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Title:
PRESSURE SENSITIVE SWITCH
Document Type and Number:
WIPO Patent Application WO/2002/001586
Kind Code:
A1
Abstract:
The invention relates to a pressure-sensitive switch, comprising: an edge structure extending in a substantially closed contour; a first carrier which is connected on its edges to the edge structure and which is electrically conductive on its side connected to the edge structure; a second carrier which is connected on its edges to the edge structure and which extends substantially parallel to the first carrier and its electrically conductive on its side connected to the structure; and connecting means for connecting the external connections to the first and the second carrier, wherein the distance between the carriers in their neutral position is substantially the same over the whole surface. Owing to this uniform spacing between the carriers the switch is identical over its whole active surface, so that no local aberrations such as dimples have to be made. The switch can hereby be miniaturized more easily. This uniformity also ensures that the sensitivity of the switch extends over its whole surface. In order to also enable construction of the switch with a comparatively large surface area relative to the thickness, the carriers are preferably manufactured from foil, and spacers are placed between the carriers inside the edge structure, which spacers are fixed to each of carriers.

Inventors:
DEN RIDDER FRANK PETRUS (NL)
ECKHARDT HANS JOHANNES (NL)
Application Number:
PCT/NL2001/000497
Publication Date:
January 03, 2002
Filing Date:
July 02, 2001
Export Citation:
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Assignee:
VITELEC B V (NL)
TENSOR B V (NL)
SMARTSENSE B V (NL)
DEN RIDDER FRANK PETRUS (NL)
ECKHARDT HANS JOHANNES (NL)
International Classes:
H01H3/14; H01H13/52; H01H35/00; (IPC1-7): H01H3/14
Foreign References:
US5399819A1995-03-21
US5895900A1999-04-20
EP0669229A21995-08-30
FR2148063A11973-03-11
US5818002A1998-10-06
Attorney, Agent or Firm:
Jorritsma, Ruurd (Nederlandsch Octrooibureau Scheveningsweg 82 P.O. Box 29720 LS The Hague, NL)
Download PDF:
Claims:
WHAT IS CLAIMED IS:
1. A compound of the formula G F[(CL)2LAP]q (I) wherein: GF is a tissue growth promoting factor or combinations thereof; CL is an acid cleavable linker which is covalently bonded to GF; z is O, 1 or 2; q is from 1 to the sum of the amino groups present on the native GF; L is a linking moiety; and AP is a polyaminomethylenephosphonic acid ligand.
2. The compound of Claim 1 wherein GF is plateletderived growth factors, insulinlike growth factors, fibroblast growth factors, epidermal growth factors, transforming growth factors, nerve growth factors or cartilage/bone inductive factors or combinations thereof.
3. The compound of Claim 2 wherein GF is plateletderived growth factors, insulinlike growth factors, fibroblast growth factors, transforming growth factors, or cartilage/bone inductive factors or combinations thereof.
4. The compound of Claim 2 wherein GF is the combination of either platelet derived growth factor and insulinlike growth factorl or plateletderived growth factor and insulinlike growth factorll.
5. The compound of Claim 1 wherein AP is a ligand that is a straight or branchedchain moiety, cyclic moiety, polymer, or aryl moiety, which ligand contains at least two nitrogen atoms.
6. The compound of Claim 5 wherein the polymer is a dense star polymer.
7. The compound of Claim 6 wherein the dense star polymer is a dendrimer or dendron.
8. The compound of Claim 5 wherein the ligand contains three or more nitrogen atoms.
9. The compound of Claim 5 wherein AP is of the formula ( I I ) wherein: each R1 independently is hydrogen, ClC4 alkyl, phenyl, hydroxy C.C. alkyl, CH,COOH, CH2P03H2 or an L moiety; with the proviso that only one of R1 may be an L moiety and one L moiety must be present and with the proviso that at least onehalf of the total R1's are CH2P03H2; each R2 and R3 independently is hydrogen or CιC4 alkyl or L moiety; with the proviso that only one L moiety is present in Formula II; n is 2, 3 or 4; n' is 2, 3 or 4; and m is 0 to 10.
10. The compound of Claim 5 wherein AP is of the formula ( I I I ) wherein: R1, R2, R3, n and m are defined as in Claim 9.
11. The compound of Claim 5 wherein AP is a straight or branchedchain moiety.
12. The compound of Claim 1 1 wherein the straight or branchedchain moiety is (Npropylcarboxyl)ethylenediamineN,N',N'trimethylenephosphonic acid; [N(4aminophenyl)ethyl]ethylenediamineN,N\N'tri methylenephosphonic acid; 1(carboxyl)ethylenediamineN,N,N',N'tetramethylenephosphonic acid; [1(4aminobenzyl)]ethylenediamineN,N,N',N'tetramethylenephosphonic acid; N(4aminophenyl)N, Nbis[propyl(i mi nodi methylenephosphonic acid)]; N[(4ami nophenyl)ethyl]N,Nbis[ethyl(imi nodi methylenephosphonic acid)]; or N[1(4aminobenzyl)N,N'ethylenediamineN',N"ethylenediamineN,N,N',N" pentamethylenephosphonic acid.
13. The compound of Claim 5 wherein AP is a cyclic moiety. 14.. The compound of Claim 13 wherein the cyclic moiety is 1 ,4,7, 1 Otetraazacyclododecane; 1 , 5,8,12tetraazacyclotetradecane; 2[(4aminobenzyl)1 , 4,7,10tetraazacyclododecane] 1 ,4,7, 10tetramethylene phosphonic acid; 1 [(αcarboxyl)4amino2methoxybenzyl]1 , 4,7, 10tetraazacyclododecane 4,7, 10trimethylenephosphonic acid; or 1 [(αphosphonyl)(4aminophenyl)ethyl]1 , 4,7,10tetraazacyclododecane4,7, 10 trimethyienephosphonic acid.
14. The compound of Claim 5 wherein AP is a aryl moiety.
15. The compound of Claim 15 wherein the aryl moiety is an aromatic ring system having a total number of atoms in the backbone of the aryl ring is from 3 to 30.
16. The compound of Claim 16 wherein the aromatic ring system has one or more additional cyclic or aromatic rings present, or is substituted by straight or branchedchain moieties.
17. The compound of Claim 16 wherein the aromatic ring system is 3,6,9, 15tetraazabicyclo[9.3.1 ]pentadeca1 (15), 1 1 , 13triene3, 6, 9tri methylene¬ phosphonic acid; 6(αcarboxyl4aminobenzyl)3, 6,9, 15tetraazabicyclo[9.3.1 ]pentadeca 1 (15), 1 1 ,13triene3,9dimethylenephosphonic acid; 13(4aminobenzyl)3,6,9, 15tetraazabicyclo[9.3.1 ]pentadeca 1 (15), 1 1 , 13triene 3,6,9trimethylenephosphonic acid; or 6[(αphosphonyl4aminophenyl)ethyl]3, 6,9, 15tetraazabicyclo[9.3.1 ]peritadeca 1 (15), 1 1 ,13triene3,9di methylenephosphonic acid.
18. The compound of Claim 1 wherein L is of the formula Re ( V) wherein: G is hydrogen, NH or R~ is an electrophilic group capable of being attached to protein; R and R6 are independently hydrogen or COOH; with the proviso that when G is hydrogen, then one of R5 or R6 is COOH; R7 is hydrogen, hydroxy or C.C4 aikoxy; and y is 0, 1 , 2, 3 or 4; with the proviso that when y is 1 , 2, 3 or 4, then only one of R5 or R6 may be COOH.
19. The compound of Claim 1 wherein the L moiety is covalently bonded to the GF.
20. The compound of Claim 1 wherein z is 1 or 2 and CL is a thiourea, thioether, peptide, ester, disulfide, amide, diester, thioether, hydrocarbon, acetal glycoside or 4 isothiocyanatophthalic anhydride.
21. The compound of Claim 1 wherein the LAP moiety is 1(αcarboxyl2 methoxy 5aminobenzyl)1 , 4,7, 10tetraazacyclododecane4, 7, 10tπ methylenephosphonic acid.
22. The compound of Claim 1 wherein the LAP moiety is 1(4 isothiocyanatobenzyl)diethylenetriaminepentamethylenephosphonic acid.
23. The compound of Claim 23 wherein the GF is plateletderived growth factors, insulinlike growth factors, fibroblast growth factors, transforming growth factors, or cartilage/bone inductive factors or combinations thereof.
24. The compound of Claim 23 wherein the GF is plateletderived growth factors or insulinlike growth factors or combinations thereof.
25. A pharmaceutical formulation vyhich comprises a compound of the formula GF[(CL)LAP]q (I) wherein: GF, CL, L, AP, z and q are as defined in Claim 1 ; and which is in solid or liquid form; and a pharmaceuticallyacceptable carrier or adjuvant.
26. The formulation of Claim 26 which is supplied as a two or more substance in kit form.
27. The formulation of Claim 26 which is supplied as single substance.
28. A method of regenerating bone of a mammal by administering to the mammal in need of such treatment, either by direct application to the area of injured or depleted bone or by indirect application, an effective amount of a composition that includes as the active ingredient a compound of the formula GF[(CL)zLAP]q (I) wherein: GF, CL, L, AP, z and q are as defined in Claim 1.
29. The method of Claim 29 wherein the effective amount is from about 0.005 to 50 mg/kg of body weight of the mammal.
30. The method of Claim 29 wherein more than one compound of Formula I is administered.
31. The method of Claim 29 wherein other active compounds are also administered.
32. The method of Claim 29 wherein further bone loss is prevented or lessened.
Description:
TARGETED DELIVERY OF GROWTH FACTORS FOR BONE REGENERATION This invention relates to specific target delivery systems, namely, delivery of growth promoting factors to bone for its regeneration by a chelant composition system Compositions containing these systems and a process for making them are also part of this invention

Historically, many physical conditions and diseases exist which cause bone loss in mammals, e g , intentional and accidental traumatic injuries, osteoporosis and penodontal diseases Thus it is often desired in the medical and dental fields to provide a composition which will stimulate and enhance bone regeneration in a mammal, e g a human patient One class of proteins which may be useful for regeneration of bone is polypeptide growth factors (GF), which are also described as tissue growth promoting factors Growth factors are polypeptides which stimulate a defined population of target cells As multifunctional molecules, they may stimulate or inhibit cell proliferation as well as affect cell function, depending on the type of the target cells and the presence of other signal peptides Examples of growth factors are platelet-derived growth factors (PDGF's), insulin-like growth factors (IGF's), transforming growth factors (TGF) such as beta's (TGF-β's) and alpha (TGF-α), epidermal growth factor (EGF), fibroblast growth factor (FGF's) including acidic fibroblast growth factor (aFGF) and basic fibroblast growth factor (bFGF), nerve growth factor (NGF), and bone morphogenetic proteins (B P's), including osteogenic and osteoinductive factors Combinations of tissue growth factors may be beneficial for promoting bone regeneration For example the combinations of PDGF and IGF-I or PDGF and IGF-II promote bone regeneration and wound healing [See, for example, Lynch et al , Proc Nat'l Acad Sci (USA) 84, 7696-7700 (1987), Lynch et al , J. Clm Invest 84, 640-646 (1989), Lynch et al , J Clm Pβnodontol 16, 545-588 (1989), Lynch et al , J Penodontol 62, 458-467 (1991), and US Patents 4,861 ,757 and 5,019,559]

PDGF's are polypeptides of about 28-35 kilodaltons (kD) They are found in numerous cell types in the body PDGF derived from human platelets contains two polypeptide sequences, PDGF-A and PDGF-B polypeptides [See H N Antoniades and M Hunkapiller Sc/ence 220, 963-965 (1983)] PDGF-A is encoded by a gene localized in chromosome 7 [C Betsholtz et al , Nature 32Q_, 695-699 (1986)], and PDGF-B is encoded by the s/s oncogene [R Doolittle et al , Science 221, 275- 277 (1983), Waterfield et al , Nature 304, 35-39 (1983)] localized in chromosome 22 [R Dalla-Favera, Science 2J8, 686-688 (1982)]

Because the two polypeptide chains of PDGF are encoded by two different genes localized in separate chromosomes, human PDGF occurs in three forms, a disulfide-lmked heterodimer of PDGF-A and PDGF-B, or two different homodimers (homodimer of PDGF-A and homodimer of PDGF-B) The role of PDGF in bone formation is not clear Some studies have indicated that it promotes bone resorption [Tashjian et al , Endocrinology 1 1 1 , 1 18-124 (1982), Canalis et al J Cell Physiol 140, 530-537 (1989)] Other studies have shown that PDGF

stimulates the proliferation of osteoblasts in vitro and, when given via repeated subpeπosteal injections in newborn rats, new bone formation in vivo [Piche and Graves, Bone VO, 131-138 (1989), Joyce et al , in Clinical and Experimental Approaches to Dermal and Epidermal Repair Normal and Chronic Wounds, pp 391-416 (1991) IGF's, or somatomedins, are polypeptides of about 7 5 kD that have a strong homology to human proinsu n [Humbel, Hormonal Proteins and Peptides _V2, 57-79 (1984)] IGF-I and IGF-II share a 62% sequence homology Their actions are mediated through two distinct receptors The IGF-I receptor is named type-l receptor (IGF-IR), and the IGF-II receptor is named type-ll receptor (IGF-IIR) IGF-I by itself has also been extensively studied for its effects on bone growth In vivo, the continuous local application of IGF-I inside a titanium chamber implanted into the adult rabbit tibia did not significantly alter bone formation [Aspenberg et al , Acta Orthop Scand , 60, 607-10 (1989)] Continuous systemic administration of somatomedic-C (IGF-I) also failed to promote the repair of bone wounds resulting from a femoral osteotomy in rats [Kirkeby and Ekeland, Acta Orthop Scand , 61, 335-38 (1990)] A preliminary study in a small number of animals suggested that continuous infusion of IGF-I into the arterial supply of one hind limb for 14 days resulted in increased cortical bone formation in that limb in older, but not young, rats The action appeared to be the result of an increased number of osteoblasts and decreased number of osteoclasts [Spencer et al , Bone _V2, 21-26 (1991 )] The local application of IGF-I to the growth plate of young hypophysectomized rats resulted in a small but significant effect on unilateral longitudinal bone growth [A M Isgaard et al , J Physiol 250, E367-372 (1986)] IGF-I and PDGF have also been isolated from bone matrix [Hauschka et al , J Biol Chem 261, 665-74 (1986), and Canahs et al , Cal Tiss Intematl 43, 346-51 (1988)]

