JPS6313997B2 - - Google Patents

Description

[Detailed description of the invention]

(a) Industrial Application Field The present invention relates to a novel porphyrin compound and its metal complex which has use as a porphyrin derivative, particularly as a cancer-tropic drug. In the present specification, the term "porphyrin derivative" is used in a broad sense and collectively refers to compounds having a basic skeleton represented by the following formula (hereinafter referred to as "porphyrin skeleton"): In the above porphyrin skeleton, the two hydrogen atoms or protons attached to the nitrogen atom of the pyrrole ring are replaced by metal atoms or metal ions, giving metal complexes called metalloporphyrins, but these metal complexes also They are also included in the term "porphyrin derivatives." (B) Prior Art It has been well known that porphyrin derivatives have selective accumulation properties in cancer tissues. However, while porphyrin derivatives exhibit toxicity when exposed to light, their selectivity for cancer tissue is still insufficient, so when they are administered to the human body, patients are unable to eliminate porphyrin derivatives that have collected in normal tissues from the body. It is necessary to remain in a dark place for a long time until it is detected. As a result of various studies to overcome this defect, the present inventors have found that a metal complex of a porphyrin compound obtained by introducing a certain metal into the porphyrin skeleton maintains affinity for cancer. It was discovered that only the phototoxicity was reduced even after the treatment (Japanese Patent Application Laid-open No. 83185/1985). (c) Problems to be Solved by the Invention As mentioned above, the phototoxicity of porphyrin compounds can be reduced by introducing a certain metal into the porphyrin skeleton, but the degree of reduction is not necessarily sufficient. (d) Means to solve the problem After further research in search of other methods that avoid the effects of phototoxicity, we found that by bonding a polyfunctional carboxylic acid to the side chain of a porphyrin compound, the porphyrin compound It has become clear that although the affinity for cancer is maintained, the affinity for healthy tissue is significantly reduced. In other words, derivatives in which a polyfunctional carboxylic acid is attached to the side chain of a porphyrin compound have the property of selectively accumulating in cancer tissues, but are rapidly excreted from normal tissues, and therefore have the property of being phototoxic. There was no longer any need for special consideration. The properties of the above-mentioned porphyrin derivatives do not substantially change even if a metal is introduced into the porphyrin skeleton; on the contrary, even more advantageous results can be obtained since the above-mentioned reduction in phototoxicity may be observed. Although it is not always easy to introduce a metal into the porphyrin skeleton depending on the type of metal, it is possible to introduce a metal into the porphyrin skeleton because it has a chelate-forming group (chelate-forming group) as a polyfunctional carboxylic acid that is bonded to the side chain of the porphyrin compound. When a carboxylic acid is used, the metal is captured by the chelate-forming group, facilitating the formation of a metal complex. Therefore, when a radioactive metal is introduced into a porphyrin compound for the purpose of using it as a radioactive metal-labeled diagnostic agent, it has the advantage that the introduction is easy and the amount introduced per molecule is large. The present invention was completed based on the above findings, and the gist thereof is as follows: (In the formula, R ₁ and R ₂ are −CH=CH ₂ , −
_{CH2CH3 ,} -CH(O-lower alkanoyl) _CH3 , -
CH(OR) _CH3 or -CH(O-lower alkylene-OR)CH3, _R3 is _-H , -COOH, -COO-lower alkyl, -COO-lower alkylene-OR or -COO-lower alkylene-OOC −Z, R ₄ is −
H, -lower alkyl or -lower alkylene-
OR, R is -H, -lower alkyl or a residue obtained by removing hydrogen from a polyfunctional carboxylic acid, Z is the formula ()
The residue obtained by removing _R3 from the compound, A is _-CH2- or -CO-, the dotted line bonded to the γ position indicates no bond or a single bond, and the dotted line between the 7th and 8th positions indicates a single bond or a Indicates the presence of a double bond. ) and its metal complexes (however, the metal can exist within the porphin skeleton or within the polyfunctional carboxylic acid residue, or within the porphin skeleton and within the polyfunctional carboxylic acid residue. At least one of ₁ , R ₂ , R ₃ and R ₄ must be a group with R representing a polyfunctional carboxylic acid residue. Furthermore, R ₃ must be -COO-
In the case of lower alkylene-OOC-Z, R ₁ can be 1-iodoethyl in addition to the above meaning. ). The term "lower alkylene" used in connection with the meanings of the above symbols means alkylene having 5 or less carbon atoms, preferably 1 to 3 carbon atoms (eg, ethylene, trimethylene, propylene). Also,
The term "lower alkyl" refers to alkyl having 8 or fewer carbon atoms, preferably 1 to 3 carbon atoms (e.g. methyl,
ethyl, n-propyl, isopropyl). Furthermore, the term "lower alkanoyl" means an alkanoyl having 8 or less carbon atoms, preferably 3 or less carbon atoms (eg, acetyl, propionyl). The term "polyfunctional carboxylic acid" refers to those having at least one functional group (eg, _-NH2 , -OH, -SH, -COOH) in addition to one carboxyl group. Preferably, those that are physiologically acceptable, such as glycine, cysteine, glutamic acid, alanine, cystine, asparagine,
Amino acids such as valine, methionine, glutamine, leucine, phenylalanine, isoleucine, serine, tryptophan, threonine, aspartic acid may be used. Further, it is more preferable to use physiologically acceptable substances having a chelating functional group, and specific examples thereof include ethylenediaminetetraacetic acid (EDTA), diethylenetriaminepentaacetic acid (DTPA), 1,2-bis(o-
aminophenoxy)ethane-N,N,N',N'-
Tetraacetic acid (BAPTA), 1,3-diaminopropan-2-ol-N,N,N',N'-tetraacetic acid (DPTA-OH), trans-1,2-cyclohexanediamine-N,N,N' , N'-tetraacetic acid (CyDTA), N-hydroxyethylethylenediamine-N,N'-N'-triacetic acid (EDTA-
OH), ethylenediamine-N,N'-diacetic acid (EDDA), iminodiacetic acid (IDA), ethylenediamine-di(o-hydroxyphenylacetic acid)
(EDDHA), etc. In addition,
These may also be used in the form of alkali metal salts. The porphyrin compound represented by formula () includes at least two types of compound groups. That is, one of them is that in formula (), A is -CH ₂ -,
The dotted line bonded to the γ-position indicates no bond, and the dotted line between the 7th and 8th positions indicates the presence of a double bond (porphins), and the others are formula () where A is -CO-, A dotted line bonded to the γ-position indicates the presence of a single bond, and a dotted line at the 7th and 8th positions indicates the presence of a single bond (horbins). When the polyfunctional carboxylic acid residue has a chelate-forming group, the metal complex of the porphyrin compound () includes at least three types of complexes. That is, there are three types: one in which a metal is bonded only to the porphin skeleton, one in which a metal is bonded only to a polyfunctional carboxylic acid residue, and one in which a metal is bonded to both a porphin skeleton and a polyfunctional carboxylic acid residue. The porphyrin compound () and its metal composite of the present invention are new substances, and can be produced by a conventional method. Usually, first, a porphyrin compound corresponding to formula () having R in which at least one of R ₁ , R ₂ , R ₃ and R ₄ is hydrogen is constructed (step (a)), and then this A polyfunctional carboxylic acid residue is introduced into (step (b)), and if necessary, before this introduction step (b) or/
and later by bonding the metal (step (c)). The composition process (a) is based on "Chemistry of Porphyrins" by Naga et al.
