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PLATINUM METALS REVIEW A quarterly survey of research on the platinum metals and of developments in their application in industry VOL. 32 OCTOBER 1988 NO. 4 Contents Reactions of Complexes of Platinum Metals with Bio-Molecules 226 Water Soluble Rhodium Catalysts 226 The Destruction of Polychlorinated Biphenyls 186 Chemical Conversion of Carbon Dioxide 187 The Electrodeposition of Platinum and Platinum Alloys 188 Ruthenium in Cancer Chemotherapy 198 Lean-Burn Oxygen Sensor Material 199 Control of Corrosion in Molten Carbonate Fuel Cells 200 Flammable Gas Detection 203 International Congress on Catalysis 204 Geology and Geochemistry of the Platinum Metals 208 Abstracts 209 New Patents 217 Index to Volume 32 226 Communications should be addressed to The Editor, Platinum Metals Review Johnson Matthey Public Limited Company, Hatton Garden, London ECl N 8EE Reactions of Complexes of Platinum Metals with Bio-Molecules By Professor A. G. Sykes Department of Chemistry, The University, Newcastle upon Tyne, England There is a growing recognition of the opportunities that may exist for in- organic biochemistry to contribute to the solution of practical problems that occur in many quite different areas, ranging from mineral extrac- tion to medicine. While most traditional applications of the platinum metals depend upon their ability to remain largely unchanged in highly reactive environments, compounds of these metals can be quite reactive and do react with biological materials. This paper reviews the present position and indicates potential applications. The reactions of co-ordination complexes of finds applications in the treatment of testicular, the platinum metals and gold with bio- ovarian and lung cancers. Cis-platin was the molecules are relevant to a number of areas. first successful anti-cancer drug, but it does The most important of these currently relates to display unpleasant side effects, notably kidney the medicinal applications of platinum and gold toxicity, nausea and vomiting, as well as (I), with much potential still to be explored. neurotoxicity. Second generation drugs, carbo- There are other applications, however, in- platin [a], which is now approved for use in cluding the laboratory use of platinum metals as the U. K., iproplatin [bl and spiroplatin [cl ,a re heavy-atom markers in the determination of less toxic and have better anti-tumour activity. biological macromolecule crystal structures, the (3). There are additional advantages, thus use of osmium tetroxide as a specific oxidant spiroplatin has higher water solubility, of and biological stain, and the use of attached o.5M, which allows easier administration of the ruthenium complexes as spectroscopic labels drug. It has been demonstrated that this form and probes for studying the electron-transfer of drug is active against three animal tumours reactions of bio-molecules. At the other ex- with a 30-fold greater activity than cis-platin. treme there is the potential use of micro- The use of carboplatin and iproplatin in organisms in mining processes, and for the synergistic combination with radiotherapy is selective extraction/recovery of metals from being investigated. Third generation drugs aqueous solutions (pH>2) with cells or cell ex- which contain combinations of malonate and tracts. The formation of ruthenium as a fusion cyclobutanedicarboxylate with amine and product in nuclear reactors-the isotopes lo3 Ru diamine ligands, so giving a broad spectrum of and '06 Ru have half lives of 40 days and I year, activity, are currently under investigation (3, respectively-and its release into the at- 4). Features of all these drugs are the use of mosphere at the time of the Chernobyl mishap, neutral Pt(I1) or Pt(1V) complexes which con- is also relevant. tain two cis amine groups (primary or secon- The use of the Pt(I1) complex cis-platin, dary, but not tertiary) and two other good cis cis-[Pt(NH,),CI,l, in chemotherapy was ap- leaving groups. Thus trans complexes, or cis proved as recently as 1979, and this is now the complexes with poor leaving groups, that is the leading anti-cancer drug in the U.S.A. (2). It is inert CN-, ONO-, NCS- or I-, are inactive. used in combination therapy with either Early experiments demonstrated that cis- and adriamycin or bleomycin and binblastine, and trans-platin bind more strongly to RNA than to Platinum Melals Rev., 1988, 32, (4), 170-178 170 DNA, and least strongly to proteins. However, Au(1) bis-diphosphine complexes such as when their ability to suppress synthesis was [Au(dppe),lU may have a future as anti- measured at low concentrations only the syn- cancer agents (11). Titanocene dichloride, thesis