In vitro, there are apparently conflicting data on the effects of IGF-I on bone cells Pfeilschifter, et al , [Endocrinology 127, 69-75 (1990)1 reported only a modest effect of IGF-I alone on bone matrix apposition in cultured fetal rat calvaπal Significant effects on bone matrix formation were seen when IGF-I was combined with PDGF-BB, TGF-β, or both PDGF-BB and TGF-β In contrast, McCarthy et al , [fndocr.no/oqy 124, 301-7 (1989)] reported that IGF-I and IGF-II stimulate significant DNA and collagen synthesis in bone cultures Hock et al , [Endocrinology 122, 254-60 (1988)] found that IGF-I stimulates primarily pre-osteoblast replication m vitro and that collagen and bone matrix synthesis is stimulated independently of cell replication Canalis et al , [J Cell Physiol 140, 530-537 (1989)] reported that PDGF-BB opposed the stimulatory effect of IGF-I on collagen synthesis, IGF-I prevented the PDGF effect on collagen degradation and that PDGF-BB and IGF-I had additive effects on calvaπal DNA synthesis Piche and Graves [Bone 10, 131-8 (1989)] also reported that m vitro IGF-I did not stimulate significant 3H-thymιdιne incorporation into bone derived cells nor did it enhance the activity of PDGF in this regard IGF-I in combination with PDGF, EGF and TGF-B resulted in uptake by the bone cells nearly equal to that achieved by 10% fetal bovine serum Receptors

for IGF-I and II have been demonstrated in osteoblast-enπched cultures from fetal rat bone [Centrella et al., J Cell Biol. (abstract) 107, 62a (1988)]. The role of IGF-I in bone metabolism has been reviewed recently by Canalis et al., [J. Endocrmol. Invest. 1_2, 577-84 (1989)]

Another class of growth factors which have been studied for their effect on bone growth is FGFs. In vivo, both aFGF and bFGF and their respective mRNA's have been detected at the site of bone fractures [Joyce et al., (1991 ) ibid]. Both aFGF and bFGF have been isolated from bone matrix [Hauschka et al., (1986) ibid]. bFGF and IGF-I have been used in combination to promote the healing of skin wounds [Lynch et al , J. Clm. Invest. (1989) ibid].

In vitro, bFGF did not significantly alter 3H-thymιdine incorporation in bone 0 fracture calluses [Joyce et al., (1991 ) ibid]. bFGF has been reported to enhance mitogenesis in fetal calvarial bone cultures but did not simulate differentiated function of osteoblasts directly [Canalis et al., ;. Clm. Invest. 81, 1572 (1988)]. aFGF has the same reported biological effects on bone as bFGF but generally requires higher concentrations [Canalis, J. Clin. Invest. 79, 52-58 (1987)]. Both aFGF and bFGF tend to decrease matrix synthesis in the fetal rat calvarial model 5 [Canalis et al., (1989) ibid]. Cultured bovine bone cells synthesize both bFGF and aFGF and store them in their extracellular matrix [Globus et al., Endocrinology 124, 1539 (1989)]. bFGF has been reported to enhance the capacity of bone marrow cells to form bone-like nodules in vitro [Noff etaL. f.F.β.S. Letters 250. 619-21 (1989)]. Both aFGF and bFGF increased DNA synthesis in cells cultured from parietal bones while bFGF was a more potent stimulator of alpha 1 Type 1 o procollagen mRNA [McCarthy et al., Endocrinology 125, 21 18-26 (1989)]. They are both mitogenic and chemotactic for cells derived from the peπodontal ligament and bind to pretreated dentin slabs [Terranova et al., / Periodontol. 60, 293-301 (1989); Terra nova et al., J. Periodontol. 58, 247-257 (1987); Terranova, In The Biological Mechanisms of Tooth Extraction and Root Resorption, Davidovitch Z. ed.; pp. 23-34 (1989)]. 5 The TGF-β family of proteins also appear to have potential as modulators of bone growth. In vitro TGF-β is produced by osteoblasts and stimulates proliferation and collagen synthesis by these cells [Robey et al., J. Cell Biol. 105, 457-463 (1987); Rosen et al., Exper. Cell Res. 165, 127-138 (1986); Hock et al., Cal. Tissue Int. 32, 385 (abstract) (1988)]. In vivo injections of TGF-β stimulate chondrogenesis and osteogenesis [Joyce et al., J. Cell Biol. 1 10, 2195-2207 0 (1990); Noda et al., Cndocr/no/oqy 124, 2991-2996 (1989)1

Bone inductive factors, such as bone morphogenetic proteins, osteogenin and osteoinductive protein 1 , can also stimulate bone formation They are often strucurally similiar to TGF-β and are characterized by their ability to induce ectopic cartilage and bone formation when implanted subcutaneously or intramuscularly in mammals (US Patents 4,877,864; 5 4,619,989; 4,455,256; 4,596,574; and 4,563,489; Wozney et al , Sαence 242, 1528-1534 ( 1988)] Targeted Delivery

While growth factors appear to have the ability to modulate bone growth, their efficacy as therapeutic agents is limited by the ability to deliver them to the site of bone deficit

In diseases such as osteoporosis this deficit occurs at various times throughout the entire skeletal system. Thus it would be ideal to target the delivery of the growth factors to skeletal tissue with preference given to the site of the bone deficit. Current methods for delivery of proteins, such as, polymers, bone grafts and liposomes are unsatisfactory because they allow only localized delivery or systemic distribution without targeting.

Various aminophosphonic and aminocarboxylic acid complexes, having a metal complexed to an aminophosphonic or aminocarboxylic acid ligand, are known to deliver agents to bone [US Patents 4,508,704, 4,515,767, 4,560,548, 4,606,907, 4,897,254, 4,898,724, 5,059,412, 5,064,633, and 5,066,478]. Clearly, it would be desirable to deliver preferentially to the bone site the desired growth factor(s) and retain its activity for the intended use. More preferred would be the ability to deliver the desired growth factor(s) preferentially to the site of injured or depleted bone and still retain its intended activity. Most preferred would be the ability to deliver the desired growth factor(s) preferentially to the site of injured or depleted bone and allow for the activation of the bone growth factor(s) on an "as needed" basis as determined by the natural bone homeostasis mechanisms in the body. The present invention has the ability to met the above objectives. Present Invention

The present invention provides compounds for stimulating and enhancing bone growth by administering bone growth promoting factors which have been modified by being associated with a polyaminomethylenephosphonic acid ligand in a way that allows their preferential localization to skeletal tissue. The compounds for this delivery system are represented by the formula

GF-[(CL) 2 -L-AP] q (I)

wherein: GF is a growth promoting factor or combinations thereof;

CL is an acid cleavable linker which is covalently bonded to GF; z is O, 1 or 2; q is from 1 to the sum of the amino groups present on the native GF;

L is a linking moiety; and

AP is a polyaminomethylenephosphonic acid ligand.

Formulations for administering the compounds of Formula I to mammals, and methods forthe use of the compounds of Formula I for targeted delivery to bone, and processes for preparing the compounds of Formula I are also contemplated by this invention.

When the compositions or formulations containing compounds of Formula I are used, sites of injured or depleted bone are treated, and bone regenerated. Natural and recombinant tissue growth factors are commercially available from R&D Systems (Minneapolis,

MN), Collaborative Research, Inc (Bedford, MA), Genzyme, Inc (Cambridge, MA), ICN Biomedicals, INC , (Cleveland, OH), Peprotech, Inc (Rocky Hill, NJ) and UBI (Lake Placid, NY) Bone inductive proteins can be purified from bone [Celeste et al , Proc Natl Acad Sci (USA) 87, 9843-9847 (1990), Wang et al , Proc Natl Acad So (USA) 85, 9484-9488 (1988), US Patents 4,455,256 and 4,619,989]

In the compounds of Formula I, although any of the growth promoting factors (GF) mentioned before may be used, preferably GF is chosen from PDGF's, IGF's, FGF's, TGF's or cartilage/bone inductive factors (BMP's)

PDGF, preferably in combination with IGF-I, has been shown to increase new bone formation when applied either alone or directly to diseased bone (US Patents 4,861 ,757 and 5,019,559 and copendmg US application Serial No 582,332, filed September 13, 1990, H Antoniades and S Lynch) PDGF contains 30 free ammo groups per molecule which can potentially be modified to increase PDGF's affinity for bone PDGF is available from R&D Systems and Genzyme, Inc PDGF has been described in US Patents 4,861 ,757 and 5,019,559 IGF-I has been shown to increase new bone formation when applied, either alone or preferably in combination with PDGF, directly to diseased bone IGF-I contains 4 free ammo groups per molecule which can potentially be modified to increase PDGF's affinity for bone IGF-I is available from R&D Systems and Genzyme, Inc IGF-I is described by R E Humbel, Eur J Biochem 190. 445-462 (1990) IGF-II has been shown to increase new bone formation when applied directly to diseased bone IGF-II contains 2 free ammo groups per molecule which can potentially be modified to increase PDGF's affinity for bone IGF-II is available from R&D Systems and Genzyme, Inc IGF-II is described by R E Humbel, fur 7 Biochem 190, 445-462 (1990) bFGF has been shown to increase new bone formation when applied directly to diseased bone bFGF contains 15 free ammo groups per molecule which can potentially be modified to increase PDGF's affinity for bone bFGF is available from R&D Systems and Genzyme, Inc bFGF is described by Gospodarowicz et al . Endocrmol Rev 8, 95-1 14 (1987) aFGF is a low molecular weight homodimer polypeptide which has been shown to increase new bone formation when applied directly to diseased bone aFGF contains 14 free ammo groups per molecule which can potentially be modified to increase PDGF's affinity for bone aFGF is available from R&D Systems and Genzyme, Inc aFGF is described by Gospodarowicz et al , Endocrmol Rev 8, 95-1 14 (1987)

TGF-β. is a low molecular weight (about 25 kDa, am o acids) homodimer polypeptide which has been shown to increase new bone formation when applied directly to diseased bone TGF-β ι contains 18 free am o groups per molecule which can potentially be modified to increase PDGF's affinity for bone TGF-β ] is available from R&D Systems and Genzyme, Inc TGF-β, is described by Sporn et al , J Cell Biol 105, 1039-1045 (1987)

BMP's have been shown to increase new bone formation when applied within mesenchymal tissues. The BMP's have been reviewed by Celeste et al. [Proc. Natl. Acad. Sci.

(USA) 87, 9843-9847 (1990)] and found to be as follows:

BMP

The polyaminomethylenephosphonic acid ligands (AP of Formula I) are either covalently bonded to the GF of Formula I (z = 0), or have a cleavable linker (L) present (z = 1). The AP ligands may be straight or branched-chain moieties, cyclic moieties, polymers (including dense star polymers, their dendrimers and dendrons), or aryl moieties, which ligands contain at least two, preferably three or more, nitrogen atoms. Preferably, the ligands are polyamino¬ methylenephosphonic acid ligands of one of the formula

( I I )

wherein: each R 1 independently is hydrogen, C.-C 4 alkyl, phenyl, hydroxy C ι -C 4 alkyl, - CH 2 COOH, -CH-PO.H. or an L moiety; with the proviso that only one of R 1 may be an L moiety and one L moiety must be present and with the proviso that at least one-half of the total R 1 's are -CH-PO.H,; each R 2 and R 3 independently is hydrogen, C.-C, alkyl or L moiety; with the proviso that only one L moiety is present in Formula II;

n is independently 2, 3 or 4; n' is independently 2, 3 or 4; and m is 0 to 10; or

(III)

wherein: R 1 , R 2 , R 3 , n and m are defined as before; or

(IV)

wherein: R 1 is defined as before.

The linking moiety (L in Formula I) is represented by the formula

R

(V)

wherein: G is hydrogen, NH 2 or

R 4 is an electrophilic group capable of being attached to protein;

R 5 and R 6 are independently hydrogen or -COOH; with the proviso that when G is hydrogen, then one of R 5 or R 6 is COOH; R 7 is hydrogen, hydroxy or C^C^ alkoxy; and y is O, 1, 2, 3 or 4; with the proviso that when y is 1 , 2, 3 or 4, then only one of R 5 or R 6 may be COOH.