(Published by Kyoritsu Shuppan) (1982), "Porphyrins and Metalloporphyrins" by Falk (Published by Elsbier) (1975), "The Porphyrins" by Dolphin (1975), The
Porphyrins)” (published by Academic Press)
This can be done by conventional methods such as those described in (1978). For example, a porphyrin compound corresponding to the formula () in which R is hydrogen is disclosed in JP-A No. 61-7279.
This may be prepared according to the method described in Publication No. 83185. Instead of artificially synthesizing it, it can also be obtained from natural sources such as plants and animals. The porphyrin compound thus constructed is then subjected to the step (b) of introducing a polyfunctional carboxylic acid residue. That is, by reacting a polyfunctional carboxylic acid or a reactive derivative thereof with a porphyrin compound () having R in which at least one of R ₁ , R ₂ , R ₃ and R ₄ is hydrogen, or a reactive derivative thereof, R ₁ ,
A porphyrin compound () having R in which at least one of R ₂ , R ₃ and R ₄ represents a polyfunctional carboxylic acid residue is produced. In this case, the point is to introduce a residue of a polyfunctional carboxylic acid into the side chain of the porphyrin compound (), so the polyfunctional carboxylic acid may be reacted with its carboxyl group,
Other functional groups may also be reacted.
For example, when using an amino acid as a polyfunctional carboxylic acid, it is generally preferable to proceed with the reaction between the carboxyl group present in the side chain of the porphyrin compound () and the amino group of the amino acid. Converting the carboxyl group of a carboxylic acid having a carboxyl group and a chelate-forming group and/or the amino group of the latter into a conventional reactive group, or appropriately protecting the functional groups present in both that are not desirable to participate in the reaction. It may be considered to do so. In addition, when using a carboxylic acid having a chelate-forming group as a polyfunctional carboxylic acid, it is necessary to It is preferable to proceed with the reaction, and for this purpose, conversion of the hydroxyl group and/or carboxyl group to a reactive group and protection of the functional group may be considered as described above. In any case, use of a reaction accelerator or condensing agent such as a dehydrating agent or deoxidizing agent may be considered as appropriate. Regardless of whether before or after the introduction step (b), the metal bonding step (c) is performed as necessary. The metal bond in the porphine skeleton or/and polyfunctional carboxylic acid residue is usually formed by metal halides, sulfates,
Do this using nitrates, etc. Types of metals include Si, Mn, Fe, Co, Ni, Zn, Ga, In,
These include Sn, Sm, Eu, Gd, Tc, Ti, etc. Depending on the type of metal, there may be some differences in the location and difficulty of bonding. The use of radioactive metals is particularly preferred for the diagnosis or treatment of cancer, and specific examples thereof include ⁶⁷ Ga, ¹¹¹ In, ²⁰¹ Tl, ⁹⁹ mTc, and the like. On the other hand, examples of preferable non-radioactive metals include Si, Co, Ni, Zn, Ga, In, and Sn. Hereinafter, the preparation of the porphyrin compound () and its metal composite will be explained in more detail by giving representative examples. For example, polyfunctional carboxylic acid residues in DTPA
(diethylenetriaminepentaacetic acid), first, a metal is bonded to a porphyrin compound or its porphyrin skeleton in which at least one of R ₁ , R ₂ , R ₃ and R ₄ is a group with R representing hydrogen. DTPA is reacted with the metal complex (JP-A-61-7279 or JP-A-61-83185) under heating in pyridine to produce a porphyrin compound () with DTPA residues bonded to the side chain and A metal composite is obtained in which a metal is bound to the porphine skeleton. Specific examples include the following: (1) Ethylene glycol Mono-diethylenetriamine-4-acetic acid-acetate Mono-10b-methylpheophorate (hereinafter referred to as DTPA-10EG)
(2) 2-desethenyl-2-[1-(diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]methylpheophobide (hereinafter referred to as PPB-Me)
DTPA-2EG PPB-Me) (3) Ethylene glycol Mono-diethylenetriamine-tetraacetic acid-acetate Mono-7c-pyropheophorate (hereinafter referred to as DTPA-7EG)
pyroPPB) (4) Ethylene glycol Mono-diethylenetriamine-tetraacetic acid-acetate Mono-7c-pheophorbate (hereinafter referred to as DTPA-7EG PPB) (5) Ethylene glycol Mono-diethylenetriamine-tetraacetic acid-acetate Mono-10b-pheophorbate (hereinafter referred to as DTPA-7EG PPB) (hereinafter referred to as DTPA-10EG PPB) (6) 2-[1-(diethylenetriamine-4acetic acid-
acetyloxyethane)oxyethyl]-4-
[1-(2-hydroxyethyloxy)ethyl]
Methyl deuteroporphyrin (DTPA)
-EGDP-Me) (7) 2-[1-(diethylenetriamine-4acetic acid-
acetyloxyethane)oxyethyl]-4-
[1-(2-hydroxyethyloxy)ethyl]
Deuteroporphyrin (monoDTPA)
(8) 2,4-bis[1-(diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl] deuteroporphyrin (hereinafter referred to as bisDTPA)
-EGDP) (9) 2-[1-(diethylenetriamine-4acetic acid-
acetyloxyethane)oxyethyl]-4-
[1-(2-hydroxyethyloxy)ethyl]
Ga-deuteroporphyrin (hereinafter referred to as
monoDTPA-EGGa-DP) (10) 2,4-bis[1-(diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]Ga-deuteroporphyrin (hereinafter referred to as monoDTPA-EGGa-DP)
bisDTPA−EG Ga−DP) (11) 2-[1-(diethylenetriamine-4-acetic acid-
