 14  C!deoxythymidine (  14  C!AZT) (Moravek) was phosphorylated according to Yoshikawa et al. (Tetrahedron Lett 1967; 50: 5065-5068). The pyridinium salt of the phosphorylated derivative was converted to its imidazolate and subsequently coupled to Lac-poly-L-lysine. Coupling was performed as described for compound 9, but in the reaction medium the ratio of the amount of drug imidazolate to that of the polymer was 2.7 instead of 4. The chemical characterization of this conjugate was performed as described for compound 9. 
     Compound 13 
     This conjugate was prepared as compound 9, but lactosamination of poly-L-lysine was interrupted after the first 24 h. Moreover, the ratio of the amount of ara-AMP imidazolate to that of the polymer was 4,6 instead of 4. 30% of the ε-amino groups of the polymer was substituted with galactosyl residues and 64% with ara-AMP. 
     II.2. Experimental Observations 
     a) Average Molecular Weights of Compound 9 
     They were determined by permeation chromatography using HPLC equipment (Waters) with two Protein-Pak columns (125 and 300 SW) connected in series. Compound 9 (80 μg) was dissolved in 20 ul mobile phase (125 mM Na 2  SO 4  +2 mM NaH 2  PO 4  H 2  O, to pH 6.0 with 0.1 N NaOH, filtered and degassed) and chromatographed with the following conditions. Flow rate: 0.9 ml/min; detection: UV at 260 nm, 0.1 absorbance units per full scale (AUFS). Columns were calibrated with aprotinin (Mr 6,500), RNAse (Mr 13,700), HSA (Mr 69,000) and IgG (Mr 158,000). Weight average molecular weight and number average molecular weight were determined using the GPC 745/745B Waters Software. They were found to be 140,339 and 72,419, respectively. The gel permeation chromatography of compound 9 is shown in FIG. 5. 
     b) Organ Distribution of Compounds 
     Experimental procedure was as described for the similar experiments with low molecular weight conjugates. Results are shown in FIG. 6. 
     Conjugates of ara-AMP and RIBVMP were radioactive in the carrier whereas the conjugate of AZTMP was labelled in the drug moiety. 
     After i.m. administration of the conjugates labelled in the carrier (FIG. 6, frames A, C) radioactivity was high in liver and low in spleen, intestine and kidney. The percentages of injected dpm recovered in kidneys were 10-20 times lower than those measured after i.m. administration of the complexes prepared with low molecular weight poly-L-lysine. Since renal accumulation of proteins is a consequence of their glomerular filtration (Maack T H, Johnson V, Kau S T, Figuereido J, Sigulem D. Renal filtration, transport, and metabolism of low-molecular weight proteins: A review. Kidney Int. 1979; 16: 251-270), the present result indicates that, as expected, only small amounts of the high molecular weight conjugates passed through the glomeruli at least after i.m. administration (see below). 
     In mice i.m. injected with Lac-poly-L-lysine-  14  C!AZTMP the level of radioactivity in liver was from 2.5 to 6 times higher than in kidneys, spleen and intestine (FIG. 6, frame D). The difference between the amount of radioactivity in liver and in other organs was less marked than that in animals administered with the conjugates labelled in the carrier (FIG. 6, Frames A,C). This result was probably due to a partial release of the drug (and/or its metabolites) from liver cells into the bloodstream after the intracellular cleavage of the drug-carrier bond. A similar release of the drug from hepatic cells in bloodstream was observed after administration of other drug/carrier hepatotropic conjugates (Fiume L, Busi C, Corzani S, Di Stefano G, Gervasi G B, Mattioli A. Organ distribution of a conjugate of adenine arabinoside monophosphate with lactosaminated albumin in the rat. 
     J Hepatol 1994, in press; Fiume L, Mattioli A, Balboni P G, Tognon M, Barbanti-Brodano G, De Vries J and Wieland Th. Enhanced inhibition of virus DNA synthesis in hepatocytes by trifluorothymidine coupled to asialofetuin. FEBS Lett 1979; 103: 47-51). 
     When free   14  C!AZTMP was i.m. injected into mice the radioactivity was equally distributed in liver, spleen and intestine with higher values in kidneys (FIG. 6, Frame E). The rate of accumulation and decline of radioactivity after administration of free or coupled   14  C!AZTMP was different. After injection of the free drug, radioactivity accumulated in tissues within the first 15 min and then rapidly declined; after injection of the conjugated drug radioactivity in liver increased up to 4-5 h. At 1-2 h the amounts of radioactivity in liver were higher in animals injected with conjugated   14  C!AZTMP at the dose of 2 μg/g than in those administered with the free drug at 5 ug/g. 
     In mice injected intravenously with Lac-  3  H!poly-L-lysine-ara-AMP (FIG. 6, Frame B) the conjugate rapidly accumulated in liver, in these animals the values of radioactivity in kidneys were higher than in those which i.m. received the same conjugate (FIG. 6, Frame A). This can be explained considering that: 
     (i) part of conjugate molecules had a molecular weight lower than that of HSA (FIG. 5); 
     (ii) a direct relationship exists between plasma concentration and glomerular filtration of small proteins (Maack T H et al. Kidney Int 1979; 16: 251-270); 
     (iii) the concentrations of conjugate in plasma which were constantly low (less than 0.9 μg/ml) following the i.m. administration reached high values after the intravenous injection (104 μg/ml at 3 min). 
     c) Experiments of Tolerability and Immunogenicity 
     They were performed using compound 9. The conjugate administered intravenously (i.v.) to 5 mice at the dose of 1.5 g/Kg did not cause any recognizable sign of suffering. 1.5 g of Lac-poly-L-lysine-ara-AMP contained 480 mg of drug (see Table 2), a dose 300 times higher than that at which ara-AMP, when conjugated to L-HSA, inhibits virus growth in HBV-infected patients. In mice the LD 50  of poly-L-lysine used for preparing the conjugate, given i.v. as salt of HCl, was between 15 and 30 mg/Kg. To study whether Lac-poly-L-lysine-ara-AMP dissolved in saline at the concentration of 150 mg/ml can damage the tissues at the site of administration, a primary eye irritation experiment was performed in 6 rabbits by placing 0.1 ml of the solution in the conjunctival sac. No eye changes were observed in any animal. 
     Semithin sections of liver from mice and rats which received Lac-poly-L-lysine-ara-AMP administered with different schedules (see Table 3) were observed at light microscope. In none of the animals were changes found in either parenchymal or sinusoidal liver cells. Accumulation into secondary lysosomes of non-completely digested molecules (disaccharides, peptides) which can not cross lysosomal membrane results in a rapid swelling of these organelles which at light microscope appear as cytoplasmic vacuoles. Such vacuoles were observed in hepatic cells of mice and rats 24 h after a single administration of L-HSA-ara-AMP at doses 5-10 times higher than that active in HBV infected patients (Fiume L, Betts C M, Busi C, Corzani S, Derenzini M, Di Stefano G, Mattioli A. The pathogenesis of vacuoles produced in rat and mouse liver cells by a conjugate of adenine arabinoside monophosphate with lactosaminated albumin. J Hepatol 1992; 15: 314-322). The absence of vacuoles in liver cells of mice and rats after administration of high doses of Lac-poly-L-lysine-ara-AMP gave indirect evidence of a rapid digestion of this conjugate into products able to cross the lysosomal membrane. 
     To study the immunogenicity of Lac-poly-L-lysine-ara-AMP twenty four mice received the conjugate for five days a week for four consecutive weeks (single daily dose=200 μg/animal). Twelve mice were intramuscularly injected while the others were administered intravenously. A week after the last injection mice were bled and antibodies against the conjugate were measured as described for low molecular weight conjugates. None of the animals produced antibodies in amounts detectable by our assay (sensitivity about 0.5 μg IgG/ml serum). 
     From the previous experimental data it appears as most likely proved that the antiviral nucleosides galatosylated poly-L-lysine conjugates, in which most of the ε-amino groups of the omopolimer are substituted by the galactose residues and the drugs, administered by intramuscolar injection, perform a hepatic targeting of drugs without producing antibodies. 
     They do not possess the acute toxicity of poly-L-lysine used for their preparation. In comparison with conjugates with the lactosaminated albumin, that need to be injected intravenously since they are otherwise immunogeus, the conjugates provided with the galactosylated poly-L-lysine are potentially able, in the infection by hepatitic viruses, to improve the patient compliance with a prolonged administration of the antiviral agent. 
     As already mentioned, the foregoing referred to the conjugates wherein the carrier was poly-L-lysine or poly-Lornithine; the experimentally verified chemical-physical properties and biological behaviour make acceptable the identical use as carriers of the other polyaminoacids. 
     These other conjugates fall therefore within the scope of the invention, as well as the employment of such polyamino acids as carriers for preparing hepatotropic conjugates with antiviral compounds the administration of which would be otherwise seriously compromised by unfavourable side phenomena induced by a high toxicity for organs other than liver. 
     