In the present invention the following terms are defined as follows. The term "straight or branched-chain moieties" refers to an alkyl group having from 1 to about 100 carbon atoms which may be either a straight-chain moiety such as, for example, ethyl, propyl, n-butyl, n-dodecane and the like, or a branched-chain moiety such as, for example, isopropyl, tert-butyl, 2,5,7-trimethyldodecyl and the like. Both the straight and branched-chain moieties must contain at least 2 nitrogen atoms, preferably from 3 to 50 nitrogen atoms, and more preferably from 3 to 25. Some examples of these moieties include

PDTMP

APEDTIVIP

CEDTMP

ABEDTMP

APIPTMP

APDTMP

ABDTMP

wherein: 5

PDTMP = (N-propylcarboxyl)ethylenediamine-N,N',N'-trimethylenephosph onic acid;

APEDTMP = [N-(4-aminophenyl)ethyl]ethylenediamine-N,N',N'-trimethylene - phosphonic acid;

CEDTMP = 1 -(carboxyl)ethylenediamine-N,N,N',N'-tetramethylenephosphoni c 0 acid;

ABEDTMP = [1-(4-aminobenzyl)]ethylenediamine-N,N,N',N'-tetramethylene- phosphonic acid;

APIPTMP = N-(4-aminophenyl)-N,N-bis-[propyl(iminodimethylenephosphonic acid)]; 5

APDTMP = N-[(4-aminophenyl)ethyl]-N,N-bis-[ethyl(iminodimethylene- phosphonic acid)]; and

ABDTMP = N-[1-(4-amιnobenzyl)-N,N'-ethylenedιamιπe-N',N"-ethylene dιamιne- N,N,N',N"-pentamethylenephosphonιc acιd, with ABEDTMP and ABDTMP being preferred The compounds are shown in the Examples The term "cyclic moieties" refers to aliphatic, saturated ring systems having at

5 least 2 nitrogen atoms, preferably from 3 to 10, and more preferrably from 3 to 8, and about twice as many carbon atoms present as nitrogen atoms Some examples of these moieties include 1 ,4,7,10-tetraazacyclododecane, 1 ,5,8,12-tetraazacyclotetradecane, 2-[(4-ammo- benzyl)-1 , 4,7, 10-tetraazacyclododecane]-1 , 4,7, 10-tetramethylenephosphonιc acid, 1-[(α-carboxyl)-4-amιno-2-methoxybenzyl]-1 , 4,7,10-tetraazacyclododecane-4,7,10-tπ-

10 methylenephosphonic acid, and 1-[(α-phosphonyl)(4-amιnophenyl)ethyl]-1 , 4,7,10-tetra- azacyclododecane-4,7,10-tπmethylenephosphonιc acιd

The term "aryl moieties" refers to an aromatic ring system which may have one or more additional cyclic or aromatic rings or substitution by straight or branched-chain moieties The total number of atoms in the backbone of the aryl ring is from 3 to 30, preferably from 6 to

15 16, and more preferably from 8 to 16 The aryl moiety contains at least 2 nitrogen atoms, preferably from 3 to 10, and more preferrably from 3 to 8 Some examples of these moieties include pyrazolyl, 3-methylpyrazolyl, 5-methylpyrazolyl, imidazolyl, 4-methylιmιdazolyl, 5- methylimidazolyl, 1 ,4-dιmethyiιmιdazolyl . 1 ,5-dιmethylιmιdazolyl, pyπdazinyl, pyπmidinyl, 2,4,6-tπmethyipyrιmιdιnyl, pyrazinyl, puπnyl, pterdmyi, 3,6,9, 15-tetraazabιcyclo[9 3 1 ]penta- 0 deca-1 (15),1 1 ,13-tπene-3,6,9-trιmethylenephosphonιc acιd (PCTMP), 6-(α-carboxyl-4-amιno- benzyl)-3,6,9,15-tetraazabιcyclo[9 3 1]pentadeca-1 (15),1 1 ,13-trιene-3,9-dιmethylenephos- phonic acid (PCAPCDMP), 13-(4-amιnobenzyl)-3,6,9,15-tetraazabιcyclo[9 3 1 ]pentadeca- 1 (15),1 1 ,13-trιene-3,6,9-trιmethylenephosphonιc acιd (PCABTMP), and 6-[(α-phosphonyl-4- amιnophenyl)ethyl]-3,6,9,15-tetraazabιcyclo[9 3 1]pentadeca-1 (15),1 1 ,13-trιene-3,9- 5 dimethylenephosphonic acid (PCAPCTMP) PCTMP, PCAPCDMP and PCAPCTMP, with PCTMP and PCAPCTMP preferred, and are taught in Kiefer et al 's copendmg US Patent Application Serial No 805,551 , filed December 10, 1991 (assigned by unrecorded assignment to The Dow Chemical Company), the disclosure of which is hereby incorporated by reference Other hetro atoms such as oxygen may be present 0 The term "polymers, including dense star polymers" are defined as described in

European Appln 0 271 180, published June 15, 1988, the disclosure of which is hereby incorporated by reference These "dense star polymers" are also referred to as STARBURST™ polymers (a Trademark of Michigan Molecular Institute, Midland, Ml) or STARBU RST™ dendrimers and described in the same European publication Preferred STARBU RST™ 5 dendrimers have polyammoimme groups where the surface has the ammo groups converted to aminomethyienephosphonic acid groups ana with at least one 4-amιnopheny! moiety on the surface These STARBURST™ dendrimers are prepared as described in European Appln 0 271 180, published June 15, 1988, the disclosure of which is hereby incorporated by reference

The "polymers" also include arborols (G R Newkome, V Org Chem. 50, 2004-2006 (1985), and either linear or branched polymer containing amines (V P Torchilin et al , Byull Eksp Biol Med. 102, 63-65 (1986)

Also included within the definition of the AP term of Formula I is

5 H 2 N-(CH 2 ) n -C(P0 3 H) 2 OH where n is from 1-3

Such compounds are described in US Patents 5,039,819, 5,019,651 , 4,922,007, 4,621 ,077, 4, 134,969, 4, 1 17,086, 4, 108,962, and 3,962,432

The term "cleavable linker" (CL of Formula I) means that the linkage between the

10 polyaminomethylenephosphonic acid (AP of Formula I) [having a bifunctional chelantmg agent (BFCA) on the linking moiety (L of Formula I)] and the protein of the GF is reversible or cleavable under certain physiological conditions. Such linkages are taught in the art and include linkages contamg thiourea, thioether, peptide, ester, and difulfide groups [C F Meares et al., Int'l. J. Cancer, Supp 2, 99-102 (1988) and references contained therein, US Patent

15 5,045,312] Also taught in the art are linkages between molecules and proteins which contain an amidine linkage. These linkages are prepared by reacting a molecule containing an imidoester with the amine groups of the protein [O. R. Zaborsky, Immobilized Enzymes in Food and Microbial Processes, p187-202, A C. Olson and C C. Cooney, eds , Plenum, New York (1974)] Similarly taught in the art are amide, diester, thioether, hydrocarbon, and disulfide

20 linkages [C H Paik et al., J. Nucl Med. 30, 1693-1701 (1989) and M K Haseman, Eur J Nucl Med. 12, 455-460 (1986)]. Cleavable diphosphonate and amidated diphosphonate linkers are taught in US Patent 5,094,848 These linkers are cleaved in situ by enzymes such as phosphodiesterase, 5'-nucleotιdase, and acid phosphatase Cleavable linkages are also taught in US Patent 5,094,849 in the form of an alkylidene hydπzide bond These linkages are formed

25 by reacting a carbonyl containing molecule with a molecule containing a hydrazide moiety Additionally, acetal glycosides have been proposed as selectively cleavable linkages [L F Tietze, Nachr. Chem., Tech. Lab. 36, 728-737 (1988)] Linkers that are acid cleavable may be particularly advantageous. Especially preferred are acid cleavable linkers wherein their rate of cleavage is at least ten-fold greater at pH 5 compared to their rate at pH 7; both rates are determined at

30 37°C. Some examples of acid cleavable linkers are disclosed in US Patents 4,542,225 and

4,618,492 and the references mentioned therein and our copending application US Serial No 026,800, filed March 4, 1993, which is hereby incorporated by reference In this latter paendmg application, the preferred acid cleavable linker is 4-ιsothιocyanatophthalιc anhydride

The term "group present to permit coupling to a protein" or "electrophilic

35 group(s) capaole of being attached to proteιn(s)" refers to an electrophilic group (R 4 of the L term of Formula I) that can bind to an ammo acid of a protein, e g the GF Some examples known to those skilled in the art of suitable groups include, but are not limited to, am o, maleimido, diazo, isothiocyanato, vinylpyπdo, bromoacetamido, carboxyl, and N-hydroxy-

succinimido active ester. When these electrophilic groups are present, the ligand (L-AP of Formula I, prior to attachment) is a BFCA.

The "polyaminomethylenephosphonic acid moieties" (AP of Formula I) are represented by a wide variety of possible groups, such as the cyclic moieties, straight or branched-chain moieties, aryl moieties, polymers including dense star poiymers, as defined above, which have at least one portion of the moiety containing between two nitrogen atoms a methylene (-CH 2 -) π group where n is 2, 3 or 4 (polyaminomethylene group). More than one such polyaminomethylene group may exist in the moiety. The moiety also contains at least two methylenephosphonic acid group (-CH 2 -P0 3 H 2 ) covalently attached to the polyamino- methylene group via a nitrogen. The polyaminomethylenephosphonic acid moieties are preferably represented by Formula II, III or IV but not limited thereto. The polyaminomethyl¬ enephosphonic acid moieties preferably have a group present to permit coupling to a protein or electrophilic group(s) capable of being attached to protein(s) as described herein. The polyaminomethylenephosphonic acid moieties (represented by L-AP in Formula I) may be linked to the protein (GF in Formula I) by a cleavable linker (represented by CL in Formula I), preferably an acid cleavable linker, as described herein.

The terms "growth factor" and "tissue growth promoting factor" mean any molecule which stimulates the proliferation, differentation, metabolism or migration of mammalian cells. The factors can be derived from natural sources or made by recombinant DMA technology or chemical synthesis. Preferably the factors are purified.

The term "purified" as used herein refers to factors which, priorto mixing with the other growth factors, are 90% or greater, by weight, of the specified protein (i.e., is substantially free of other proteins, lipids, and carbohydrates with which it is naturally associated). A purified protein preparation will generally yield a single major band on a polyacrylamide gel for each subunit. Most preferably, the purified factor used in the compositions of the invention is pure as judged by amino-terminal amino acid sequence analysis.

The ligands of this invention (AP of Formula I) may be in the form of their pharmaceutically acceptable salts. The term "ligand" as used herein is understood to include these salts. The term "pharmaceutically acceptable salt" means a cation acceptable for pharmaceutical use. These are cations that are not substantially toxic at the dosage administered to achieve the desired effect. Illustratively, these salts include those of alkali metals, such as sodium and potassium; alkaline earth metals, such as calcium and magnesium; ammonium; light metals of Group IIIA including aluminum; and organic primary, secondary and tertiary amines, such as trialkylamines, including triethylamine, procaine, dibenzylamine, N,N'-dibenzylethylenediamine, dihydroabiethylamine, N-(C 1 -C 4 )alkyipiperidine, and any other suitable amine. Sodium and potassium salts are preferred. The term "pharmaceutically *' acceptable" means suitable for administration to warmblooded animals, e.g. mammals,

especially human beings, and includes being nontoxic, e.g. suitable for pharmaceutical use and is not poisonous to the warm-blooded animal. The pharmaceutically acceptable salts of the compounds of the present invention are prepared by conventional ion exchange processes or by treating the ligand or compound of Formula I with an appropriate base. Preparation of Polyaminomethylenephosphonic Acids

Various processes are known to prepare the polyaminomethylenephosphonic acid moieties of the present invention. A few of these processes are discussed below. A. Preparation from Amines Much literature exists which describes the preparation of polyaminomethylenephosphonic acids, particularly the straight or branched-chain moieties, from amines. For example, US Patent 2,599,807, the disclosure of which is hereby incorporated by reference, teaches the preparation of polyaminomethylenephosphonic acids by heating an aqueous solution of an amine with chloromethylenephosphonic acid in the presence of a base such as sodium carbonate at pH> 10. Other examples are shown by the references given below describing the preparation of ethylenediaminetetramethylenephosphonic acid (EDTMP) from the corresponding ethylenediamine (EDA), using a variety of phosphonomethylating agents as shown in the table below.

PREPARATIONOF EDTMP

EDTA= ethylenediaminetetramet ylenecarboxyl c acid

** _ = the disclosure of which is hereby incorporated by reference

Additional examples involving the preparation of cyclic polyaminomethylene¬ phosphonic acids from the corresponding amines can be found in US Patent 4,937,333, the disclosure of which is hereby incorporated by reference, and D W Swmkels et al , Reel Trav Chim Pavs-BAS 1 10. 124-128 (1991) The preparation of polyaminomethylenephosphonic acids from amines via an intermediate aminomethylenephosphonate ester or mixed aminomethylenephosphonic acid ester is found in WO 91/0791 1 , published June 13, 1991 , the disclosure of which is hereby incorporated by reference This process uses phosphonomethylating agents (e g formaldehyde and dialkyl phosphite) in an aqueous solution which forms the peralkyl phosphonate esters These ester are then hydrolyzed to the ammomethylenephosphonic acids The reference also describes how to make alkyl or aryl substitutions on the carbon between the nitrogen and phosphorous by treatment of the ester with a strong base (e g n-butyl lithium) and alkylating with an alkyl or aryl halide

B Preparation of Polyaminomethylenephosphonic Acids from Carboxyhc Acids Polyaminomethylenecarboxylic acids can be converted into the corresponding polyaminomethylenephosphonic acids by various known processes The general reaction to transform the corresponding carboxy c acid involves a reagent capable of donating a phosphonic acid group For example, the reaction of EDTA with PCI 3 in nitrobenzene to give EDTMP (e g US Patent 3,832,392, the disclosure of which is hereby incorporated by reference) C Preparation of Bifunctional Chelating Agents (BFCAs) having Amine Groups

Capable of Conversion to Polyaminomethylenephosphonic Acids

Simon et al 's (assigned by unrecorded assignment to The Dow Chemical Company) copending US Patent Application Serial No 565,379, filed August 9, 1990, the disclosure of which is hereby incorporated by reference, teaches the process to make various linear or branched linear polyaminomethylenephosphonic acids that are capable of being attached to proteins WO 84/03698, published September 27, 1984, describes open chain polyamme based bifunctional chelating agent intermediates which can be phosphonomethyl- ated to yield BFCAs The synthesis of linear or branched polyalkylene polyphosphonate BFCAs is also described in US Patent 4,808,541 , the disclosure of which is hereby incorporated by reference

US Patents 3,994,966 and 4,622,420 and various references given therein describe how to make various ethylenediamme and diethylenetπamine based BFCAs with different groups for attachment to protein amine groups, all of which can be converted from the amine to a polyaminomethylenephosphonic acid BFC to be attached to the amine group of the protein

Open chain polyaminomethylenephosphonic acid BFCAs containing the linkage through an aminocarboxylic acid can be prepared from the corresponding polyamme intermediate BFCAs as described in European Appln 0 279 307, published August 24, 1988, the

disclosure of which is hereby incorporated by reference. US Patents 4,994,560, 5,006,643 and 5,064,956 also describe how to make various open chain and cyclic amine containing BFCAs which can be phosphonomethylated to yield the corresponding polyaminomethylenephos¬ phonic acid BFCAs. Cyclic polyamine BFCAs are taught in EP Appln. 0 353450, published February 7,

1990, and describes how to prepare many different cyclic amine containing BFCAs which can then be carboxymethylated to yield aminomethylenecarboxylates. The amine containing intermediates of these BFCAs can alternatively be phosphonomethylated to yield the corresponding polyaminomethylenephosphonic acid BFCAs. Similarly, US Patent 4,885,363 describes a variety of 1 ,4,7,10-tetraazacyclododecane based amine containing intermediates which can be converted by phosphonomethylation to the corresponding polyaminomethylene¬ phosphonic acid BFCAs. The cyclic BFCAs based on the 1 , 4,7,10-tetraazacyclododecyltetra- methylenephosphonic acid and the open chain BFCAs based on diethylenetriaminopenta- methylenephosphonic acid are a preferred group of polyaminomethylenephosphonic acid BFCAs ligands.