acetyloxyethane)oxyethyl]-4-
[1-(2-hydroxyethyloxy)ethyl]
In-deuteroporphyrin (hereinafter referred to as
monoDTPA-EG In-DP) (12) 2,4-bis[1-(diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]In-deuteroporphyrin (hereinafter referred to as monoDTPA-EG In-DP)
bisDTPA−EG In−DP), etc. When the porphyrin compounds prepared in this way and the metal complexes in their porphyrin skeletons are reacted with metal chlorides (e.g., InCl ₃ , SmCl ₃ , EuCl ₃ , GdCl ₃ ) in a chloroform-methanol mixture, DTPA residues cause The metal is captured to obtain a metal complex of porphyrin compounds in which the metal is bound to the corresponding DTPA residue. Specific examples include the following: (13) Ethylene glycol In-mono-diethylenetriamine-tetraacetic acid-acetate mono-
10b-methylpheophorbate (hereinafter referred to as In-
DTPA-10EG PPB-Me) (14) Ethylene glycol In-mono-diethylenetriamine-4acetic acid-acetate mono-7c
-Pyropheophorbate (hereinafter In-DTPA-
7EG pyroPPB) (15) 2-[1-(In-diethylenetriamine-4
Acetic acid-acetyloxyethane)oxyethyl]
-4-[1-(2-hydroxyethyloxy)ethyl] deuteroporphyrin dimethyl ester (hereinafter referred to as In-DTPA-EG DP-Me) (16) 2-[1-(In-diethylenetriamine-4
Acetic acid-acetyloxyethane)oxyethyl]
-4-[1-(2-hydroxyethyloxy)ethyl] deuteroporphyrin (hereinafter In-
monoDTPA-EG DP) (17) 2,4-bis[1-(In-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl] deuteroporphyrin (hereinafter referred to as In-
bisDTPA−EG DP) (18) 2-[1-(Sm-diethylenetriamine-
4-acetic acid-acetyloxyethane)oxyethyl]-4-[1-(2-hydroxyethyloxy)
ethyl] deuteroporphyrin (hereinafter Sm-
DTPA-EG DP) (19) 2-[1-(Eu-diethylenetriamine-4
Acetic acid-acetyloxyethane)oxyethyl]
-4-[1-(2-hydroxyethyloxy)ethyl] deuteroporphyrin (hereinafter Eu-
DTPA-EG DP) (20) 2-[1-(Gd-diethylenetriamine-4
Acetic acid-acetyloxyethane)oxyethyl]
-4-[1-(2-hydroxyethyloxy)ethyl] deuteroporphyrin dimethyl ester (hereinafter referred to as Gd-DTPA-EG DP-Me) (21) 2-[1-(Gd-diethylenetriamine-4
Acetic acid-acetyloxyethane)oxyethyl]
-4-[1-(2-hydroxyethyloxy)ethyl] deuteroporphyrin (hereinafter Gd-
DTPA-EG DP) (22) 2-[1-(In-diethylenetriamine-4
Acetic acid-acetyloxyethane)oxyethyl]
-4-[1-(2-hydroxyethyloxy)ethyl]Ga-deuteroporphyrin (hereinafter In
-monoDTPA-EG Ga-DP) (23) 2,4-bis[1-(In-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]Ga-deuteroporphyrin (hereinafter referred to as In-bisDTPA-EG Ga-DP) (24) 2-[1-(In-diethylenetriamine-4
Acetic acid-acetyloxyethane)oxyethyl]
-4-[1-(2-hydroxyethyloxy)ethyl]In-deuteroporphyrin (hereinafter In-
monoDTPA-EG In-DP) (25) 2,4-bis[1-(In-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]In-deuteroporphyrin (hereinafter referred to as monoDTPA-EG In-DP)
In-bisDTPA-EG In-DP (26) 2-[1-(Gb-diethylenetriamine-4
Acetic acid-acetyloxyethane)oxyethyl]
-4-[1-(2-hydroxyethyloxy)ethyl]Gd-deuteroporphyrin (hereinafter Gd
-monoDTPA-EG Ga-DP) (27) 2,4-bis[1-(Gd-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]Ga-deuteroporphyrin (hereinafter referred to as Gd-bisDTPA-EG Ga-DP) (28) 2-[1-(Ga-diethylenetriamine-4
Acetic acid-acetyloxyethane)-4-(1-hydroxyethyloxyethyl)oxyethyl]
Ga-deuteroporphyrin (hereinafter Ga-
monoDTPA-EG Ga-DP) (29) 2,4-bis[1-(Ga-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]Ga-deuteroporphyrin (hereinafter referred to as Ga-bisDTPA-EG Ga-DP) say) etc. In addition, when the polyfunctional group is a glycine or glutamic acid residue, first R ₁ , R ₂ , R ₃
and R at least one of R ₄ represents hydrogen
In the presence of a condensing agent (for example, dicyclohexylcarbodiimide (DDC)), a porphyrin compound having a porphyrin structure or a metal complex in which a metal is bonded to the porphyrin skeleton (Japanese Unexamined Patent Publication No. 61-7279 or 61-83185) is added. Glycine or glutamic acid is reacted in an inert solvent (eg chloroform). In this case, the raw material porphyrin compound is preferably reacted in the form of dicyclohexylamine or (DCHA) salt, and the glycine and glutamic acid are preferably reacted in the form of lower alkyl ester (for example, methyl ester). In this way, a porphyrin compound () is obtained, specific examples of which include: (30) Hematoporphynyl diglycine (hereinafter referred to as
(31) Hematoporphynyl diglutamic acid (hereinafter referred to as HP-glu) (32) Diacetylhematoporphynyl diglycine (hereinafter referred to as HDA-gly) (33) Diacetylhematoporphynyl diglutamic acid (hereinafter referred to as HDA-glu), etc. These porphyrin compounds () are heated with a metal chloride (for example, InCl ₃ ) in acetic acid to give a metal complex in which a metal is bonded to the porphyrin skeleton. Examples of such metal complexes are as follows: (34) In-hematoporphynyl diglycine (hereinafter referred to as In-HP-gly) (35) In-hematoporphynyl diglycine (hereinafter referred to as In-HP-gly) (36) In-diacetylhematoporphynyl diglycine (hereinafter referred to as In-HDA-gly) (37) In-diacetylhematoporphynyl diglycine (hereinafter referred to as In-HDA-glu), etc. A metal complex of a porphyrin compound () in which the binding metal is a radioactive metal can be prepared from the corresponding porphyrin compound () and the corresponding radioactive metal compound in the same manner as described above. For example, if the radioactive metal is ⁶⁷ Ga, ¹¹¹ In or ²⁰¹ Tl, then ⁶⁷ GaCl ₃ and
¹¹¹ InCl ₃ or ²⁰⁷ TlCl ₃ may be used.