of DNA was suppressed. It is believed that [Ti(Cp), U , 1, where Cp = cyclopentadienyl, cis-platin type complexes are effective because represents an interesting example of an they bind to the N-7p ositions of two adjacent organometallic anti-tumour reagent (12). guanines of the DNA, and that this hinders Another type of interaction of simple replication (5-7). A normal cell is able to op- transition-metalc omplexes with DNA is the in- pose this attachment by means of its repair tercalation which m r s with planar mechanisms, while a tumour cell has a deficien- heterocyclic chromophores. The heterocyclic cy in repair proteins which could otherwise ligands can insert and stack between base pairs recognise the damaged segment and cause a of the DNA helix. Such effects have recently repair. Analogous trans complexes attach more been reviewed by Barton (8). The stereoselec- readily to guanine in the initial stages but tive interaction of tris(phenanthr0line) com- ,+ decrease in concentration over 24 hour periods plexes such as [Rubhen) 1 has for example ,+ due to their removal by repair proteins. been noted, the A-[Ru(phen) 1 complex in- A complex such as cis-platin is believed to re- tercalating more favourably than the A isomer, main in the neutral dichloro form in the plasma which is inhibited by steric repulsions between where the concentration of U- is high H-atoms of the phenanthroline and 0-atoms of (-103mM). After W o n a cross the cell the DNA phosphate (13). There are also membrane, in the presence of only ,~IM U- spectroscopic applications, and the tris - in the cytoplasm, the complex yields the (4,7 diphenylphenanthroline) ruthenium (11) various aquated products (8). Since H,O is a complex can be used as a sensitive stain for good leaving group the platinum can then at- helix conformation in chromosome studies tach itself to the DNA. using fluorescence techniques. Electron- Rhodium complexes, for example transfer reactions of intercalated metal com- [Rh,(O,CR),l, have been reported to possess plexes, for example the Fe(I1)-EDTA some activity as anticaocer agents (9). More derivative complex which has the aromatic generally, when added to cell growth media, methidium intercalator attached by a short complexes mm-[RhX,L,l (where L is a N- hydrocarbon chain, can with oxygen give rise to heterocyclic such as pyridine) are known to in- single strand DNA scissions (14). The Fe(I1) terfere with cell division and cause f3atmnt.a- activates the oxygen to yield 0,- or tion in growth (10). A series of Pd(II) analogue OH' radicals (or Fe-0, complexes), which at complexes have been tested, but show little high local concentrations can bring about promise. It is known that Pd(I1) is more labile cleavage of the sugar phosphate backbone. than Pt(I1) and this can lead to unavoidable tox- The binding of platinum complexes to icity. The Pd(II) may not even reach the DNA. cytochrome c has recently been studied. A Recent reports indicate that the four-cmrdinate metalloprotein has many advantages in such Platinum Me& Rm., 1988, 32, (4) 171 investigations because structural features have number of reagents, possibly with some pertur- been extensively explored, and the presence of bation of conformation, is however of low reac- the metal helps in demonstrating whether at- tivity with [Pt(terpy)ClI+. This is particularly tachment of a second metal has any disruptive interesting since, in separate studies with amino effects on the protein structure. Kostili has acids or small peptides as entering ligands, the shown that [PtCI I - and [ Pt(z-Fpy) ,C 1 ,I , complex is completely selective towards cys- where 2-Fpy is 2-fluoropyridine, cross-link teine. From a recent crystallographic study on horse cytochrome c by co-ordinating to the iso-1-cytochrome c, it has been confirmed that S-atom of the thioether side chain of a the Cysroz is buried and in a hydrophobic methionine, [dl, in this case Met65 (15). region. The binding is illustrated in [el. With Recently it has been demonstrated that in- [Pt(terpy)ClP however, selective covalent cubation of horse cytochrome c with the Rh(I1) labelling of histidine residues, tfl, His33 (major dimer [Rh,(O,CCH,),l for 2 days at pH 7 (but binding) and His26 (minor binding) is observ- not pH 5) gives the diprotein complex ed, with no labelling of Met65 (16). The dif- [Rh,(O,CCH,),l(cyt c)~[,g l (19). Attachment ference in behaviour can be attributed to the A steric demands of the terpyridine ligand, % which prevent it binding to the thioether group. Interestingly, in the case of the com- OI ..