The attachment group from the polyaminomethylenephosphonic acid BFCAs to the protein may be substituted from the cyclic polyaminomethylenephosphonic acid itself and are exemplified by J. P. L. Cox in 7. Chem. Soc, Chem. Commun. 797 (1989), and M. K. Moi et al, in J. Amer. Chem. Soc. 1_H), 6266-6267 (1988). Similar compounds are shown in WO 89/1 1475, published November 30, 1989.

Cyclic amine compounds based on the 1 ,4,8, 1 1-tetraazacyclotetradecane have been described by M. K. Moi et al, in Inorg. Chem. 26, 3458-3463 (1987). These can be converted to the tetraaminomethylenephosphonic acid counterpart compounds by processes mentioned above. Similar compounds which may be used in the present invention are described in US Patent 4,678,667. Additional examples of cyclic polyamines are described by T. J. McMurry et al. in Bioconjugate Chem. 3(2), 108-1 17 (1992). These intermediate bifunctional cyclic amines can be phosphonomethylated to give the corresponding polyaminomethylene¬ phosphonic acid BFCA (the L-AP portion of Formula I).

Bicyclopolyazamacrocylocarboxylic acid BFCA intermediates are disclosed in Kiefer et al.'s (assigned by unrecorded assignment to The Dow Chemical Company) copending US Patent Application Serial No. 805,270, filed December 10, 1991 , the disclosure of which is hereby incorporated by reference, can be phosphonomethylated to give the polyaminomethyl¬ enephosphonic acid BFCAs.

Bicydopolyazamacrocylophosphonic acid BFCAs are disclosed in Kiefer et al.'s (assigned by unrecorded assignment to The Dow Chemical Company) copending US Patent Application Serial No. 805,551 , filed December 10, 1991 , the disclosure of which is hereby incorporated by reference, teaches the process to make various bicy opolyazamacrocylophos- phonic acid BFCAs having polyaminomethylenephosphonic acid BFCAs.

D. Preparation of Bifunctional Chelating Agents (BFCAs) having their Nitro Groups Reduced to Amine Groups

When the reduction of a nitro group, especially a nitrophenyl group, to the corresponding amino group is desired, particularly for compounds described in Paragraph C above, this reduction is readily accomplished by methods known in the art. For example, the processes listed in Survey of Organic Syntheses 1 , 41 1-417 (1970), pub. John Wiley & Sons, and references contained therein.

E. Preparation of Bifunctional Chelating Agents (BFCAs) having their Amino Groups Converted to Electrophilic Groups The BFCAs of the ligands of the present invention (e.g. L of Formula I) have a group present to permit coupling to a protein or electrophilic groups capable of being attached to a protein. The process to convert the amino group to electrophilic groups capable of being attached to a protein is well known in the art. Some references that provide suitable process are: C. F. Meares et al., Ace. Chem. Res. V7, 202-209 (1984) and references given therein; D. Parker, Chem. Soc. Rev. 19, 271-291 (1990) and references given therein; C. F. Meares et al., J. of Protein Chem. 2, 215-228 (1984) and references given therein; C. F. Meares "Protein Tailoring Food Med. Uses", Amer. Chem. Soc. Symp., 339-352 (1985), ed. R. E. Feeney and J. R. Whitaker, pub. Dekker, NY, NY. Examples of BFCAs have been given before. Additionally, many reagents are available for forming an amide bond in aqueous solution which brings together an amine containing molecule with a carboxylate containing molecule. For example, commercially available water soluble carbodiimides have been developed for this purpose [J. V. Staros, Anal. Biochem. 156, 220-222 (1986)].

Another method for linking two nucleophiles together is to convert one, such as an amine into a Michael acceptor, by reaction with acryloyl chloride orthe chemical equivalent. This converts the amino group to the acrylamide group which can then react with a different nucleophilic amine (Chem. Abst. 83:80295b).

Other methods for preparing drug-carrier conjugations are described by M. J. Poznansky and R. L Juliano in Pharmacol. Rev. 36, 278-336 (1984) and WO 90/14844.

F. Preparation of BFCAs by Other Methods The molecules for attaching two nucleophilic moieties together are termed bifunctional crosslinking agents. If the two reactive ends of the molecule are the same, they are termed "homobifunctional" crosslinking agents. If the two reactive ends of the molecule are different, they are termed "heterobifunctional" crosslinking agents.

T. Kitagawa et al. in Chem. Pharm. Bull. 29, 1 130-1 135 (1981 ) and references given therein disclosed how to make heterobifunctional crosslinking agents for protein modification. Such reagents possess two selectively reactive groups such as a maleimide group (which reacts with thiol moieties) and N-hydroxysuccinimidyl ester (which reacts with amine groups such as lysine). These reagents allow the combination of two molecules together if one molecule

contains amine groups and the other molecule contains thiol group(s) Similar compounds containing a maleimide group has been reported by O Nielsen in Synthesis 819-821 (1991 ).

Other bifuctional cross nkers have been developed for the attachment of BFCAs or other electrophilic molecules to proteins or other nucleophillic substrates (US Patent 4,680,338 and references given therein); dialdehyde crosslinking agents [S. Avameas et al., Scand. J. Immunol. 8, 7-23 (1978)]; and commercially available crosslinking agents are shown in Pierce 1989 Handbook and General Catalog, pp 283-31 1 (Pierce, Rockford, IL).

Proteins and small molecules containing electrophilic groups such as amines (but also including other similar electrophilic groups) can be modified by reaction with commercially available Traut's reagent [I. Wower, Nuc. Acid Res. 9, 4285-4291 (1981 )] to convert ammo groups to sulphydryl groups which can then react selectively with maleimide groups

G. Cleavable Linkers

Sometimes it is advantageous that the linkage between the polyaminomethyl¬ enephosphonic acid BFCAs and the GF be reversible or cleavable under certain physiological conditions. Such linkages are taught in the art and examples have been given above. Particularly advantageous are the linkers that are acid cleavable. Some examples of acid cleavable linkers are disclosed in US Patents 4,542,225 and 4,618,492 and the references mentioned therein. These cleavable linkers possess a cyclic anhydride at one end of the linker which reacts with amine groups, and a maleimido group at the other end of the linker which reacts with sulphydryl groups. The linkage between the anhydride and ammo groups (which forms an amide with a carboxylic acid hereby) is easily cleaved at acidic pH. Also US Patent 4,764,368 describes the use of cyclohexene-1 ,2-dicarboxylιc acid anhydrides as a way to introduce acid cleavable amide functionality between a small molecule and a large molecule WO 90/14844 describes the use of sugar derivatives as cleavable linkers in weakly acidic conditions

H. Presence of Metal Ions

Supπsingly, the addition of metal ions does not significantly inhibit the affinity of polyaminomethylenephosphonic acids for calcific surfaces For example, the addition of calcium or samarium ions does not interfere with the affinity of 1 , 4,7,10-tetraazacyclodo- decanetetramethylenephosphonic acid (DOTMP) for the calcific surface of hydroxyapitite

For example, DOTMP has been shown to go to calcific sites in vivo when complexed with ions of samarium, holmium, gadolinium or yttrium in US Patent 4,976,950. Also ethylenediaminetetramethylenephosphonic acid (EDTMP) when complexed with calcium or other metal ions has also been shown to go to calcific sites in vivo (European Appln. 0462 787, published December 27, 1991)

I Clusters of Aminophosphonic Acids for Attachment to Proteins

Polymers having polyaminomethylenephosphonic acids, including dense star polymers such as described in European Appln. 0 272 180, published June 15, 1988, are

prepared by reacting the amine with formaldehyde and dialkyl phosphite in an aqueous solution which forms the peralkyl phosphonate ester. This ester is then hydrolyzed to the aminomethylenephosphonic acid on the dense star polymer. Particularly, the dense star is in the PAMAM form having amine groups on its surface. These amine groups are then reacted with phosphonomethylating agents to form the polyaminomethylenephosphonic acid, which is then conjugated to the GF. The advantages of the dense star as the bone seeking moiety are that it can be water soluble, have a controlled size, and specific groups and quantity of groups available for conjugation to GF.

The polymers of the L-AP of Formula I also include arborols (G. R. Newkome, J. Org. Chem. 50, 2004-2006 (1985) which are capable of being attached to proteins, e.g. GF. The arborols are monocascade spheres which possess a three-deminsional microenviroment having the outer surface covered with polar functional groups. These arborols can be converted into polyamines by methods known in the art for converting esters and alcohols into amines (e.g. Survey of Organic Synthesis 1 , 41 1-417 (1970), pub. John Wiley and references given therein). The arborol polyamines can be converted into polyaminomethylenephosphonic acids by the methods described above. By starting the arborol cascade polymer with the appropriate group such as p-nitrobenzyl bromide, the arborols can contain a group capable of attaching to proteins. Thus aborols containing polyaminomethylenephosphonic acid groups and a group capable of attaching to a protein by either a stable covalent linkage or cleavable linkage can be prepared.

Also, other polymers, either linear or branched, containing amines and a group capable of attachment to a protein have been described [V. P. Torchilin et al., Byull. Eksp. Biol. Med. 102, 63-65 (1986)]. Such polyamine containing polymers can be converted by methods described above to polymers containing polyaminomethylenephosphonic acid groups. By adjusting the stoichiometries of the protein to reactive group containing cluster of polyaminomethylenephosphonic acid, the type of product can be altered. Also, by adjusting the stoichiometry during the step that introduces the linkage containing the reactive group, a cluster compound can be linked to two molecules of protein which may be identical to each other or different molecules of protein. J. Alternate Processess

Selective attachment of the polyaminomethylenephosphonic acid BFCAs to noncritical amine groups on a GF may be accomplished by first mixing the GF with a soluble or solid support immobilized form of the receptor from cells which will form a GF-receptor aggregate. This aggregate can then be reacted with an excess of the reactive form of the poly- aminomethylenephosphonic acid BFCA. Since the GF is bound to the receptor, only amine groups not involved in the GF receptor interaction will be modified. The GF modified in this fashion is then able to interact with its receptor v vo to yield biological activity. The aggregate between the modified GF and the receptor can then be broken down into the now

selectively modified GF and the reusable receptor, which after separation will yield fully active modified GF that still recognizes the receptor.

The compounds of Formula I can be prepared in several different ways. For example, the AP portion can be reacted with L to form the L-AP portion; the L-AP portion then attached to the CL; with the CL-L-AP group then attached to the GF. Alternatively, GF is reacted with CL to form the GF-CL portion; which GF-CL is then reacted with L-AP to form compounds of Formula I. The degree of modification of the GF is described by the q term of Formula I, which is arrived at experimentially by adjusting the concentrations, time, temperature, pH, and stoichiometry of the reactions between GF, CL and the L-AP molecules. Formulations

The formulations of the present invention are in the solid or liquid form. These formulations may be supplied as a single substance for direct use or as two or more substances (e.g. in kit form) such that the two components are mixed at the appropriate time prior to use. Whether premixed or as a kit, the formulations may require a pharmaceutical ly-acceptable carrier or adjuvant.

The compounds of this invention may also be administered parenterally, that is, subcutaneously, intravenously, intramuscularly, or interperitoneally, as injectable dosages of the compound in a physiologically acceptable diluent with a pharmaceutical carrier which can be a sterile liquid or mixture of liquids such as water, saline, aqueous dextrose and related sugar solutions, an alcohol such as ethanol, isopropanol, or hexadecyl alcohol, glycols such as propylene glycol or polyethylene glycol, glycerol ketals such as 2, 2-di methyl- 1 ,3-dioxolane-4- methanol, ethers such as poly(ethyleneglycol) 400, an oil, a fatty acid, a fatty acid ester or glyceride, or an acetylated fatty acid glyceride with or without the addition of a pharmaceutically acceptable surfactant such as a soap or a detergent, suspending agent such as pectin, carbomers, methylcellulose, hydroxypropylmethylcellulose, or carboxymethylcellulose, or emulsifying agent and other pharmaceutical adjuvants- Illustrative of oils which can be used in the parenteral formulations of this invention are those of petroleum, animal, vegetable, or synthetic origin, for example, peanut oil, soybean oil, sesame oil, cottonseed oil, corn oil, olive oil, petrolatum, and mineral oil. Suitable fatty acids include oleic acid, stearic acid, and isostearic acid. Suitable fatty acid esters are, for example, ethyl oleate and isopropyl myristate. Suitable soaps include fatty alkali metal, ammonium, and triethanolamine salts and suitable detergents include cationic detergents, for example, dimethyl dialkyl ammonium halides, alkyl pyridinium halides, and alkylamines acetates; anionic detergents, for example, alkyl, aryl, and olefin sulfonates, alkyl, olefin, ether, and monoglyceride sulfates, and sulfosuccinates; nonionic detergents, for example, fatty amine oxides, fatty acid alkanolamides, and polyoxyethylenepoly-propylene copolymers; and amphoteric detergents, for example, alkyl-beta-aminopropionates, and 2-alkyl-imidazol ' ine

quarternary ammonium salts, as well as mixtures. The parenteral compositions of this invention will typically contain from about 0.001 % to about 10% by weight of compound of Formula I in solution. Preservatives and buffers may also be used advan-tageously. In order to minimize or eliminate irritation at the site of injection, such compositions may contain a non- ionic surfactant having a hydrophile-lipophile balance (H LB) of from about 12 to about 17. The surfactant can be a single component having the above HLB or can be a mixture of two or more components having the desired HLB. Illustrative of surfactants used in parenteral formulations are the class of polyethylene sorbitan fatty acid esters, for example, sorbitaπ monooleate.