Alternatively, if the radioactive metal is ⁹⁹ mTc, a pertechnetate (eg, Na ⁹⁹ mTcO ₄ ) may be used with a suitable reducing agent (eg, sodium hydrosulfite, stannous chloride). Specific examples of metal complexes of the porphyrin compound () obtained in this way are as follows: (38) ¹¹¹ In-hematoporphynyl diglycine (hereinafter referred to as ¹¹¹ In-HP-gly) (39) ¹¹¹ In-hemato Porphynyl diglutamic acid (hereinafter referred to as ¹¹¹ In-HP-glu) (40) ¹¹¹ In-diacetylhematoporfinyl
Diglutamic acid (hereinafter referred to as ¹¹¹ In-HDA-glu) (41) ⁶⁷ Ga-hematoporphynyl diglycine (hereinafter referred to as ⁶⁷ Ga-HP-gly) (42) ⁶⁷ Ga-hematoporphynyl diglutamic acid (hereinafter referred to as ⁶⁷ Ga-HP-glu) (43) ⁶⁷ Ga-diacetylhematoporphynyl
Diglutamic acid (hereinafter referred to as ⁶⁷ Ga-HDA-glu) (44) ²⁰¹ Tl-hematoporphynyl diglycine (hereinafter referred to as ²⁰¹ Tl-HP-gly) (45) ²⁰¹ Tl-hematoporphynyl diglutamic acid (hereinafter referred to as ²⁰¹ (referred to as Tl−HP−glu) (46) ²⁰¹ Tl−diacetylhematoporphynyl
Diglutamic acid (hereinafter referred to as ²⁰¹ Tl-HDA-glu) (47) Ethylene glycol ¹¹¹ In-mono-diethylenetriamine-tetraacetic acid-acetate Mono-10b-methylpheophorate (hereinafter referred to as ¹¹¹ In)
-DTPA-10EG PPB-Me) (48) 2-[1-( ¹¹¹ In-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]-4-[1-(2-hydroxyethyloxy)
( ^{49) 2-[1-(111 In} -diethylenetriamine-4acetate-acetyloxyethane)oxyethyl]-4-[1- (2-hydroxyethyloxy)
[ethyl] deuteroporphyrin (hereinafter referred to as ¹¹¹ In
-monoDTPA-EG DP) (50) 2,4-bis[1-( ¹¹¹ In-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]deuteroporphyrin (hereinafter referred to as
¹¹¹ In-bisDTPA-EG DP) (51) 2-[1-( ¹¹¹ In-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]-4-[1-(2-hydroxyethyloxy)
ethyl] Ga-deuteroporphyrin (hereinafter
¹¹¹ In-monoDTPA-EG Ga-DP) (52) 2,4-bis[1-( ¹¹¹ In-diethylenetriamine-4-acetic acid-acetyloxyethane)oxyethyl]Ga-deuteroporphyrin (hereinafter referred to as ¹¹¹ In-bisDTPA- EG Ga-DP) (53) Ethylene glycol ⁶⁷ Ga-mono-diethylenetriamine-4-acetic acid-acetate Mono-10b-methylpheophorate (hereinafter referred to as ⁶⁷ Ga
-DTPA-10EG PPB-Me) (54) 2-[1-( ⁶⁷ Ga-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]-4-[1-(2-hydroxyethyloxy)
( ^{55) 2-[1-(67 Ga} -diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]-4-[1- (2-hydroxyethyloxy)
ethyl] deuteroporphyrin (hereinafter referred to as ⁶⁷ Ga
-monoDTPA-EG DP) (56) 2,4-bis[1-( ⁶⁷ Ga-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl] deuteroporphyrin (hereinafter referred to as
⁶⁷ Ga-bisDTPA-EG DP) (57) 2-[1-( ⁶⁷ Ga-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]-4-[1-(2-hydroxyethyloxy)
ethyl] Ga-deuteroporphyrin (hereinafter
⁶⁷ GamonoDTPA-EG Ga-DP) (58) 2,4-bis[1-( ⁶⁷ Ga-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]Ga-deuteroporphyrin (hereinafter referred to as ⁶⁷ Ga-bisDTPA-EG Ga (59) Ethylene glycol ²⁰¹ Tl-mono-diethylenetriamine-tetraacetic acid-acetate Mono-10b-methylpheophorate (hereinafter referred to as ²⁰¹ Tl)
-DTPA-10EG PPB-Me) (60) 2-[1-( ²⁰¹ Tl-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]-4-[1-(2-hydroxyethyloxy)
ethyl] deuteroporphyrin dimethyl ester (hereinafter referred to as ²⁰¹ Tl-DTPA-EG DP-Me) (61) 2-[1-( ²⁰¹ Tl-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]-4-[1- (2-hydroxyethyloxy)
ethyl] deuteroporphyrin (hereinafter referred to as ²⁰¹ Tl)
-monoDTPA-EG DP) (62) 2,4-bis[1-( ²⁰¹ Tl-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl] deuteroporphyrin (hereinafter referred to as
²⁰¹ Tl-bisDTPA-EG DP) (63) 2-[1-( ²⁰¹ Tl-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]-4-[1-(2-hydroxyethyloxy)
ethyl] Ga-deuteroporphyrin (hereinafter
²⁰¹ Tl-monoDTPA-EG Ga-DP) (64) 2,4-bis[1-( ²⁰¹ Tl-diethylenetriamine-4-acetic acid-acetyloxyethane)oxyethyl]Ga-deuteroporphyrin (hereinafter referred to as ²⁰¹ Tl-bisDTPA- EG Ga-DP) (65) Ethylene ^glycol99 mTc-mono-diethylenetriamine-4-acetic acid-acetate Mono-10b-methylpheophorbate (hereinafter referred to as
⁹⁹ mTc-DTPA-10EG PPB-Me) (66) 2-[1-( ⁹⁹ mTc-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]-4-[1-(2-hydroxyethyloxy)ethyl] Deuteroporphyrin dimethyl ester ( ⁹⁹ mTc-DTPA-EG DP-
(67) 2-[1-( ⁹⁹ mTc-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]-4-[1-(2-hydroxyethyloxy)ethyl] deuteroporphyrin (hereinafter referred to as Me)
⁹⁹ mTc-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl] deuteroporphyrin ( ⁹⁹ mTc-bisDTPA-EG
(68) 2,4-bis[ ⁹⁹ mTc-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl] deuteroporphyrin (hereinafter referred to as DP)
⁹⁹ mTc-bisDTPA-EG DP) (69) 2-[1-( ⁹⁹ mTc-diethylenetriamine-4acetic acid-acetyloxyethane)oxyethyl]-4-[1-(2-hydroxyethyloxy)ethyl]Ga -deuteroporphyrin (hereinafter referred to as ⁹⁹ mTc-monoDTPA-EG Ga-DP) (70) 2,4-bis[1-( ⁹⁹ mTc-diethylenetriamine-4acetic acid-acetyloxyethane)
[oxyethyl]Ga-deuteroporphyrin (hereinafter referred to as ⁹⁹ mTc-bisDTPA-EG Ga-DP), etc. The iodized porphyrin compound () in which R ₁ is iodoethyl and R ₃ is -COO-lower alkylene-OOC-Z and its metal complex, for example, the corresponding 2-ethenylporphyrin compound or its metal complex 2-(1-bromoethyl) obtained by reacting with hydrogen bromide
It can be prepared by reacting the reaction product with sodium iodide in an inactivated solvent (for example, acetone) under heating and stirring, and complexing the resulting reaction product with a metal if necessary. Specific examples include the following: (71) Bis[2-desethenyl-2-(1-iodoethyl)-dipheophobide] ethylene glycol diester (hereinafter referred to as I ₂ PPB dimer)
) etc. (E) Effect The porphyrin compound () and its metal complex according to the present invention have a chemical structural feature in that they have a polyfunctional carboxylic acid residue in the side chain of the porphyrin skeleton, and as a result, they have various physiological effects. exhibits specific or pharmacological properties. That is, these porphyrin derivatives selectively accumulate in cancer cells and are slowly excreted from cancer cells. In particular, metal composites do not react when exposed to light, but when exposed to external energy other than light, such as microwaves or electromagnetic waves, they react and become excited, producing singlet oxygen with strong oxidizing properties. Destroy cancer cells. Furthermore, since it is quickly excreted from normal organs and cells, it does not cause any damage to them. Originally, most porphyrin derivatives have a strong effect on light, but according to the present invention, polyfunctional carboxylic acid residues are introduced into their side chains, and if necessary, these can be combined into metal complexes. By converting to cancer cells, excretion from normal tissues is increased and phototoxicity is reduced, making it possible to suppress the expression of phototoxicity while retaining selective concentration on cancer cells. Ta. As described above, the porphyrin derivatives of the present invention can react to external energy without substantially exhibiting phototoxicity, and when a chelate-forming group is present in the polyfunctional carboxylic acid residue, they can react with metals. can be universally and easily combined.