>.GJ - G f l HNVN- Rh‘- R6’- N-NH plex [Pt(NH,) H, 01 + preliminary results *o’ I indicate that binding occurs 55 per cent to yo the methionine and 45 per cent to histidine [gl His33 (17). is at a histidine residue, and model complexes H3Nt - CI H-COO- 0,s‘- PLI t -C\sH 3 I[mRh =,( Oim,CidCaHzo,l)e,,( Iwmit)h,I tchaen Ibme pcroe-poarrdeidn,a wtehde irne the axial position. Since no reaction is observed (CH2)2 ‘0 I H3C LI with tuna cytochrome c, which does not have :.s\ the His33 residue, it has been concluded that CH3 attachment is at this residue on horse L=CI- or cytochrome c. Enhanced stability of the dimer Met QF [ dl [el adduct to hydrolysis, as compared to [Rh,(O,CCH,),(Im),l, is attributed to the t H3N -CH -COO- I steric bulk of the protein with the possibility of some H-bonding in addition. CH2 I Gold(1) drugs are extensively used in the HF=F treatment of rheumatoid arthritis although :Nb ,NH again the mechanism is not well understood C H (20). The most commonly used drugs are His Ifl Myochrisin (gold sodium thiomalate) and The reaction of cytochrome c from Candtda Solganal (gold thioglucose), which are ad- krusei and baker’s yeast with [Pt(terpy)Cl] ministered by weekly or monthly intramuscular + has also been studied (IS), when modification injections. The structures of these compounds of surface His33 and His39 residues (which are are not known precisely. The newer drug in hydrophilic regions) is observed, but His26 Auranofin, the gold triethyl phosphine (in a hydrophobic pocket) is largely shielded. thioglucose complex, can be administered oral- The cysteine residue, HS-CH,-R (pK,- 8.3), ly (11). It seems likely that the role of the drug Cys102 in baker’s yeast, which is reactive to a is anti-inflamatory and/or anti-enzymatic, and Platinum Metals Rev., 1988, 32, (4) 172 residues, none of which are present in large numbers in metalloproteins, and in some cases provide unique sites. Some care is required because mother liquors high in [CI-I or AcO [SO, 2-1 concentrations could impede efficient binding of [PtCI,lz-, which is first converted The Structure of Auranofin to aqua and hydroxo forms of neutral or I+ charge before attaching to the residues in- dicated (25). Other complexes which will react that the body's immune responses are effected in the same way are [Pt(N02),12-, in some way. There is some evidence that gold [Pt(NH,),CI,l or IPt(en)CI,l, where accumulates in the red blood cells. The uptake en = ethylenediamine, whereas the inertness of Et,PAu+ into such cells has been in- of [Pt(CN),12- ensures its retention as a vestigated (21). With concentrations of 2- anion which will interact, if at all, with , Et PAu (up to 9mM) in excess of that achiev- positively charged residues (lysines, arginines + ed in therapeutic applications (25-5opM), in- and at pH<7 histidines) by electrostatic associa- teractions with intracellular glutathione, and a tion. A wide range of mercury compounds in- second site identified as the cysteine p-93 of cluding for example ethylmercury phosphate, hemoglobin, takes place. Excess Et PAu' also are known to bind to cysteine or histidine reacts at weaker binding sites (nitrogen or residues (26), and can, because of their struc- thioether ligands). Comparisons have been ture, readily penetrate into proteins to react made with the binding of gold at weak and with buried side chains. Lanthanides (often strong binding sites identified on serum samarium because of its large anomalous scat- albumin (22). A facile interprotein gold transfer tering signal) and uranium compounds will from gold modified hemoglobin to the -SH con- bind at carboxylate residues, although buffers taining component of serum albumin has been other than phosphate (which will bind to such noted in this work. The application of I'P metals) should be used. The complex ion NMR spectroscopy has been important in these K, [HgI, 1, which in aqueous solution generates studies. trigonal [HgI,]- , can bind electrostatically to The use of heavy-atom markers was a major cations or, because of its flat structure, breakthrough in the X-ray structure determina- penetrate into proteins (23). tion of large bio-molecules. In this process the The strong oxidant osmium tetroxide, which crystalline material is derivatised for phase is more stable than RuO, ,i s used as a reagent determination by a method of isomorphous to give syn dihydroxy addition from the less replacement (23). Procedures involve soaking hindered side of a double bond (27). The the crystal in mother liquor containing the reagent adds rather slowly but quantitatively to heavy-atom marker, or reacting the two give the intermediate as illustrated [il. together prior to crystallisation. In order to ob- - tain the necessary information, the native dif- I I fraction intensities and those obtained from - c = c - + OSOL c - c - crystals derivatised in at least