Other possible formulations for the compounds of Formula I include: orally, using known oral pharmaceutical formulations some of which may contain magnesium hydroxide in excessive amounts [P. J.Neuvonen et al., fur. J. Clin. Pharmacol. 35, 495-501 (1988)]; trans- dermal delivery using known procedures from B. Kari, Diabetes 35, 217 (1986), B. R. Meyer et al., C/ n. Pharmacol. Ther. 44, 607 (1988); implants using adsorption of the compound onto activated carbon particles which are then implanted or injected [A. Hagiware, Gan to Kagaku Ryoho V5, 1038-1042 (1988) or Chem. Abst. 109: 156158n (1988)]; and nasal delivery, either alone or in combination with permeation inhancers [W. A. Lee, BioPharm. 22-25 (Nov/Dec, 1990) or Wall Street J. B1 , (August 16, 1989)]; and others by R. Langer. Sc/. 249, 1527-1533 (Sept. 28, 1990). The formulations may also be applied locally to the site of the injured or depleted bone by direct topical application to that site. The latter method may require surgery to expose the site of injured or depleted bone.

Bone regeneration using the compounds of the present invention is more effective than that achieved in the absence of treatment (i.e. without applying exogenous agents) or by treatment with similar levels of unmodified growth promoting factors, i.e. only GF of Formula I. Because of the relatively high cost of GF production and the potential ability of GF to cause adverse toxic affects when delivered in high doses systemically, it is also desireable to use the ligand to ensure delivery to the desired site and reduce the overall dose of GF and its toxic effects to the mammal.

In the method of regenerating bone of a mammal, especially a human patient, according to the invention there is administered to the mammal either by direct application to the area of injured or depleted bone or by indirect application, for example, via systemic circulation (such as following parenteral, intramuscular or subcutaneous injection) an effective amount of a composition that includes a compound of Formula I.

The amount of (CL).-L-AP of Formula I which is needed to aid in bone delivery of the GF can be any effective amount. The amount of compound of Formula I to be administered in order to treat any of the diseases desired for such a delivery system can vary widely according to the particular dosage unit employed, the period of treatment, the age and sex of the patient treated, the nature and extent of the disorder treated, and other factors well-known to * those

practicing the medical arts. Moreover the compounds of Formula I can be used in conjunction with other agents known to be useful in the treatment of bone diseases.

The effective amount of compounds of Formula I to be administered according to the present invention will generally range from about 0.005 to 50 mg/kg of body weight of the patient and can be administered as frequently as one or more times per day. The compounds of Formula I can be administered in a pharmaceutically acceptable formulation as described above. The compounds of Formula I can have one or more different active compounds administered either simultaneously or sequentially; and such compounds may be administered with other known active agents for regenerating bone. The invention will be further clarified by a consideration of the foil owing examples, which are intended to be purely exemplary of the present invention. Definitions

The terms used in the present examples and not defined previously herein are as follows: BMP = bone morphogenetic proteins

BSA = bolvine serum albumin

FCS = fetal calf sera

HPLC = high pressure liquid chromatography

HSA = human serum albumin PBS = phosphate buffered saline

RP-HPLC = reverse phase HPLC

SCN-BDTMP = 4-isothιocyanatobenzyldiethylenetrιamιnopentamethyienepho s- phonic acid

All solvents and reagents were obtained from commercial suppliers and used without further purification, except as defined below

All water was passed through a Barnstead NANOpure™ ion exchange/carbon bed water purification system and had a resistivity of about 18.5 megaohms

Acetic acid was glacial acetic acid from Aldπch Chemical Co. at greater than

99 99% 1 % HSA in 1.0 mL aliquots in PBS (20mM phosphate, pH 7.4, 0.15M NaCI) were received frozen from the Institute of Molecular Biology, Inc. (1MB) 5 I-PDGF was obtained from 1MB (frozen in 135 μL alιquots, containing 100 μg of nonradioactive IGF and 26.5 μCi of carrier free 1 5 I-PDGF), as well as unlabelled purified recombinant PDGF-BB and IGF-I, all in 0.1 M acetic acid Centricon™ membrane filters of 10,000 and 3,000 molecular weight cutoff

(Amicon Division of W R Grace and Co.) were used for washing and concentrating the aqueous protein solutions

Growth Factor Modification General Methods

Purified recombmant human PDGF-BB and recombmant human IGF-I and their respective radioiodmated forms were supplied by the Institute of Molecular Biology, Inc The identities of both PDGF-β and IGF-I were established by ammo acid composition and amine terminal ammo acid sequence Ammo acid composition was determined by gas phase hydrolysis of the protein foil owed by RPHPLC essentially according to the method of Eveleigh and Winter [J W Eveleigh and G D Winter, "Ammo Acid Composition Determination" Protein Sequence Determination, pp 91-95 (1970)] The amine terminal ammo acid sequence was obtained by the Edman degradation followed by formulation and analysis of the PTH ammo acid by HPLC essentially according to the method of Hunkapiller and Hood [M W Hunkapiller and L E Hood, Methods in Enzymology _____]_, 486-489, (1983)] Purities were determined using scanning densitometry of Coomassie blue and silver stained SDS PAGE gels and RP-HPLC STARTING MATERIALS Example A

Preparation of PDGF-BB and IGF-I

Both PDGF-BB and IGF-I were produced by standard recombmant DNA techniques and purified by conventional chromatography Both process are well known to those ski 11 in the art (PDGF- US Patents 4,061 , 757 and 5,045,633, IGF-I Y Sato et al , ./ Biochem 101 , 1247- 1252 (1987) and Wong et al , Gene 68, 193-203 (1988)

Analysis of the amine terminal ammo acid residues 1 through 20 of the PDGF-BB (provided by 1MB) gave a single, intact amine terminus and was identical to those residues predicted by the cDNA sequence

Sequence analysis of the amine terminal residues 1 through 53 of the human IGF-I (produced by 1MB) yielded a single intact amine terminus identical to those residues predicted by the cDNA sequence The ammo acid compositions were found to be consistent with that predicted by the integrated human IGF-I gene Both growth factors were greater than 95% pure Example B Biological Activity of PDGF-BB and IGF-I

Potency or bioactivity of each factor was measured by cell culture mttogenic assay in which the effective dose at half-maximal stimulation (ED50) is defined as one unit Both bioassays are based on the measurement of the incorporation of [ 3 H]-Thymιdιne into DNA of BALB/c 3T3 mouse fιbroblasts The 3T3 cells are seeded, in DMEM supplemented with 10% FCS, into 96 well assay plates at 2500 cells per well Assay plates are incubated (37°C) for seven days prior to use This allows for the depletion of serum components and induces quiescence in the cells In the PDGF-BB bioassay standards and test samples are added in triplicate on the afternoon of the seventh day and are allowed to incubate overnight for 18 hours The cells are

then exposed to 1.0 μCi of 3 H-thymιdιne for 6 hours, which is incorporated according to the biological activity of the PDGF.

In the bioassay for IGF-I, the cells are preincubated with PDGF-BB, prior to the addition of test samples and standards. The premcubation enables the cells to respond to IGF-I when the IGF-I is added in the presence of Epidermal Growth Factor (EGF). After an overnight incubation period the cells are exposed to 1.0 μCi of 3 H-thymidιne which is incorporated according to the biological activity of IGF-I.

In both the PDGF-BB and IGF-I assays, following extensive washing, the cells are lysed and the samples are quantitated on a liquid scintillation counter. The resulting data are plotted to generate a dose response curve from which unit activity determinations can be made.

A unit is defined that concentration of GF which induces 50% of the maximum cellular response in the appropriate assay (ED50 value). Maximum response in the PDGF asnd IGF-I assays is defined as the cellular response to a 5% Fetal Calf Sera (FCS) standard. The specific activity was calculated by dividing the number of units based on the mitogenic assay by the mass as determined by amino acid analysis. The potency for both PDGF-BB and IGF-I prior to protein modification was 1 to 3 ng/mL (see Figure 3 for PDGF-BB; Figure 4 for IGF-I). Typically, the specific activities were in the range of 3 to 10 x 10 5 units per mg of protein. Example C Radiolabelled 1 2 5|-PDGF

The "cold" PDGF described in Example A was labelled by the [ 12 5|]-Bolton Hunter method which principally labels the primary amines of accessible iysine and N-terminal residues. 125 I-PDGF is also commercially available from NEN. NEN normally supplies the 125 l- PDGF in a sodium citrate buffered salt solution containing 1 % BSA as a carrier protein Prior to use this BSA must be removed from the commercially available ,25 I-PDGF to allow efficient modification of the PDGF In order to produce the carrier free form of 1 5|-PDGF, antibody affinity chromatography was used. The immobilized anti-PDGF antibody (supplied by 1MB) exhibits specific binding to the AB and BB PDGF isoforms, and no binding to the AA homodimer 42.6 μCi 12 5|-PDGF m a neutral pH buffer was applied to a 200 μL anti-PDGF column The BSA was exhaustively flushed from the column with PBS and the 1 5|-PDGF eluted in 0 1 M acetic acid. Based on a specific activity of 35 μCι/μg this particular lot of 125 I-PDGF is estimated to have, on average, one [ 1 5|] attached for every 1.8 PDGF dimers. Example D Radiolabelled 125|-|GF The "cold " IGF described above was labelled with [ 125 l] using the lactoperoxidase or chloramme T method which lodmatestyrosine residues forming lodotyrosyl products 125 l- IGF-I is commercially available from NEN 1 2 5|-IGF-I was supplied carrier free and freeze dried

from 100 uL of 100mM sodium citrate, pH 4 5 Based on a specific activity of 208 μCι/μg, this lot of 125 I-IGF-I is estimated to have on average, one [ 125 l] attached for every 1 4 IGF-I protein chains Example E Preparation of two PDGF solutions

A vial containing radioactive PDGF was placed in the well of a Capmtec dose calibrator which was adjusted for 1 $ | A vial containing 50 μg of PDGF was rinsed with 200 μL of 0 1 M acetic acid and added to a vial containing 100 μg of cold IGF and 1 5|-PDGF in 135 μL of 0 1 M acetic acid The cold PDGF was vial was rinsed with 7 more 200 μL portions of 0 1 M acetic acid, which rinses were combined to provide one sample containing radioactive and nonradioactive PDGF and nonradioactive IGF The combined sample vial was shaken to mix and two 750 μL aliquots of the solution were removed Each aliquot was placed on a separate membrane of a centncon 10, labelled 1 and 2 Appropriate volume and gamma readings were taken which verified the volume and radioactivity before and after dividing of the sample The two aliquot samples were spun in a centrifuge and placed in new tared filtrate cups

Each membrane filter (1 and 2) was then treated with 1 0 mL of 3 0M sodium bicarbonate buffer and recentπfuged The two cups were removed and replaced with new tared filtrate cups Both membrane retained samples read 10 5 μCi The two membrane filters were then treated with an additional 1 0 mL of 3 0M sodium bicarbonate buffer and recentπfuged Both filtrate cups were removed and replaced with new tared filtrate cups Each of the two samples read 10 5 μCi on the membrane The washing procedure described above was done to remove the carrier nonradioactive IGF which should come through the membrane The remaining material on the membrane was then ready for conjugation Example F Preparation of H-N-BD03TMP

The free base, 1-(α-carboxyl-2-methoxy-5-nιtrobenzyl)-1 ,4,7,10- tetraazacyclododecane, 513 g (1 3 mmol) was added to a stirred slurry of 776 mg (4 7 mmol) of tπethyl phosphite and 141 mg (4 7 mmol) of paraformaldehyde The resulting slurry was heated with stirring to 95°C for 2 hours, cooled to room temperature and concentrated in vacuo to give a viscous oil The oil was chromatographed using a basic alumina column and eluted with chloroform and, after evaporation of the sol vent, to yield (55%), as a light yellow viscous oil, of the ester, 1 -(α-carboxyl-2-methoxy-5-nιtrobenzyl)-1 , 4,7, 10-tetraazacyclo- dodecane-4,7,10-trιmethylenephosphonιc acιd hexaethyl ester

The ester, 250 mg (0 3 mmol) was hydrolyzed by stirring with 3 mL of concentrated HCI at 100°C for 18 hours The aqueous solution was freeze-dπed to give (80%), as a cream colored solid, 1-(α-carboxyl-2-methoxy-5-nιtrobenzyl)-1 ,4,7, 10-tetraazacyclodo- decane-4,7, 10-trιmethylenephosphonιc acιd (O N-BD03TMP)

A 100 mg portion of 0 2 N-BD03TMP was dissolved in 20 mL of water. After purging the system with nitrogen, 120 mg of 10% Pd/C was added and the suspension placed under an atmosphere of hydrogen with constant vigerous stirring. After 3 hours the catalyst was removed via filtration and the filtrate lyphilized to give 89.1 mg of H 2 N-BD03TMP as a chocolate colored solid. A 23. mM solution of this ligand was prepared by dissolving 89.1 mg of H 2 N-BD03TMP in 4.26 mL of water. Example G Preparation of SCN-BDTMP

(1.) A 100 mL three necked, flask was loaded with 2.0 g (5.76 mmol) of 1-(4- 0 nitrobenzyl)diethylenetriamine trihydrochloride [prepared by the procedure described by M. W. Brechbiel et al. in Inorg. Chem. 25, 2772-2781 (1986)]. A separate solution of 10.93 g (0.108 mol) of concentrated HCI and 6.91 g (0.086 mol) of phosphorous acid was prepared and added to the reaction flask. The flask was fited with a therometer, reflux condenser and a stir bar. With constant stirring the reaction solution was brought to reflux. An addition funnel was 5 loaded with 12.0 g (0.144 mol) of 37% by wt formaldehyde solution, attached to the reaction flask, and dripped into the heated mixture at a rate of about 1 mL/min. The reaction was held at reflux for an additional 16 hours, then reduced in volume under vacuum to produce an amber semisolid. The solid was taken up in about 2 mL of water and added dropwise with vigorous stirring to about 800 mL of methanol. The resulting white percipitate was removed by o filtration and dried at 5°Cto yield, as an off white crude solid, 2.32 g (57%) of 1-(4- nitrobenzyOdiethylenetriaminepentamethylenephosphonic acid (0 2 N-BDTMP).