Based on these properties (cancer affinity, non-phototoxicity, cancer destruction by external energy, ability to form metal complexes, etc.), the porphyrin derivatives of the present invention are particularly useful as diagnostic agents, markers, missile therapy agents, etc. for cancer and malignant tumors. Useful. (f) Examples The pharmacological effects and manufacturing method of the substance of the present application will be explained below using examples. Example 1 Laser irradiation on excised organ (excitation fluorescence spectrum)
Colden hamsters (group of 5) on the 21st day
5mg diluted in 0.1M citrate buffer (1ml)
After intravenously injecting the test drug DTPA-10EG PPB-Me, cancer cells and other organs were removed, and each organ was injected with an N ₂ -pulsed laser (N ₂ , 337 nm,
2ns (400 to 1000 nm) was irradiated, the excitation fluorescence spectrum was measured, and wavelengths of 600 to 900 nm were examined based on the NADH peak wavelength of 470 nm. Table 1 shows the results obtained by performing the same operation below.

【table】

[Table] Table 1 shows the values obtained by measuring the excitation fluorescence spectra of each organ extracted 24 hours later, and calculating the peak wavelength at 600 to 900 nm using 470 nm as the peak wavelength of NADH as reference 1. As is clear from the results in Table 1, these porphyrin-related compounds have a remarkable selective affinity for cancer cells. Example 2 1 g of ethylene glycol mono-10b-methylpheophorate was dissolved in 50 ml of pyridine,
Add 1.5 g of DTPA and react for 3 hours under heating and stirring. The end point of the reaction was determined by TLC [MeOH-HOAc
(5:2)] to confirm the product around Rf=0.6.
After the reaction, remove excess DTPA by filtration and add ethyl acetate to the filtrate to precipitate crystals. This was subjected to silicic acid column chromatography (ethyl acetate-methanol), and DTPA-10EG PPB-Me0.5g
I got it. (Yield 31.4%) Example 3 1 g of 2-desethenyl-2-(1-ethanealcoholoxyethyl)methylpheophobide was dissolved in 50 ml of collidine, 1 g of DTPA was added, and the mixture was reacted under reduced pressure at 50° C. for 2 hours. Thereafter, the same procedure as in Example 2 was carried out to obtain 0.2 g of DTPA-2EG PPB-Me. (Yield 12.5%) Example 4 1 g of ethylene glycol mono-7c-pyropheophorate was dissolved in 60 ml of picoline, and DTPA1
g and left to react at room temperature for one week.
The following operation was performed in the same manner as in Example 2, and DTPA-7EG
0.1 g of pyroPPB was obtained. (Yield: 6.1%) Example 5 1 g of ethylene glycol mono-7c-pheophorbate is dissolved in 50 ml of DMF, 1.5 g of DTPA is added, 1 g of silica gel is added, and the mixture is reacted with stirring under heating. The following operations were carried out in the same manner as in Example 2,
0.1 g of DTPA-7EG PPB was obtained. (Yield 6.3%) Example 6 1 g of ethylene glycol mono-10b-pheophorbate was dissolved in 50 ml of pyridine, and DTPA1.5
g, and 1 g of zeolite were added, and the mixture was allowed to react under heating and stirring. The following operation was performed in the same manner as in Example 2, and DTPA
-10EG 0.4 g of PPB was obtained. (Yield 25%) Example 7 1 g of 2,4bis[1-(2-hydroxyethyloxy)ethyl]methyldeuteroporphyrin
was dissolved in 50 ml of picoline, 1 g of DTPA was added, and the mixture was reacted with heating and stirring. Thereafter, the same procedure as in Example 2 was carried out to obtain 0.6 g of DTPA-EG DP-Me. (Yield 37.7%) Example 8 1 g of 2,4-bis[1-(2-hydroxyethyloxy)ethyl] deuteroporphyrin was dissolved in 70 ml of pyridine, 1 g of DTPA was added, and the mixture was allowed to react under heating and stirring. The end point of the reaction is TLC
Rf = around 0.6 and Rf in [MeOH-HOAc (5:2)]
Two products around = 0.3 were confirmed, and the following procedure was carried out in the same manner as in Example 2. These two components were subjected to silicic acid column chromatography (ethyl acetate-methanol), and monoDTPA-EG DP0.4g and bisDTPA-
0.4 g of EG DP was obtained each. (yield 25.8% and 19.1
%) Example 9 2,4bis[1-(2-hydroxyethyloxy)ethyl]Ga-deuteroporphyrin 1 g
was dissolved in 70 ml of pyridine and reacted with 1 g of DTPA under heating and reduced pressure. The following operation was carried out in the same manner as in Example 8, and monoDTPA-EG Ga-DP0.3g and bisDTPA were used.
0.3 g of -EC Ga-DP was obtained. (Yield 20.3
% and 15.4%) Example 10 1 g of 2,4bis[1-(2-hydroxyethyloxy)ethyl]In-deuteroporphyrin was dissolved in 70 ml of collidine, 1 g of DTPA was added, and the mixture was reacted with stirring under heating. The following operation was carried out in the same manner as in Example 8, and 0.5 g of monoDTPA-EG In-DP was added.
0.4 g of bisDTPA-EG In-DP was obtained.
(Yield 35.5% and 22.0%) Example 11 Each compound obtained in Examples 2, 4, 7, 8, 9, and 10, namely DTPA-10EG PPB-Me, DTPA-7EG pyroPPB, DTPA-EG DP 1 g each of -Me, monoDTPA-EG DP, bis-DTPA-EG DP, monoDTPA-EG Ga-DP, bisDTPA-EG Ga-DP, monoDTPA-EG In-DP and bisDTPA-EG In-DP was separately treated with CHCl. When dissolved in 100 ml of ₃ -MeOH (3:1) and added with the calculated amount of InCl ₃ dissolved in 2 ml of water, a complex is immediately formed (change in color tone is confirmed by TLC, visual inspection, and ultraviolet hand scope). . The obtained complexes were concentrated to dryness under reduced pressure, and the following compounds were obtained separately: In-DTPA-10EG PPG-Me, In-DTPA-7EG pyroPPB, In-DTPA-EG DP-Me, In-monoDTPA-EG DP, In- bisDTPA−EG DP, In−monoDTPA−EG Ga−DP, In−bisDTPA−EG Ga−DP, In−monoDTPA−EG In−DP, and In−bisDTPA−EG In−DP were obtained with 100% yield, respectively. . Example 12 DTPA-EG DP obtained in Example 8 [mono:
bis (3:1) mixture] 1 g was added to CHCl ₃ -MeOH
(4:1) in 100 ml, to which calculated amounts of SmCl ₃ , EuCl ₃ and GdCl ₃ each dissolved in 2 ml of water are added separately to immediately form a complex. Thereafter, the same procedure as in Example 11 was carried out to obtain Sm-DTPA-EG DP, Eu-DTPA-EG DP, and Gd-DTPA-EG DP, each with a yield of 100%. Example 13 monoDTPA-EG Ga- obtained in Example 9
1 g each of DP and bisDTPA-EG Ga-DP
When dissolved in 200 ml of CHCl ₃ -MeOH (1:1) and separately added the calculated amount of Gd-Cl ₃ dissolved in 2 ml of water, a complex is immediately formed. Thereafter, the same procedure as in Example 11 was carried out to obtain Gd-monoDTPA-EG Ga-DP and Gd-bisDTPA-EG Ga-DP with a yield of 100%. Example 14 monoDTPA-EG Ga- obtained in Example 9
1 g each of DP and bisDTPA-EG Ga-DP
Dissolved in 200 ml of CHCl ₃ -MeOH (1:1), to which a calculated amount of GaCl ₃ dissolved in 2 ml of pyridine is added separately to immediately form a complex. Thereafter, the same procedure as in Example 11 was carried out to obtain Ga-monoDTPA-EG Ga-DP and Ga-bisDTPA-EG Ga-DP with a yield of 100%. Example 15 Dissolve 1 g of hematoporphyrin in 30 ml of THF,
To this was added 2 ml of DCHA dissolved in 10 ml of ether to react. If ether is added after the reaction, crystals will precipitate. Collect these crystals and use them in the ether.