two unique sites I I I I Iil - have to be determined. HO OH I I The reactivities of individual amino acids has -C-C-- been summarised by Petsko and different I I classes of heavy-atoms defined according to The latter is subsequently decomposed with their affinities (23). The most extensively used sodium sulphite in, for example, ethanol. The reagent is [PtCl,12- which is capable of bin- same reaction can be carried out more ding to methionine, histidine and cysteine economically with hydrogen peroxide using Platinum Metals Rev., 1988, 32, (4) 173 osmium tetroxide as a catalyst. The procedure on a-lytic protease and lysozyme can be used to finds commercial use in small scale prepara- determine inter-residue distances (I 5.5 and tions of scarce materials. Osmium tetroxide is 11.8& respectively) (32). At about the same highly toxic however, and particularly hazar- time the preparation and characterisation of a , dous to the eyes because of its ready reaction (NH,) Ru(II1) to histidine-33 derivative of with organic matter to give a black oxide, a pro- horse cytochrome c was reported (33). This perty which is utilised in its application as a f=- type of attachment to electron transport ative and stain in electron microscopy. This is metalloproteins has now been carried out in a probably due to its ability to react with un- number of cases in order to explore fued saturated fatty acid side chains of lipids (24). distance (crystallographically defined for the Binding of [OsO, 1 * - to cis diols has been used unmodified protein) electron transfer from the in the X-ray analysis of t-RNA where binding attached ruthenium (as Ru(II)), to the active L: is most likely to the 3'-ribose, [ii] (28). ; site in its oxidised form, heme Fe(II1) in the 1:: - case of cytochrome c (34). A feature of all these , studies is the special affinity of (NH ) Ru for + K~OSOL >OSQ histidine in preference to other amino acid Iiil residues. A procedure for detecting genetic changes in Relevant to these studies is the earlier Taube new strains of viruses has recently been work, and the observation that both Ru(I1) and reported using hydroxylamine and osmium Ru(II1) are inert to substitution. Modification tetroxide (29). is carried out using a -50-fold excess of Attachment of pentaammineruthenium(II1) [Ru(NH, ) H, 01 2+ [iiil , - to the N-3 position of the imidazole side chain + of a histidine residue, [hl in proteins was IRu(NH,),H,OI2+ His-Protein reported (NH,),RuHis-Protein Iiiil ,CH2CHCO$ after which the reaction is terminated by I HN-C NH; chromatographic filtration to remove excess of /1 \\ HC4,CH the ruthenium reagent. The fully oxidised form N Ru(III)Fe(III) is obtained by oxidation with [Fe(CN), 1 after which further purification 3- (by FPLC) and characterisation is carried out. NH3 [hl In order to study the intramolecular electron- by Matthews and coworkers in 1978 (30). transfer process, rapid pulse-radiolysis or flash- Earlier in the 1970s it had been shown that im- photolysis in situ reduction has to be achieved to idazole and histidine complexes readily form in generate the Ru(II)Fe(III) combination; about aqueous solution, and are extremely stable at 10 per cent reduction is appropriate. The in- neutral and acidic pHs. The first studies were tramolecular electron-transfer process [ivl, - with the ribonuclease A protein which has four histidine residues. Three derivatives each con- Ru(ll)Fe(I ll) Ru( III)Fe( II) [ivl taining a single (NH,), Ru-histidine complex can then be monitored spectrophotometrically. were synthesised and purified. It was found In the cytochrome c case protein concentrations that sensitivity of the charge-transfer spectrum are sufficiently dilute so that there is no con- of one of these derivatives to temperature and tribution from the intermolecular (bimolecular) urea-induced unfolding could be used to ex- path [vl. - plore conformational changes in the vicinity of Ru(II)Fe(lll) + Ru(lll)Fe(lll) the complex (31). It has also been shown that Ru(lll)Fe(lll) + Ru(lll)Fe(ll) Ivl fluorescent energy transfer between trypto- phans and a (NH,),Ru attached to a histidine The reduction potentials for the couples Platinum Metals Rev., 1988, 32, (4) 174 [Ru(NH,),(His)12+/’+( 0.08V)a nd cytochrome c (II)/(III) (0.26V) ensure that there is a N lHis87) positive driving force for [ivl. An interesting variation on this experiment is to attach other ligands to the ruthenium which have much more strongly oxidising couples, for example, [R~(NH,),(isn)(H,0)1~+(’o~.