(2.) A 500 mg portion of crude 1-(4-nitrobenzyl)diethylenetriaminepenta- methylenephosphonic acid was purified on a 1.5 cm Q-Sepharose (Pharmacia) anion exchange column eluting with 0 to 1 M ammonium acetate gredient. The desired product, 1-(4-nitro- 5 benzyl)diethylenetriaminepentamethylenephosphonic acid, is the most retained peak at UV 280 nm. Collection of the last eluting peak resulted in about 43 mL of solution containing purified product. The volume was reduced to about 26 mL and treated with 200 mg of 10% Pd/C. The suspension was put under a balloon of hydrogen gas as stirred vigerously for about 2.5 hours. HPLC (anion exchange, eluting with O to 1 M ammonium acetate over 30 minute 0 gradent a 2 mL/min) indicated a slight shift to a shorter retention time for the reduced product. The suspension was then filtered, and the filtrate lyophilized to give 259 mg of white glassy solid. HPLC indicated a purity of about 92% . The product was further purified by preparative anion exchange chromatrography as described above to give, as a white solid, 144 mg of the ammonium salt of 1 -(4-aminobenzyl)diethyienetriaminepentamethylenephosphonic acid, with 5 a purity by anion exchange HPLC of >95% . The product was further characterized by as follows.

Decoupled P-31 NMR showed 3 singlets in the expected 221 ratio

1 H NMR(D 2 0)

5259-367 (m, 17H),413 (b 2H), 691 (d,2H),721 (d, 2H)

5 13 CNMR(D^O)

5520,526,533,534,541,549,558,571,571,583,583,652,1205,131 1,1335,1468

(3a ) AO 09M solution of the ammonium salt of 1-(4-amιnobenzyl)dιethylenetrι- ammepentamethylenephosphonicacid in water was prepared by dissolving 146 mg of the phosphonicacid in 1913 mL of water A328μL portion of this solution (containing about 25

10 mgof the phosphonicacid) was placed ma 10 mL vial containing 1 mL of water and 1 mLof chloroform To the emulsion that formed was added 100 μLof thiophosgene with vigerous stirring for about 1 hour The chloroform layer was removed and the aqueous portion extracted with water using four 1 mL portions of chloroform The washed aqueous solution of the product was frozen ma dry ice/acetone bath and lyophi I ized togive 265 mg of puffy white

15 powder A05mg portion was dissolved in 200μL of water A 6 μL portion of this solution was diluted with 38 mLof water and the UV spectrum obtained showing absorption maxima at 270 and 283 nm confirming the product, 1-(4-ιsothιocyanatobenzyl)dιethylenetrιamιnepenta- methylenephosphonic acid (SCN-BDTMP)

(3b ) A 43 mg (51 μM) portion of 1-(4-amιnobenzyl)dιethylenetrιammepenta-

20 methylenephosphonic acid was dissolved in 2 mLof water and mixed with 1 mLof chloroform To the stirred solution was added 150 μLof thiophosgene in one portion After vigerous stirring for 25 hours the chloroform layer was removed and the aqueous portion extracted with water using three 3 mL portions of chloroform The washed aqueous solution of the product was frozen in a dry ice/acetone bath and lyophi zed to give 454mg of puffy white

25 powder A 24mg portion was dissolved in 960 μLof water A 6 μL portion of this solution was diluted with 38 mL of water and the UV spectrum obtained showing peaks at 272 and 282 nm confirming the product, 1-(4-ιsothιocyanatobenzyl)dιethylenetπamιnepentamethyle ne- phosphomcacid

(3c ) Preparation of 347mMand 347mM solutions of SCN-BDTMP

30 A 100 mg portion (1389 x 10' mol) of SCN-BDTMP was dissolved in 400 μLof 03M sodium bicarbonate buffer The resulting solution had a pH of 751 which was adjusted to a pH of 948 by the addition of 5 μLof 50% (wt) sodium hydroxide The final solution was 347mM of SCN-BDTMP

A 5 μL portion of the above prepared 347mM SCNBDTMP solution was added to

35 45μLofO 1M sodium bicarbonate and mixed thoroughly The final solution was 347mM of SCN-BDTMP

Example H

Preparation of four IGF Solutions

Vials of 100 μL of lyophi zed radiolabelled 1 5 I-IGF-I (from NEN) or lyophilized recombmant IGF-I (from 1MB) were each reconstituted with 100 μL of water to give solutions of 1 mg/mL of IGF containing 0 5M of sodium chloride in 20mM of Tris-hydrochloπc acid with 0 25% BSA as a carrier protein The recombmant IGF vial's contents were dissolved in 10mM of acetic acid and transferred into the glass serum vial containing lodmated IGF dissolved in 535 mg of 10mM acetic acid This combined solution of IGF containing tracer 125 I-IGF-I was dialysed (Spectra/Por7™ membrane from Spectrum Medical Industries) against three 1 L portions of

10 10mM acetic acid The contents of the dialysis bag were then divided into 4 equal volumes and placed onto the membranes of 4 separate Centricon™ microconcentrator membrane filters (3000 molecular weight cutoff) The Centπcons"" were then spun to concentrate the solutions and the contents of the membrane washed with one 1 6 mL of 0 3M sodium bicarbonate buffer at pH = 9 48 This method gave 4 Centncon '" membrane units containing the amounts of IGF

15 shown below

IGF

20

* approximate

25

Example I

Preparation of two IGF solutions

Frozen radiolabelled 125 l-lGF as a 150 μL aliqout containing 300 μg of IGF-I and 23 6 μCι of carrier free 125 I-IGF in 0 1M acetic acid was allowed to thaw and then diluted to a final volume of about 1 5 mL using 0 1 M acetic acid A 700 μL aliqout of this solution was

30 placed on each of 2 Centricon™ microconcentrator membrane filters (3000 molecular weight cuttoff) The Centπcons™ were then spun to concentrate the solutions and the contents of the membrane washed with two consecutive 1 mL portions of 0 3M sodium bicarbonate buffer at pH = 9 48 The calculated amount of IGF (with tracer 1 5 I-IGF) in membrane no 1 was 130 μg (1 7 x 10-8 mol) and in membrane no 2 was 127 μg 5

Example J

Preparation of 1 ,3-propanedιamιne-N-(carboxy-propyl)-N,N',N'-trιmethylene -phosphonιc acid

(PDTMP)

The structure of the compound PDTMP is shown by the following formula.

HOOC — (

2 3

Commercial grade 3-amιnopropyl-2-pyrrolιdιnone (5 0 g) was added slowly to a solution of phosphorous acid (9 7 g) in 6M hydrochloric acid (50 mL) The yellow solution was heated to reflux and treated dropwise with formalin (9 23 mL of 37% solution) over at two hour period After refluxmg an additional 18 hours, the solution was cooled and the solvent removed to give a viscous oil Dripping the oil into 200 mL of methanol gave 5 15 g of PDTMP after filtering and drying This compound showed the expected two singlets in the decoupled 3, P-NMR spectrum at 8 2 ppm and 7 5 ppm (relative to H 3 P0 4 ) in a 2: 1 ratio

This compound may be used as a ligand AP in Formula I where the L is through the COOH group. Example K

Preparation of Ethylenedιamιne-N-(4-ammo-phenethyl)-N,N',N'-trιmethylene phosphonιc Acid (APEDTMP)

The structure of the compound APEDTMP is shown in the following formula:

H 2 N

Three 250 mL Erlenmeyer flasks were loaded with 120 mL of ethylenediamme (EDA) and equipped with a stirring oar and placed on a stirrer Three 10 g samples of p- nitrophenethylbromide were weigned and added slowly to the stirring flasks containing EDA over a thirty minute period Following tne addition of p-nitrophenethyl bromide the flasks were allowed to stir overnight (sixteen hours) at room temperature Tne contents of the flasks

were transferred to a 500 mL round bottomed flask and attached to a simple distillation apparatus The excess EDA was distilled from the desired product at a temperature of 28 to 32°C under vacuum Following the removal of most of the starting EDA the viscous oil was dissolved in water and extracted three times with 75 mL of methylene chloride (CH 2 CI 2 ) The CH_.CI 2 layers were combined and concentrated in a rotoevaporator to yield 29 34 grams of a viscous dark oily liquid

All of this sample was added to a 500 mL round bottomed flask along with 100 mL of 1 5M HCI The aqueous layer was treated with activated carbon heated to 90°C, then filtered through a paper filter The aqueous layer was stripped under vaccum and dried in a vacuum 0 dessicator overnight

The resulting dry solid was washed with cold methanol and filtered to give 15 60 g of N-(p-nιtro-phenethyl)ethylenedιamιne as the hydrochloπde salt An additional 6 77 g of product was obtained by evaporating the filtrate and washing with methanol to give a combined yield of 72% 5 A 250 mL three-necked, round bottomed flask was loaded with 20 0 g (0 063 moles) of N-(p-nιtro-phenethyl)ethylenedιamιne trihydrochlonde salt To this flask was added 9 O g of deionized water and 22 79 g (0 219 moles) of concentrated hydrochloric acid in a solution with 17 16 g (0 209 moles) of phosphorous acid

The flask was attached to a reflux condenser, equipped with a stir bar, and set on o a stirrer A 10 mL syringe was filled with 17 74 g (0 219 moles) of 37% formaldehyde solution and attached to a syringe pump pre-calibrated to deliver at a flow rate of 0 1 mL/min The reaction solution was brought up to reflux temperature, then with constant stirring, the formaldehyde was slowly added to the flask over a three hour period

Following the addition of the formaldehyde solution, the reaction was allowed to 5 reflux and stir for an additional three hours The reaction was allowed to cool and the water was removed under vaccum to give a viscous, dark solid This was slowly added to methanol resulting in a light brown solid This precipitate was filtered and dried to give 20 g (65% yield) of N-(p-nιtrophenethyl)-ethylenedιamιne-N,N',N'-trιmethylen e phosphonic acid A 10 g sample of this tri phosphonic acid was dissolved in 20 mL of water and neutralized with 2 mL of 0 concentrated ammonium hydroxide This crude ammonium salt was then purified using reverse phase preparative HPLC eluting with water A sample of N-(p- nιtrophenethyl)ethylenedιamιne-N,N',N'-trιmethylene phosphonic acid (710 mg, 1 21 μmoles) purified in this manner was dissolved in 50 mL of water and placed in a hydrogenation bottle with a 235 mL volume capacity A blanket of nitrogen was gently blown into the bottle to 5 displace the air Approximately 50 mg of 10% Pd on carbon was added as a catalyst and any catalyst on the vessel sides was rinsed down with water Once all the catalyst was under water, the nitrogen padded bottle was placed on a Parr hydrogenation shaker apparatus After removal of the nitrogen by means of a vacuum line, an atmosphere of hydrogen was

introduced This flushing was repeated to ensure that all oxygen had been removed The final charge of hydrogen gave a pressure of 35 psi The hydrogenation was started by shaking the bottle and continued until the hydrogen uptake ceased (2 5 hours) This pressure drop and the known volume of hydrogen can be used to calculate the moles of hydrogen used which in this case was 99 2% of theoretical The reaction mixture was then carefully vacuum filtered (after removal from the depressuπzed hydrogenation apparatus) through a glass frit and the catalyst thus separated was washed with four 25 mL portions of water The combined aqueous filtrate was then frozen and lyophilized overnight to yield 580 mg (86% yield) of N-(4-amιnophenyl)- ethylethylenedιamιne-N,N',N'-trιmethylenephosphonιc acid as the ammonium salt (APEDTMP) The decoupled 31 P-NMR Spectrum of this compound showed a singlet at 8 0 ppm

(relative to H 3 P0 4 ) and a singlet at 16 9 ppm in the expected ratio of 1 2, respectively

This compound may be used as a ligand AP in Formula I where the L is through the NH 2 group Example L Preparation of 1 -(Carboxy)ethylenedιamιnetetramethylenephosphonιc Acιd (CEDTMP) The structure of the compound CEDTMP is shown below

2 3

To a solution of phosphorous acid (12 9 g) in 6M hydrochloric acid (50 mL) was added 5 0 g of 2,3-dιamιnoproprιonιc acid dihydrochloπde (Aldπch Chemical Co , Milwaukee, Wl) The solution was heated to reflux and treated dropwise with formalin (37% formaldehyde in water, 12 3 mL) over a period of 45 minutes After an additional eighteen hours of reflux, the solvent was removed and the oil dissolved in methanol (20 mL) This solution was then added with stirring to absolute ethanol (200 mL) to yield a fine precipitate This solid was then filtered and dried, yielding 7 37 g of CEDTMP An aliquot of this solution was diluted ten-fold and analyzed by high performance liquid chromatography (HPLC) HPLC was performed on a Dionex'" 201 Oi Ion Supression Chromatography System (Sunnyvale, CA) using an AS-7 anion exchange column (8mm x 25cm) and eluting with 0 03M nitric acid at a flow rate of 0 6 mL/min with ultraviolet detection monitored at 330 nanometers This compound had a retention time of 10 1 1 minutes