Filter off DCHA, hematoporphyrin DCHA salt
1.4g was obtained. (Yield 90.0%) Example 16 1 g of diacetyl hematoporphyrin was added to Example 15.
Diacetylhematoporphyrin is prepared in the same manner as
1.4 g of DCHA salt was obtained. (Yield 94.6%) Example 17 Hematoporphyrin obtained in Example 15
To 1 g of DCHA salt, 50 ml of CHCl ₃ was added, then 0.6 g of glycine ethyl hydrochloride was added, and 0.5 g of DCC was added dropwise with stirring to react for 2 hours. After standing overnight {confirmed by TLC [toluene-acetone (1:1)]}, concentrate under reduced pressure and add ethyl acetate to the residue.
Filter out DCUrea. After concentrating the filtrate under reduced pressure, HP-gly
-Ethyl ester was obtained. Add this to 50ml of alcohol
Add and dissolve, and add N/ to dissolve until the hydrolysis reaction is completed.
Add 2KOH alcohol. After the reaction, water is added and a trace amount of DCUrea is filtered off again. When 10% citric acid is added to the filtrate to make it acidic (PH4), crystals will precipitate. Collect this by filtration, wash with water, dry and HP-
Obtained 0.8 g of gly. (Yield 71.4%) Example 18 Hematoporphyrin obtained in Example 15
50 ml of CHCl ₃ was added to 1 g of DCHA salt, and then 0.8 g of hydrochloric acid glutamic acid diethyl ester was added, and the procedure was repeated in the same manner as in Example 17 to obtain 1.0 g of HP-glu. (Yield 78.1%) Example 19 0.6 g of glycine ethyl hydrochloride ester was added to 50 ml of a CHCl ₃ solution containing 1 g of the diacetylhematoporphyrin DCHA salt obtained in Example 16, and the following Example 17
0.9 g of HDA-gly was obtained in the same manner as above. (yield
81.1%) Example 20 To 50 ml of a CHCl ₃ solution containing 1 g of the diacetylhematoporphyrin DCHA salt obtained in Example 16, 0.8 g of diethyl hydrochloride glutamic acid ester was added, and the following procedure was repeated in the same manner as in Example 17 to obtain 1.1 g of HDA-glu. I got it.
(Yield 87.3%) Example 21 Reaction intermediates obtained in Examples 17, 18, 19, and 20
1 g each of HP-gly-ethyl ester, HP-glu-diethyl ester, HDA-glu-ethyl ester, HDA-glu-diethyl ester
50 ml of acetic acid was added to each to dissolve them, and then 200 mg of sodium acetate and 200 mg of InCl ₃ were added, and the mixture was allowed to react under heating and stirring at 100°C. After the reaction (can be easily determined by visual inspection, ultraviolet handscope, or TLC), add 100 ml of physiological saline to precipitate crystals, collect by filtration, wash the filtrate with water, and dilute with N/2KOH alcohol. After the reaction, add 10% citric acid to make it acidic (PH4), and crystals will precipitate. This was collected by filtration, washed with water, and dried to give In-HP-gly0.5 (yield 41.0%), In-HP-glu0.4g (yield 33.3%), In-HDA-gly0.4g (yield 33.1%) and In-HDA-glu (0.4 g, yield 33.9%) were obtained. Example 22 ¹¹¹ Production of a radioactive diagnostic agent containing a complex of In-monoDTPA-EG Ga-DP as an active ingredient Add monoDTPA-EG Ga-DP to 2 ml of sterile, pyrogen-free 0.1M citrate buffer (PH5.7).
Add 1.96 mg (1.68 μmol) and dissolve. This solution is passed through a 0.2 μm pore size filter and filled into a nitrogen purged vial. Add 0.1 ml of saline containing _1.3 mCi of ¹¹¹ InCl to the vial and
A radioactive diagnostic agent containing ¹¹¹ In-monoDTPA-EG Ga-DP complex as an active ingredient was obtained. Example 23 Properties of radiodiagnostic agent containing ¹¹¹ In-monoDTPA-EG Ga-DP as an active ingredient ¹¹¹ In contained in the radiodiagnostic agent obtained in Example 22
-monoDTPA-EG To investigate the labeling rate of Ga-DP, methanol:
It was developed using acetic acid (5:1) as a solvent and scanned with a radiochromato scanner. Radioactivity was depicted as a peak at Rf=0.31, and no other radioactivity peaks were observed. Furthermore, when chromatography was performed on ¹¹¹ InCl ₃ used in the production of the present radiodiagnostic agent shown in Example 22 in the same manner as described above, a radioactive peak was observed at the origin. From the above results, ¹¹¹ In-monoDTPA- contained in this radiodiagnostic agent.
It was confirmed that the labeling rate of EG Ga-DP was approximately 100%. Example 24 Production of a radioactive diagnostic agent containing _a complex of ¹¹¹ In-HP-gly as ^an active ingredient HP-
1 ml of an acetic acid solution containing 1.03 mg (1.68 μmol) of gly was added and dissolved by stirring for 5 minutes using an ultrasonic cleaner.
Further, the solution was heated in an oil bath (80° C.) for 1 hour, and then allowed to naturally heat up to room temperature. Next, 2ml of water
was extracted twice with 2 ml of Kasho ethyl acetate. The ethyl acetate layer was collected, washed with 2 ml of water, and further dried under vacuum. After drying, add 0.05ml of 0.1N NaOH to the residue.
(5μmol), stir to dissolve and continue to 2/15N
2 ml of phosphate buffer (PH7.4) was added and mixed. This solution was filled into a nitrogen purged vial through a 0.2 μm pore size filter, and the desired ¹¹¹ In-HP-
A radioactive diagnostic agent containing a gly complex as an active ingredient was obtained.