+em V) or [Ru(NH,),(py)(H,O)I (o.33mV), so that ,+’I+ a variation on intramolecular electron transfer [vil can be monitored. This type of study is at Fig. 1 Structural model showing selected parts and the relative orientations (with present under investigation. - edge to edge separation) of the donor and acceptor sites in ruthenium-modified Ru(lll)Fe(ll) Ru(ll)Fe(lll) [vil A. variabilis plastocyanin (Ref. 35) With hind-sight, cytochrome c(1I) with its high overall positive charge (estimated as + 8 at - pH 7) was not in fact a good choice in the first to. Plastocyanin (35) and azurin (36) each have instance for modification with a positively a single copper active site, and utilise charged complex. The time for modification Cu(II)/Cu(I) redox states. High-potential iron- s, (24-72h) is substantially longer than that re- sulphur protein (HIPIP) has a cuboidal Fe, quired for acidic negatively charged proteins. cluster which can be either Fe,S,’+”+ (37), Thus with the single copper protein plasto- while both the cytochromes c and cs5,c ontain cyanin the procedure for [iii] requires only 20 a heme Fe and have Fe(III)/Fe(II) stable states minutes in the case of the acidic plastocyanin (38, 39). It should be noted that not all proteins (charge 9-) from the green algal source have histidine residues, and that not all Scenedesmus obliquus, but requires approx- histidines are modified by ruthenium. For ex- imately 4 hours for the basic plastocyanin ample in the case of cytochrome c, His33 is (charge I+) from the blue-green algal source readily modified but His26 is not. Anabaena variabilis (35). Some care is required in defining the distance Modification of proteins by the attachment of (d) for intramolecular electron transfer from the (NH,),Ru is not trivial, and extensive Ru(I1). For the copper proteins the Cu-S (cys- characterisation of the products is required for teine) is likely to be the lead-in group, and since each new protein studied to ensure that attach- there is delocalisation between copper and ment is indeed at a histidine residue, and (if sulphur the relevant distance is to the S-atom, more than one histidine) which histidine is in- Figure I (35). Similarly there is delocalisation volved (3s ). Techniques used include Induc- at the imidazole ring of the histidine to which tively Coupled Plasma (ICP) atomic emission the ruthenium is attached, and the nearest spectroscopy to determine the metal content, point of the imidazole to the active site is con- NMR to demonstrate that the histidine C,H sidered relevant. A computer graphics proton resonance is no longer present due to the representation for P. srutzeri cytochrome c5,, is line broadening effect of paramagnetic Ru(III), illustrated in Figure 2 (39). The direct and testing with diethyl pyrocarbonate (DEPC) polypeptide link between His47 and the heme for modification of a histidine (with attendant is circuitous in the extreme, and cannot be rele- U.V. spectrophotometricc hanges) which can no vant. Electron transfer to the axially co- longer occur when ruthenium is present. There ordinated Met61 has been assumed, but is no evidence to suggest that ruthenium attach- transfer to the heme ring, which is strongly ment is at all disruptive. electron delocalised, is also possible. For Three different types of electron-transport HIPIP, Figure 3, the distance to the nearest protein have been modified and will be referred point of the Fe,S, cube, one of the ~.c,-sulphido Platinum Metals Rev., 1988, 32, (4) 175 \ His16 Fig. 2 Structural model showing selected parts and relative orienta- tions of the donor and acceptor heme and His47 (with Ru(NH~)~ attached) sites in P. stutreri cytochrome csJl. The buried pro- pionate attached to the heme at position 7 is also indicated (Ref. 39) ligands, is considered relevant (37). Of all the the outset the distance separating the Ru(I1) studies to date HIPIP is the only protein in from the metal active site, and the driving force which the modified histidine is linked directly were expected to be the prime rate determining by a short polypeptide chain to the active site factors. The results obtained clearly indicate (Cys43 is co-ordinated to the Fe,S,). The that this is not so and that biological electron through bond distance (saturated bonds!) is transfer is far from simple. It is concluded that 13A, whereas the through space distance is protein structure and the nature of the in- only 7.9A. No benefits seem to accrue from tervening polypeptide material must be impor- this type of attachment. tant. Of current interest is just how influential Distances (d) for electron transfer coinciden- any intervening aromatic residues might be. tally fall into two groups which are close to 12A Further results from this work are awaited. and 8A, respectively, and values for the ther- Sperm-whale myoglobin, an oxygen binding modynamic driving force (AEO) lie in a fairly protein, has also been