This compound may be used as a ligand AP in Formula I where the L is through the COOH group Example M

Preparation of 1-(4-amιnobenzyl)ethlene-dιamιnetetramethylenephosphonιc acιd (ABEDTMP) The structure of the compound ABEDTMP is shown in the formula

To a 50 mL round bottomed flask was added 0 6 g (0 2256 moles) of 1-(4- n nιtrobenzyl)ethylenedιamιne, concentrated HCI (1 24 g, 0 01 18 mole) and then phosphorous acid (0 0925 g, 01 13 mole) The solution was brought to reflux and then treated with 0 956 g (0 01 18 mole) of 30% formaldehyde dropwise over a ninety minute period The reaction was then kept at reflux overnight, cooled to room temperature and then added dropwise to 100 mL of cold methanol The resulting precipitate was filtered and dried to yield 1 -(4-nιtrobenzyl)- ethylenediammetetramethylenephosphonic acid, which was dissolved in 60 mL of water in a 5 hydrogenation flask A 50 mg sample of 5% Pd on carbon was added and the flask connected to a Parr hydrogenation apparatus and shaken until hydrogen uptake ceased The solution was then filtered to remove the catalyst and the resulting clear filtrate was frozen and freeze-dried to yield 1 28 gm (86%) of 1-(4-amιnobenzyl)-ethylenedιamιnetetramethylenephosphonι c acιd This compound gave the expected decoupled 3 , P-NMR spectrum 0

This compound may be used as a ligand AP in Formula I where the L is through the NH 2 group Example N Preparation of N 4 -(p-amιnophenyl)-norspermιdιne

[Bιs(cyanoethyl)](p-arrιnophenyl)amιne was prepared as described in US Patent 5 2,809,985 A 9 O g (42 mmol) sample of the bisnitnle was dissolved in 90 mL of ethanol and 10 mL of 50% NaOH and treated with 6 g of Raney nickel (w-2 grade) and placed under an atmosphere of hydrogen with shaking Shaking was continued until the hydrogen uptake

ceased at which time the catalyst was removed by filtration The filtrate was reduced in volume under vacuum to a viscous oil, dissolved in 40 mL of 50% NaOH, and extracted with three 75 mL portions of chloroform The combined chloroform layers were dried over sodium sulfate, decanted and rotoevaporated under vacuum to yield 7 2 gm (77% yield) of the title compound The product was characterized by proton NMR

This compound may be used as a ligand AP in Formula I where the L is through the NH 2 group Example 0 Preparation of N"(4-amιnophenyl)-dιpropylenetrιamιne-N',N',N'",N'"- tetramethylenephosphonic Acid (APIPMP)

The structure of the compound APIPMP is shown by the formula

N 4 -(p-amιnophenyl)norspermιdιne, prepared in Example N (3 65 g, 16 4 μmoles) was added to 25 mL of water and treated with a solution of 6 2 g (75 6 mMoles) phosphorous acid in 13 mL (163 mMoles) of concentrated HCL The resulting dark blue solution was heated to 100°C and treated dropwise with 5 9 g (73 mMoles) of 37 weight percent formaldehyde in water over a 2 75 hour period The solution was kept at reflux for an additional 15 hours, then cooled to room temperature and dripped into ethyl alcohol The resulting brown precipitate was vacuum filtered and dried under vacuum to give 3 84 g (40% yield) of the title compound (APIPMP) as a brown solid The product thus obtained gave a retention time of 5 50 minutes (minor peak) and 10 50 (major peak) when analyzed on the anion exchange HPLC system described in Example L

This compound may be used as a ligand AP in Formula I where the L is through the NH 2 group

Example P

Preparation of N"-(4-amι nophenethyl)-dιethylenetπamιne-N',N',N'",N'"-tetra- methylenephosphonic acid, tetrasodium salt (APDTMP)

The structure of the compound APDTMP is shown by the formula

Diethylenetπamiπe (20 g, 0.045 mole) was dissolved in 200 mL of toluene and treated over five minutes with a solution of p-nitrophenethyl bromide (10 g, 0.89 mole) in 150 mL of toluene. Afterthree hours of stirring the supernatent was decanted from the gummy solid and extracted three times with 100 mL portions of water. The combined water layers were reduced under vacuum to a low volume and back extracted with 100 mL chloroform. The chloroform was then evaporated under vacuum to yield 9.32 g (83%) of N"-(p-nιtrophenethyl)- diethylenetriamine.

A 5 g sample of this amine was then dissolved in 3N HCI to yield a pH less than 2. The resulting solution was poured into excess methanol. The resulting precipitate was filtered and dried under vacuum to yield 3 g of the corresponding hydrochloπde salt. A 1 3 g ( 004 mole) portion of this salt was dissolved in 20 mL of water and treated with phosphorous acid (1.5 g, 0.018 mole) and concentrated hydrochloric acid (2.0 g; 0 019 moles). The solution was brought to reflux and 37% formaldehyde (1 5 g, 0.019 mole) was added in a dropwise fashion After two additional hours of reflux the solution was cooled to room temperature and evaporated under vacuum to give a viscous oil. This oil was added dropwise to 150 mL of methanol with vigorous stirring. The resulting white precipitate was filtered and dried under vacuum to give 1 65 g (66% yield) of N"-(4-nιtrophenethyl)dιethylenetrιamιne-N',N',N'",N'"- tetra-methylenephosphonic acid In the HPLC method described for Example L this product exhibited a single peak with retention time of 16 9 minutes

A 700 mg (1 1 Moie) sample of this compound was dissolved in 44 mL (4 4 mMole) of 0 1 N NaOH To this solution was added l OO mg of 10% Pd on carbon suspended in 56 mL water and the whole reaction mixture was placed under hydrogen with vigorous

shaking. After hydrogen uptake ceased, the catalyst was filtered and the filtrate evaporated under vacuum to give 0.80 g (100% yield) of N"-(4-aminophenethyl)diethylenetri-amine- N',N',N'", N'"-tetramethylenephosphonic acid tetrasodium salt (APDTMP) as a hygroscopic yellow solid. The title compound exhibited a single peak with a retention time of 5.95 minutes on the HPLC system described for Example L.

This compound may be used as a ligand AP in Formula I where the L is through the NH 2 group. Example Q

Preparation of 4-lsothiocyanatophthalic Anhydride (ACL-3, an acid cleavabie linker)

To a slurry of 4-aminophthalic acid (2.7183 grams(g), 15.00 mmol) and anhydrous potassium carbonate (8.75 g, 63.3 mmol) in 70 mL of tetrahydrofuran (THF) was added thiophosgene (2.30 mL, 30.18 mmol). The reaction mixture was stirred 10 minutes at ambient temperature, then heated to reflux for one hour. After cooling to room temperature, the reaction product solution was filtered through celite and then concentrated to dryness under a stream of dry nitrogen and under an efficient fume hood to avoid exposure to thiophosgene. The crude 4-isothiocyanatophthalic acid was thus recovered; 1 H NMR (300 MHz, acetone-d6) d 10.22 (br s, 2H), 7.81 (br s, 1 H) 7.61 (s,1 H), 7.48 (br s, 1 H); 13C NMR (75 MHz, acetone-d6) d 167.8, 167.7, 138.3, 135.8, 134.4, 131.7, 131.7, 128.6, 126.5.

The 4-isothiocyanatophthalic acid thus obtained was immediately heated to reflux in a mixture of trifluoroacetic anhydride and methylene chloride for 2 hours under a nitrogen atmosphere. After cooling to room temperature, the reaction mixture was concentrated under reduced pressure. Recrystallization of the resultant solid from 30 mL of carbon tetrachloride afforded 4-isothiocyanatophthalic anhydride as brownish-purple crystals in a yield of 2.3778 g, (77 percent of theoretical). The title compound melted at 106-108°C; 1 H NMR (300 MHz, acetone-d6) d 8.15 (d, J = 8.1 Hz, 1 H), 8.06 (d, J = 1 .7 Hz, 1 H), 7.97 (dd, J = 8.1 , 1.7 Hz, 1 H); 13C NMR (75 MHz, acetone-d6) d 163.3, 162.6, 1 39.8, 134.8, 134.6, 130.6, 128.2, 123.5, 1 1 1.6; IR (CHCI 3 ) 2010 (br), 1840, 1740 cm-1 ; MS m/e 205, 161, 133 (base), 74.

FINAL PRODUCTS

Example 1 and Comparative A

Conjugation of PDGF with SCN-BDTMP

A 400 μL portion of 34.7mM SCNBDTMP solution (1.389 x 10 "5 moles) (prepared in Example G) was added to aliquot 1 from Example E. This steoichometry gives a 794: 1 molar ratio of isothiocyanate group per amino group on the protein (Sample 1 ).

A 400 μL portion of the 0.3M sodium bicarbonate buffer was added to aliquot 2 from Example E as a control (Comparative A).

Both samples 1 and 2 were mixed well. The samples, still on the membrane, were allowed to set at room temperature for 14.5 hours. The samples were then centrifuged at full speed to concentrate the samples for one hour. Following centrifugation each sample read 10.0 μCi on the membrane. To each membrane was added 1.0 mL of 0.1 M sodium phosphate buffer. After swirling to mix, the samples were again centrifuged at full speed for 40 min. The filtrate cups were removed and replaced with new tared filtrate cups. Each sample read 9.9 μCi on the membrane.

To each sample was added 740 μL portion of HSA solution to bring the volume on the membrane to 800 μL. Each solution was mixed and transferred into new tared filtrate cups. Each membrane unit was washed with 500 μL of 1 % HSA. The Centricon™ units were then capped, inverted, and centrifuged for about 10 min. at full speed to remove the membrane retentate into the cap. The wash solutions were pipetted into the corresponding filtrate cup. The Centricon™ caps were also washed with 200 μL portion of HSA solution which was then transferred to the filtrate cups. These respective final solutions contained about 18.5 μg (1) and 19.0 μg (Comparative A) in 1.42 mL of HSA and 0.15M sodium chloride. Example 2 Conjugation of one SCN-BDTMP per IGF

A 10 μL (3.47 x 10 "8 mole) portion of 3.47mM SCN-BDTMP solution (prepared in Example G) was added to Centricon™ no. 1 of Example H (containing approximately 41.2 μg of IGF). An additional 390 μL of 0.1 M sodium bicarbonate buffer at pH = 9.35 was added. The solution residing on the Centricon™ membrane was then mixed well and allowed to set for 14 hours at room temperature. The unit was then reverse spun to remove the membrane's contents. A 158 μL aliquot of 0.1 M sodium bicarbonate was added to bring the final volume to about 600 μL.

Example 3

Conjugation of two SCN-BDTMP per IGF A 20 μL (6.94 x 10 '8 mole) portion of 3.47 mM SCN-BDTMP solution (prepared in

Example G) was added to Centricon™ no. 2 of Example H (containing approximately 41.7 μg of IGF). An additional 390 μL of 0.1 M sodium bicarbonate buffer at pH = 9.35 was added. The solution residing on the Centricon™ membrane was then mixed well and allowed to set for 14

hours at room temperature The unit was then reverse spun to remove the membrane's contents A 86 μL aliquot of 0 1M sodium bicarbonate was added to bring the final volume to about 600 μL Example 4 Conjugation of four SCN-BDTMP per IGF

A 400 μL (1 39 x 10 5 mole) portion of 34 7 mM SCN-BDTMP solution (prepared in Example G) was added to Centricon™ no 3 of Example H (containing approximately 45 7 μg of IGF) The solution residing on the Centricon™ membrane was then mixed well and allowed to set for 14 hours at room temperature The unit was then reverse spun to remove the membrane's contents A 208 μL aliquot of 0 1 M sodium bicarbonate was added to bring the final volume to about 600 μL Comparative B Control for Examples 2, 3 and 4

A 400 μL portion of 0 1 M sodium bicarbonate buffer at pH = 9 35 was added to Centricon™ no 4 of Example H (containing approximately 47 7 μg of IGF) An additional 390 μL of 0 1 M sodium bicarbonate buffer at pH = 9 35 was added The solution residing on the Centricon™ membrane was then mixed well and allowed to set for 14 hours at room temperature The unit was then reverse spun to remove the membrane's contents A 23 μL aliquot of 0 1 M sodium bicarbonate was added to bring the final volume to about 600 μL Example 5

Conjugation of four SCN-BDTMP per IGF

A 400 μL (1 39 x 10 5 mole) portion of 34 7mM SCN-BDTMP solution (prepared in Example G) was added to Centricon™ no 1 of Example I (containing approximately 130 μg of IGF) The solution residing on the Centricon™ membrane was then mixed well and allowed to set for 13 hours at room temperature The unit was then centrifuged to concentrate the protein of the solution The residual on the membrane was then washed with 0 5 mL of 0 1 M sodium phosphate buffer (pH = 7 4) by adding buffer and then centπfuging for one hour The residual on the Centncon™ membrane was then removed by adding 572 μL of a 1 percent HSA solution, swirling and pipetting The membrane was washed with an additional 0 5 mL of 1 percent HSA to completely remove the membrane's contents The final volume of combined recovered solution was about 1 5 mL containing an estimated 9 5 μg/100 μL of modified IGF in about 1 percent HSA Comparative C Control for Example 5 A 400 μL portion of 0 3M sodium bicarbonate buffer at pH = 9 48 was added to