(Yield 76.4%) Example 25 Properties of radiodiagnostic agent containing ¹¹¹ In-HP-gly as an active ingredient ¹¹¹ In contained in the radiodiagnostic agent obtained in Example 24
In order to examine the radiochemical purity of -HP-gly, a test was conducted in the same manner as in Example 23. Radioactivity is depicted as a peak at Rf = 0.66,
No other radioactivity peaks were observed. From this, it was confirmed that the radiochemical purity of this drug was almost 100%. Example 26 Scintigraphy of a radiodiagnostic agent containing ¹¹¹ In-monoDTPA-EG Ga-DP as an active ingredient in tumor-bearing hamsters The radiodiagnostic agent (300 μCi) obtained in Example 22 was
Intravenously administered to hamsters transplanted with pancreatic cancer [References
Ueda et al.; PeptIdes, 5, 423, (1984)], after administration
Scintigrams were obtained after 72 and 96 hours using a gamma camera equipped with a medium-energy high-resolution collimator. According to this, the cancer site was clearly visualized at both times. From this, it was confirmed that this agent is very useful as a cancer diagnostic agent. Example 27 ¹¹¹ In-monoDTPA-EG In-body distribution of a radiodiagnostic agent containing Ga-DP as an active ingredient in tumor-bearing hamsters Radioactive diagnostic agent obtained in Example 22 (300 μCi)
Alternatively, gallium citrate ( ⁶⁷ Ga) (1mCi) is currently widely used as a cancer diagnostic agent in clinical settings.
was intravenously injected into the hamster shown in Example 26, dissected over time to extract the organs, measure the radioactivity in each organ and the weight of each organ, and obtain the radioactivity ratio between the cancer and each organ. . (The results are shown in Tables 2 and 3)

【table】

[Table] From Tables 2 and 3, it was confirmed that this drug has a higher cancer accumulation property than gallium citrate ( ⁶⁷ Ga). Example 28 Distribution of a radioactive diagnostic agent containing ¹¹¹ In-HP-gly as an active ingredient in tumor-bearing hamsters Radioactive diagnostic agent obtained in Example 24 (300 μCi)
was intravenously injected into the hamster shown in Example 26, and
Dissection was performed according to 27, and the radioconcentration ratios of the cancer and each organ were obtained. (The results are shown in Table 4)

[Table] From Table 4, it was confirmed that this drug has a high cancer accumulation property. Example 29 ⁹⁹ mTc-monoDTPA-EG Production of radioactive diagnostic agent containing Ga-DP as an active ingredient MonoDTPA-EG Ga-DP 1.74 mg (1.5 μmol)
Add to 1.5 ml of distilled water for injection, stir to dissolve, and add 0.26 mg of sodium hydrosulfite.
(1.5 μmol) and dissolve. Next, the pH was adjusted to around 5.7 with a 0.1N hydrochloric acid solution. This solution is passed through a 0.2 μm pore size filter and filled into a nitrogen purged vial. 5.0mCi pertechnetate
A radioactive diagnostic agent containing ⁹⁹ mTc-monoDTPA-EG Ga-DP as an active ingredient was obtained. Example 30 Properties of radiodiagnostic agent containing ⁹⁹ mTc-monoDTPA-EG Ga-DP as an active ingredient Contained in the radiodiagnostic agent obtained in Example 29
In order to investigate the labeling rate of ⁹⁹ mTc-monoDTPA-EG Ga-DP, a test was conducted in the same manner as in Example 23. Radioactivity was depicted as a peak at Rf=0.31, and no other radioactivity peaks were observed. Furthermore, when chromatography was performed on the pertechnetate salt used in the production of the present radiodiagnostic agent shown in Example 29 in the same manner as above, Rf=
A radioactivity peak was observed at 0.87. From the above results, the ⁹⁹ mTc contained in this radiodiagnostic agent
The labeling rate of monoDTPA-EG Ga-DP is approximately 100
It was confirmed that %. Example 31 ⁶⁷ Production of a radioactive diagnostic agent containing Ga-DTPA-EG DP-Me as an active ingredient Add DTPA-EG DP-Me1 to 2 ml of sterile, pyrogen-free 0.1M citrate buffer (PH5.7). 86mg
(1.68μmol) was added, dissolved, and the pore size was further increased to 0.2μmol.
Pass through a filter and fill into a nitrogen purged vial. Add 0.1 ml (1.3 mCi) of ⁶⁷ GaCl ₃ to the vial to obtain the desired ⁶⁷ Ga-DTPA-EG DP-.
A radioactive diagnostic agent containing Me as an active ingredient was obtained. Example 32 Properties of radiodiagnostic agent containing ⁶⁷ Ga-DTPA-EG DP-Me as an active ingredient ⁶⁷ Ga contained in the radiodiagnostic agent obtained in Example 31
-DTPA-EG In order to examine the labeling rate of DP-Me, a test was conducted in the same manner as in Example 23.
Radioactivity was depicted as peaks around Rf = 0.31 and Rf = 0.06. The radioactivity peak observed at Rf=0.31 is monoDTPA-EG DP-Me, and the radioactivity peak observed at Rf=0.06 is
bisDTPA-EG DP-Me, respectively. This was confirmed from the characteristic coloration of the Rf derivative on the thin layer. Further, when chromatography was performed on ⁶⁷ GaCl ₃ used in the production of the present radiodiagnostic agent shown in Example 31 in the same manner as described above, a radioactive peak was observed at the origin. From the above results, ^{the 67} Ga-
It was confirmed that the labeling rate of DTPA-EG DP-Me was approximately 100%. Example 33 Production of a radioactive diagnostic agent containing ¹¹¹ In-bisDTPA-EG DP as an active ingredient 2.41 mg (1.68 μM) of BisDTPA-EG DP was prepared according to the production method shown in Example 22.
A radioactive diagnostic agent containing ¹¹¹ In-bisDTPA-EGDP as an active ingredient was obtained. Example 34 Properties of radiodiagnostic agent containing ¹¹¹ In-bisDTPA-EG DP as an active ingredient ¹¹¹ In contained in the radiodiagnostic agent obtained in Example 33
−bisDTPA−EG To examine the labeling rate of DP,
The test was conducted in the same manner as in Example 23. Radioactivity was depicted as a peak near Rf=0.06, and no other radioactivity peaks were observed. From this,
It was confirmed that the labeling rate of ¹¹¹ In-bisDTPA-EG DP contained in this drug was approximately 100%. Example 35 Production of a radioactive diagnostic agent containing ⁶⁷ Ga ^- HP- _glu as an active ingredient HP-
1 ml of an acetic acid solution containing 1.46 mg (1.68 μmol) of glu was added, and the desired radioactive diagnostic agent containing ⁶⁷ Ga-HP-glu as an active ingredient was obtained according to the manufacturing method shown in Example 24. (Yield 46.5%) Example 36 Properties of radiodiagnostic agent containing ⁶⁷ Ga-HP-glu as an active ingredient ⁶⁷ Ga contained in the radiodiagnostic agent obtained in Example 35
In order to determine the radiochemical purity of -HP-glu, a test was conducted in the same manner as in Example 23. Radioactivity was depicted as a peak at Rf=0.83, and no other radioactivity peaks were observed. From this, it was confirmed that the radiochemical purity of this drug was almost 100%. Example 37 1 g of bis(pheophobide) ethylene glycol diester is dissolved in 25 g of 30% hydrobromic acid/acetic acid and reacted for 15 hours with stirring. After the reaction, it was concentrated under reduced pressure to obtain bis[2-desethenyl-2-(1
-Bromoethyl)-pheophobide]ethylene glycol diester crystals were obtained. This was dissolved in 50ml of acetone, and then dissolved in 50ml of acetone.
Add 10 g of NaI and react for 30 minutes while stirring while heating. After the reaction, add 100ml of water to the reaction solution and dilute with CHCl ₃
Extraction was performed to obtain 1.0 g of l ₂ PPB dimer. (Yield 82.0
%) Example 38 2,4-bis[1-(2-hydroxyethyl)
Treated in the same manner as in Example 9 using 2,4-bis[1-(3-hydroxypropyl)oxyethyl]Ga-deuteroporphyrin instead of [oxyethyl]Ga-deuteroporphyrin,
monoDTPA-PG Ga-DP was obtained. Example 39 ¹¹¹ In-monoDTPA-PG Production of a radioactive diagnostic agent containing Ga-DP as an active ingredient ¹¹¹ In-monoDTPA was treated in the same manner as in Example 22 except that monoDTPA-PG Ga-DP was used.