used by the Gray group narrow range 180-3mmV, see the Table. At to explore factors affecting electron transfer \I p 10 I v Fig. 3 Structural model show- ing selected parts and relative orientations of the Fe,S, active site of high-potential iron- sulphur protein, which is co- ordinated by Cys43, and His42 which is ruthenium modified (Ref. 37) Met49 Platinum Metals Rev., 1988, 32, (4) 176 I A Comparison of Rate Constants for Intramolecular Electron Transfer from Ru(I1) in Ruthenium-Modified Metalloproteins Protein Site of d AE O k Reference Modification (A) (mV) (S- Cytochrome c (horse) His33 11.8 180 30, 53a 38 Azurin (P.a.) His83 11.8 240 1.9 36 Plastocyanin (So.) His59 10-12 300 <0.26 35 Plastocyanin (A.v . His59 11.9 260 <0.08 35 Cytochrome c, 5, (P.s. His47 7.9 200 13 39 HlPlP (C.V.) His42 7.9 270 1 8b 37 a Values obtained by flash photolysis and pulse radiolysis. respectively Values 1 and 13s-’ have been obtained by the Gray group for two HlPlPs modified at His42 reactivity. This protein has four surface Methods for the selective extraction of gold histidines His12, His48, His81 and His116 (all and platinum ions from an aqueous solution at at different distances 14.6-22.d from the pH>2 with cells or cell extracts of a micro- heme Fe) each of which can be ruthenium- organism (green or blue-green algae) (40) and modified. Four different singly-modified fungi (41), and subsequent elution with S- Ru(NH,), derivatives have been prepared, and donor ligands are being actively explored. This in this case a rate constant (k) against distance is the subject of a recent U.S. patent (40). (d) relationship In k versus d appears to hold. Fungi have also be used to remove precious Unlike the studies with electron transport pro- metals from dilute aqueous solutions (41). teins reorganisation energy requirements at the Finally, mention should perhaps be made active site are more significant. This is because here of the application of bacterial leaching pro- metMb has an axial H,O ligand whereas cesses in the extraction of certain metals from deoxyMb is five co-ordinate with no H,O. their ores which in the case of uranium and cop- The myoglobin intramolecular reactions are per is already being exploited commercially (@, somewhat slower therefore on this account. 43). 7liobacillus fernoxidam is for example able The successful attachment of ruthenium to to oxidise iron pyrites (FeS) to soluble Fe” proteins and various applications that have and SO:- with very beneficial results (43). resulted poses the question: if ruthenium, why The use of other closely related micro- not other metals? As far as electron transfer organisms, which are active in hot spring studies are concerned it is of crucial importance regions, in order to make available the metallic that the ruthenium stays attached (it is gold present in pyrites deposits is currently substitution-inert t,>>I min) in both the receiving attention (4). Ru(I1) and Ru(II1) oxidation states, and that This short review illustrates the wide range of the reduction potentials are of the required potential applications of platinum metal com- magnitude. Another metal which may behave pounds centering around their reactivity with a in this way is osmium, but here very little is variety of different bio-molecules. Relevant known of the (11) state solution chemistry. As areas stretch from laboratory applications to far as the other platinum metals are concerned medicine via the further development of pro- Rh(II1) and Ir(II1) are too inert to be readily at- cedures for mining and recovery. Many of the tached, and the (11) states are comparatively applications make use of specific chemical pro- rare. In the case of palladium and platinum the perties identified in the already well studied stable oxidation states (11) and (Iv) are and extensive inorganic solution chemistry of separated by two electrons. these elements. Platinum Metals Rev., 1988, 32, (4) 177 Additional abbreviations used in the text, without explanation: dppe = bis(diphenylphosphho)ethylene, EDTA = ethylenediamine tetraacetic acid, terpy = terpyridine, py = pyridine, isn = isonicotinamide, Mb = myoglobin. References I S. J. Lippard ed., “Flatbum, Gold and Other 23 G. A. Petsko, “Methods in Enzym.”, Academic Metal Chemotherapeutic Agents”, American Press, New York, 1985, 114, 147-176 Chemical Society, Symp. Series No. 209, 1983 24 T. L. Blundell and L. N. Johnson, “Protein 2 H. E. Howard-Lock and C. J. L. 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and '06 Ru have half lives of 40 days and I year, dignon and H. B. Gray, Pmc. Natl.Acad. Sci.U.S.A., 1982 . plasticiser alcohol 2-ethylhexanol, via aldol con-.
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