Centricon™ no 2 of Example I (containing approximately 127 μg of IGF) The solution residing on the Centricon™ membrane was then mixed well and allowed to set for 13 hours at room temperature The unit was then spun to concentrate the protein of the solution The residual

on the membrane was then washed with 0.5 mL of 0.1 M sodium phosphate buffer (pH = 7 4) by adding buffer and then spinning on a centrifuge for one hour The residual on the Centricon™ membrane was then removed by adding 855 μL of a 1 % HSA solution, swirrlmg and pipetting. The membrane was washed with an additional 0.5 mL of 1 % HSA to completely remve the membrane's contents The final volume of combined recovered solution was about 1 4 mL containing an estimated 9.5 μg/100 μL in about 1 % HSA. Example 6 IGF modified with BDTMP using ACL-3

A 175 uL portion of ACL-3 (12.1 mg ACL-3 in 200 uL of tπfluoroethanol, prepared in Example Q) was added to a Centricon™ containing approximately 100 μg of IGF in about 500 μL of 0.3M bicarbonate buffer (pH = 9.5) The resulting pH was 8.85. After 15 minutes at room temperature, the Centricon™ unit was then centrifuged until the volume had dropped to about 243 μL (243 mg weight) which took about 2 hours To this concentrated solution was added 300 μL of ABDTMP solution (7.1 mg, 10.5 μMoles in 300 μL of bicarbonate buffer at pH = 9.5). The resulting pH was 9.27. This solution was allowed to stand at room temperature for 46 hours. The pH was found to be 9.78 and the volume was about 0 485 μL. This was put on a centrifuge (Clay-Adams) for 6 hours and the volume was reduced to 1 17 μL. A 2 mL aliquot of 0.3M sodium bicarbonate buffer was added and the solution again centrifuged. After 10 hours of centπfuging the volume was about 49 μL. An additional 500 μL of 0.3M sodium bicarbonate was added and the Centricon™ unit centrifuged for 4 hours to give a final volume of 52 μL. A 547 μL portion of 0.1 M sodium phosphate buffer (pH = 7.02) was added and mixed well. The total weight in the Centricon™ unit was 599 mg or about 600 μL in volume. The estimated concentration in this sample is 100 μg IGF per 600 μL of solution (16.7 μg/1 OOμL). Comparative D Control for Example 6

A 175 μL of tn luoroethanol was added to a Centricon containing approximately 100 μg of IGF in about 500 μL of 0.3M bicarbonate buffer (pH = 9.5). The resulting pH was 9.50. After 15 minutes at room temperature, the Centricon™ unit was then centrifuged until the volume had dropped to about 230 μL (230 mg weight) which took about 2 hours. To this concentrated solution was added 300 μL of 0.3M sodium bicarbonate buffer. The resulting pH was 9.46. This was allowed to set at room temperature for 46 hours. The pH was found to be 9 79 and the volume was about 397 μL. This was put on a centrifuge (Clay- Adams) for 6 hours and the volume was reduced to 27 μL. A 2 mL aliquot of 0.3M sodium bicarbonate buffer was added and the solution again centrifuged After 10 hours of centπfuging the volume was about 21 μL. An additional 500 μL of 0.3M sodium bicarbonate was added and the Centricon™ unit centrifuged for 4 hours to give a final volume of 27 μL A 573 μL portion of 0.1 M sodium phosphate buffer (pH = 7.02) was added and mixed well The

total weight in the Centricon™ unit was 603 mg or about 600 μL in volume The estimated IGF concentration in this sample is 100 μg IGF per 600 μL of solution (16 7 μg/100μL)

Example 7

IGF modified with BDTMP using ACL-3 A 210 μL aliquot of IGF solution ( 100 μg of IGF containing tracer amounts of 1 5 | labeled IGF in buffer solution) was put on a membrane of a Centricon™ membrane filtration devices A 500 μL aliquot of 0 3M sodium bicarbonate was added to both Centricon™ unit and it was then centrifuged to less than 50 mg remaining on the membrane The contents on the membrane (washed IGF) was taken up in 500 μL more of 0 3M sodium bicarbonate and was treated with the 19 4 mg of ACL-3 dissolved in 300 μL of warm trifluoroethanol The sample was allowed to stand for 15 minutes then centrifuged for 2 hours Atthe end of thistime a 300 μL volume of ABHDP (357 μMoles) was added to the Centricon™ unit containing the modified IGF and the solution then allowed to stand for about 16 hours The pH remained about 10 during this time The Centricon™ was then centrifuged for about 4 hours to reduce the volume The membrane retained material (modified IGF) was then diluted with 500 μL of sodium bicarbonate buffer and reconcentrated by centnfuging The residual membrane retained volume was 221 mg A 1 279 mL volume of 0 1 M sodium phosphate (pH = 7 02) was added to bring the final volume up to 1 5 total The Centricon™ was then reverse spun to remove the membrane retained material This material was used in biodistπbution studies in rats shown in Example V Comparative E Control for Example 7

The same procedure was followed as m Example 7 except that the addition of warm trifluoroethanol did not contain the ACL-3 linking compound Example 8

PDGF modified with BDTMP using ACL-3

A 100 μL aliquot of PDGF solution was put on the membrane of a Centricon™ membrane filtration device The PDGF solution contained 10 μCi of 125 l labeled PDGF (22 μCi/μg) per 200 μL of 0 1 sodium phosphate, 0 01 M sodium citrate, 0 5M NaCI and 1 % Bovine Serum Albumin at pH = 4 6 A 500 μL aliquot of 0 3M sodium bicarbonate was added to the Centricon™ unit and it was then centrifuged until 50 mg remained on the membrane The contents on the membrane (washed PDGF) were taken up in 500 μL more of 0 3M sodium bicarbonate The membrane retained material was then treated with the 36 7 mg of ACL- 3 dissolved in 300 μL of warm trifluoroethanol, allowed to stand for 15 minutes, and then centrifuged for 2 hours At the end of this time a 300 μL volume of ABH DP (357 μMoles) was added to the Centricon™ unit containing the modified PDGF and the solution then allowed to stand for about 16 hours The pH remained about 10 during this time The Centricon™ was then centrifuged for about 4 hours to reduce the volume The membrane retained material

(modified PDGF) was then diluted with 500 μL of sodium bicarbonate buffer and reconcentrated by centrifuging. The residual membrane retained volume was 329 mg. A 1.171 mL volume of 0.1 M sodium phosphate (pH = 7.02) was added to the membrane of the Centricon™ to bring the final volume up to 1.5 mL total. The Centricon™ was then reverse spun to remove the membrane retained material. This material was used in biodistribution studies in rats as shown in Example VI. Comparative E Control for Example 8

The same procedure was followed as in Example 8 except that the addition of 0 warm trifluoroethanol did not contain the ACL- 3 linking compound. BIOLOGICAL EXAMPLES: BIODISTRIBUTION Example I 125 I-PDGF-(SCN-BDTMP)

Spraque-Dawley rats weighing in the 175-230 g weight range were acclimated for 5 5 days prior to injection. The rats were injected via the tail vein with 50 μL of both samples from Example 1 (Samples 1 and Comparative A) (about 200,000 cpm). After 2, 6 and 18 hours, the rats were sacrificed by cervical dislocation, tissues taken, weighed and the amount of radioactivity in each tissue determined by counting for 5 min. in a scintillation counter equipped with a Nal crystal coupled to a multichannel analyzer. The counts in each tissue were o compared to the counts in 50 μL standards in order to determine the percentage of injected dose in each tissue. The counts in the tail were subtracted from the standards to give the percent injected dose adjusted for the amount found in the tail. Background counts were obtained and subtracted from the tissue counts. The percent dose in bone was estimated by multiplying the percent dose in the femur by 25. The muscle and blood numbers were 5 obtained assuming that muscle is 43% and blood is 6.5% of the rat body weight. These adjustments of the percent dose for the various body parts are accepted values for the rat model. [W.F. Goeckeler et al., J of Nucl. Med. 28(4), 495-504 (1987)]. The results are given in Table I where each data point represents the average of five rats unless noted otherwise.

0

5

Table I

• is Comparative A

15 It is readily apparent that conjugation of SCN-BDTMP with PDGF results in targeting of the PDGF to bone. PDGF conjugated to SCN-BDTMP was 8 times more effective in going to bone than native, unmodified PDGF. In addition, the residence time in the bone was increased by about 30 fold. Example II

20 125 I-IGF-(SCN-BDTMP)

Spraque-Dawley rats weighing in the 175-230 g weight range were acclimated for 5 days prior to injection. The rats were injected via the tail vein with 50 μL of one of the four samples from Examples 2, 3, 4 or Comparative B. After 30 mins. the rats were sacrificed by cervical dislocation, tissues taken, weighed and the amount of radioactivity in each tissue

25 determined by counting for 5 min. in a scintillation counter equipped with a Nal crystal coupled to a multichannel analyzer. The counts in each tissue were compared to the counts in 50 μL standards in order to determine the percentage of injected dose in each tissue. The counts in the tail were subtracted from the standards to give the percent injected dose adjusted for the amount found in the tail. Background counts were obtained and subtracted from the tissue

30 counts. The percent dose in bone was estimated by multiplying the percent dose in the femur by 25. The muscle and blood numbers were obtained assuming that muscle is 43% and blood is 6.5%ι of the rat body weight. The results are given in Table II where each data point represents the average of five rats.

35

Table II

% Injected Dose Ad usted for Amount of Dose Found in Tail

Comparative B

The dergee of modification of the IGF with the number of bone seeking groups added via AP of Formula I was based upon stoichiometry of reactants The results are summarized in Table III where each data point represents the average of five rats Table III

Clearly the results demonstrate that targeted delivery of IGF-I to bone can be achieved by the conjugation of SCN-BDTMP to IGF-I As shown in Table III, the degree of targeting is apparently directly related to the degree of modification Example III ,25 I-IGF-(SCN-BDTMP)

Spraque-Dawley rats weighing in the 175-230 g weight range were acclimated for 5 days pπorto injection The rats were injected via the tail vein with 50 μL of the samples from Examples 5 or C After 2, 6 and 18 hours the rats were sacrificed by cervical dislocation, tissues taken, weighed and the amount of radioactivity in each tissue determined by counting for 5 mm in a scintillation counter equipped with a Nal crystal coupled to a multichannel analyzer The counts in each tissue were compared to the counts in 50 μL standards in order to determine the percentage of injected dose in each tissue The counts in the tail were subtracted from the standards to give the percent injected dose adjusted for the amount found in the tail Background counts were obtained and subtracted from the tissue counts The percent dose in

bone was estimated by multiplying the percent dose in the femur by 25 The muscle and blood numbers were obtained assuming that muscle is 43% and blood is 6 5% of the rat body weight

The results are given in Table IV where each data point represents the average of four rats

Table IV

% Injected Dose Ad usted for Amount of Dose Found in Tail

omparat ve

Example IV

Biological Activity of IGF-I-(SCN-BDTMP)

Various samples from the prior examples were run on an IGF-I mitogenic activity assayto determine their potency The protocol is based on a competence-progression model in which the assay cell line responds to varying levels of IGF-I in a dose dependent manner Cells from a mouse fibroblast line are seeded in 96 well assay plates and grown to confluence to induce quiescence Prior to addition of samples and standards the cells are premcubated with PDGF-BB, which enables them to respond to IGF-I when it is added in the presence of EGF After an overnight incubation period the cells are exposed to 1 0 μCi of 3 H-thymιdιne which is incorporated at varying levels depending on the amount of IGF-I added to the assay well Following extensive washing, the cells are lysed and the samples are quantitated in a scintillation counter equipped with a Nal crystal coupled to a multichannel analyzer The resulting data are plotted to generate a dose response curve from which unit activity determinations can be made

A unit is defined as that concentration of IGF-I which induces 50% of the maximum cellular response in that assay (ED 50 value) Maximum response is defined as cellular response to a 5% FCS standard Maximum response due to exogenous IGF-I is usually 3-5 times baseline Pπorto dilution for the assay, the concentration of IGF-I was determined via an

125 I-IGF-I tracer which had been spiked into the stock sample prior to manipulation Counts were made on a 25 μL aliquot of the stock sample and 25 μL of the two samples The ratio of counts per mm (CPM)/μg of IGF-I in the stock sample was used to determine the concentration

of IGF-I in the two samples for the bioassy. The average of the stock sample aliquots was 5, 135

CPM/μg. The values for each sample was determined by CPM per μL and dividing the number by the stock sample aliquot of 5, 135 CPM/μg. These measurments and calculations resulted in the following values: Example 5 sample was 107.2 μg/mL; and Example C was 1 10.8 μg/mL. The results are shown in Table V.

Table V

** Comparative C

Example V ,25 l-IGF-ACL-3-BDTMP) Doses (150 μL) of the material from Example 7 and Comparative Example E were drawn up into 500 μL syringes equipped with 28 gauge needles and injected into the tail veins of 5 rats. After 6 hours the rats were sacrificed and dissected to obtain the organ distribution of the radiolabelled material. Because of the low amount of radioactivity involved, the samples were counted for 10 minutes. The final number of counts (less background) found in the femurs of rats injected with the modified IGF material of Example 7 were 3.8 times the number of counts (less background) found in the femurs of rats injected with the control material of Comparative E as seen in the following Table VI.

Table VI

Example VI

125 l-PDGF-ACL-3-BDTMP)

Doses (100uL) of this material were drawn up into 500 uL syringes equipped with

28 gauge needles and injected into the tail veins of 5 rats for each of Centricon 1 (Experimental) and Centricon 2 (Control) After 6 hours the rats were Aced and dissected to obtain the organ distribution of the radiolabelled material Because of the low amount of radioactivity involved, the samples were counted for 10 minutes The final number of counts (less background) found in the femurs of rats injected with Centricon 1 (experimental) material were 3 8 times the number of counts (less background) found in the femurs of rats injected with Centricon 2

(control) material as seen in the following Table VII

Table VII

The data thus demonstrates that modification of GF's using techniques described in the present invention results in targeted delivery of biologically active GF's to bone Although the invention has been described with reference to its preferred embodiments, those of ordinary skill in the art may, upon reading and understanding this disclosure, appreciate changes and modifications which may be made which do not depart from the scope and spirit of the invention as described above or claimed hereafter