A radioactive diagnostic agent containing -PG Ga-DP as an active ingredient was obtained. Example 40 ¹¹¹ In−monoDTPA−EG Ga−DP, ¹¹¹ In−
monoDTPA-PG Biological distribution of radioactive diagnostic agents containing Ga-DP and gallium citrate ( ⁶⁷ Ga) as active ingredients in tumor-bearing and inflammation-inducing hamsters. -pinene: β-pinene: l-limonene = 8:1:1, weight ratio) to induce inflammation. To this, ¹¹¹ In−monoDTPA−EG Ga
−DP (760μCi), ¹¹¹ In−monoDTPA−PG Ga−
DP (760μCi) or gallium citrate ( ⁶⁷ Ga)
A radioactive diagnostic agent containing (570 μCi) as the active ingredient was intravenously injected, and 72 hours later, a scintigram was obtained with a gamma camera. Thereafter, dissection was performed over time, organs were extracted, and the radioactivity in each organ and the weight of each organ were measured to obtain the radioactivity concentration ratio between the cancer and each organ. The results are shown in Table 5.

【table】

[Table] From the above results, ¹¹¹ In−monoDTPA−EG Ga
−DP and ¹¹¹ In−monoDTPA−PG Ga−DP
shows almost the same ability in terms of cancer affinity and inflammation focus affinity, but when compared with gallium citrate ( ⁶⁷ Ga), both are superior in cancer visualization ability.
It can be understood that the ability to visualize inflammatory foci is inferior. Example 41 ¹¹¹ In−monoDTPA−EG Ga−DP, ¹¹¹ In−
monoDTPA−PG Ga−DP, ¹¹¹ In−
MonoDTPA-EG Radioactive diagnostic agent containing Zn-DP and gallium citrate ( ⁶⁷ Ga) as active ingredients in inflammation-induced rats. 0.1 ml of croton oil was subcutaneously injected into the right hind paw of SD rats (weighing approximately 200 g). . 4 days later, ¹¹¹ In−
monoDTPA−EG Ga−DP, ¹¹¹ In−
monoDTPA−PG Ga−DP, ¹¹¹ In−
A radioactive diagnostic agent (0.5-1.0 mCi) containing monoDTPA-EG Zn-DP or gallium citrate ( ⁶⁷ Ga) as an active ingredient was administered into the tail vein, and 72 hours later, a scintigram was obtained with a gamma camera. Thereafter, dissection was performed over time, organs were extracted, and the radioactivity in each organ and the weight of each organ were measured to obtain the radioactivity concentration ratio between the cancer and each organ. The results are shown in Table 6.

[Table] From the above results, ¹¹¹ In−monoDTPA−EG
Ga-DP, ¹¹¹ In-monoDTPA-PG Ga-DP and ¹¹¹ In-monoDTPA-EG Zn-DP accumulate to a lesser extent in inflammatory foci compared to gallium citrate ( ⁶⁷ Ga), and are therefore more effective in detecting cancer. I can understand that it is suitable. Example 42 2-[1-(2-hydroxyethyloxy)ethyl]-4-vinylGa-deuteroporphyrin and its positional isomer 2-vinyl-
1 g of 4-[1-(2-hydroxyethyloxy)ethyl]Ga-deuteroporphyrin (mixture) [monoEG Ga-DP] is dissolved in 40 ml of pyridine, 1 g of DTPA is added, and the mixture is allowed to react under heating and stirring. The following procedure was carried out in the same manner as in Example 2, and 2-[1-(2-hydroxyethyloxy)
ethyl]-4-vinylGa-deuteroporphyrin, and its positional isomer 2-vinyl-4
-[1-(2-hydroxyethyloxy)ethyl]Ga-deuteroporphyrin DTPA monoester [monoDTPA-monoEG Ga-DP]
0.5g was obtained. (Yield 33.3%) Example 43 ¹¹¹ In-monoDTPA-monoEG Production of radioactive diagnostic agent containing Ga-DP as an active ingredient MonoDTPA-monoEG The same procedure as in Example 22 was used except for using Ga-DP ^. In−
A radioactive diagnostic agent containing monoDTPA-monoEG Ga-DP as an active ingredient was obtained. Example 44 ¹¹¹ In-monoDTPA-monoEG Properties of radiodiagnostic agent containing Ga-DP as an active ingredient ¹¹¹ In contained in the radiodiagnostic agent obtained in Example 43
-monoDTPA-monoEG In order to determine the radiochemical purity of Ga-DP, a test was conducted in the same manner as in Example 23. Radioactivity was depicted as a peak at Rf: 0.31, and no other radioactivity peaks were observed. Therefore, the radiochemical purity of this drug is approximately 100%.
It was confirmed that %. Example 45 Distribution of a radioactive diagnostic agent containing ¹¹¹ In-monoDTPA-monoEG Ga-DP as an active ingredient in tumor-bearing hamsters. ¹¹¹ In−
A radiopharmaceutical containing monoDTPA-monoEG Ga-DP as an active ingredient was intravenously injected, and 72 hours later, a scintigram was obtained with a gamma camera. According to this, the cancer site was clearly depicted. Thereafter, the animal was dissected, the organs were removed, and the radioactivity in each organ and the weight of each organ were measured to obtain the radioactivity concentration ratio between the cancer and each organ. The results are shown in Table 7.

[Table] From the above results, it was confirmed that this drug is useful for cancer diagnosis. (G) Effects of the Invention The porphyrin derivative of the present invention has the ability to accumulate in cancer cells, has reactivity to external energy, has a destructive action on cancer cells, and does not exhibit phototoxicity to normal cells. , is extremely useful as a cancer therapeutic or cancer diagnostic agent.

Claims (1)

[Claims] 1 Formula: (In the formula, R ₁ and R ₂ are −CH=CH ₂ , −
_{CH2CH3 ,} -CH(O-lower alkanoyl) _CH3 , -
CH(OR) _CH3 or -CH(O-lower alkylene-OR)CH3, _R3 is _-H , -COOH, -COO-lower alkyl, -COO-lower alkylene-OR or -COO-lower alkylene-OOC −Z, R ₄ is −
H, -lower alkyl or -lower alkylene-
OR, R is -H, -lower alkyl or a residue obtained by removing water from a polyfunctional carboxylic acid, Z is a residue obtained by removing R ₃ from the compound of formula (), A is -CH ₂ - or -CO- , a dotted line bonded to the γ position indicates no bond or a single bond, and a dotted line between the 7th and 8th positions indicates the presence of a single bond or a double bond. ) and its metal complexes (however, the metal can exist within the porphin skeleton or within the polyfunctional carboxylic acid residue, or within the porphin skeleton and within the polyfunctional carboxylic acid residue. At least one of ₁ , R ₂ , R ₃ and R ₄ must be a group with R representing a polyfunctional carboxylic acid residue. Furthermore, R ₃ must be -COO-
In the case of lower alkylene-OOC-Z, R ₁ can be 1-iodoethyl in addition to the above meaning. ).