                                           TABLE 2__________________________________________________________________________Characteristics of high molecular weight poly-L-lysine conjugates.                               % ε-NH.sub.2 groups             Lactose (μg)                      Drug (μg)                               substituted byCompound          Compound (mg)                      Compound (mg)                               Lactose                                    Drug                                        dpm/μg__________________________________________________________________________9 LAC-poly-L-lysine-ara-AMP             385      330      48   43  010 LAC- .sup.3 H!poly-L-lysine-ara-AMP             352      312      44   41  291011 LAC- .sup.3 H!poly-L-lysine-RIBVMP             396      299      46   39  250412 LAC-poly-L-lysine- .sup.14 C!AZTMP             371      219      45   26  46613 LAC-poly-L-lysine-ara-AMP             210      440      31   64  0__________________________________________________________________________ 
    
     
                       TABLE 3______________________________________Schedules of administration of Lac-poly(L-Lys)-ara-AMP to miceand rats for the microscopic study of liver cells.   Daily        Route of Days ofAnimal  dose (μg/g)                injection                         administration______________________________________Mice    6            i.m.     20   30           i.v.     1   60           i.v.     1Rats    6            i.m.     7   30           i.m.     7   60           i.v      1______________________________________ 
    
     Animals were killed 24 h after the last injection. Liver samples were fixed and semithin sections were stained as described in (Fiume, L., Betts, M. C., Busi, C., Corzani, S., Derenzini, M., Di Stefano, G., Mattioli, A., J. Hepatol 1992; 15: 314-322).