Mark J. McKeage

Role of lipophilicity in determining cellular uptake and antitumour activity of gold phosphine complexes

Purpose: The lipophilic cation [Au(I)(dppe)2]+ [where dppe is 1,2-bis(diphenylphosphino)ethane] has previously demonstrated potent in vitro antitumour activity. We wished to determine the physicochemical basis for the cellular uptake of this drug, as well as of analogues including the 1:2 adducts of Au(I) with 1,2-bis(di-n-pyridylphosphino)ethane (dnpype; n=2, 3 and 4), and to compare in vitro and in vivo antitumour activity. Methods and results: Logarithmic IC50 values for the CH-1 cell line bore a parabolic dependence on drug lipophilicity, as measured either by high-performance liquid chromatography or by n-octanol-water partition. Cellular uptake of drug, as measured by inductively coupled plasma mass spectrometry, varied by over three orders of magnitude over the series. Logarithmic uptake had a parabolic dependence on drug lipophilicity but a linear relationship to logarithmic IC50 values. Free drug concentrations were determined under the culture conditions and logarithmic free drug IC50 values and uptake rates were linearly related to lipophilicity. Uptake of drug in vivo in tissue from murine colon 38 tumours was approximately proportional to the dose administered. Host toxicity varied according to lipophilicity with the most selective compound having an intermediate value. This compound was also the most active of those tested in vivo, giving a growth delay of 9 days following daily intraperitoneal dosing (10 days) at 4 μmol kg−1 day−1. It was also significantly more active than another lipophilic cation, MKT-077. Conclusions: Alteration of lipophilicity of aromatic cationic antitumour drugs greatly affects cellular uptake and binding to plasma proteins. Changes in lipophilicity also affect host toxicity, and optimal lipophilicity may be a critical factor in the design of analogues with high antitumour activity.

Relationships between hydrophobicity, reactivity, accumulation and peripheral nerve toxicity of a series of platinum drugs

Previous work has shown platinum drugs to differ in their effects on the peripheral nervous system. To test whether their differential toxicity was due to differences in their partitioning into the peripheral nervous system, we correlated the hydrophobicity, reactivity, tissue accumulation and neurotoxicity of a series of eight platinum analogues. Neurotoxicity was detected by measuring sensory nerve conduction velocity (SNCV) in Wistar rats treated twice per week at the maximum tolerated dose. Tissue platinum concentrations were measured by inductively coupled plasma mass spectrometry. Hydrophobicity (log P) was measured using an octanol-aqueous shake-flask method. The half-life of platinum drug binding to plasma proteins in vitro was determined. The cumulative dose causing altered SNCV ranged from 15 to > 2050 μmol kg–1. Ranking of the compounds by their neurotoxic potency in rats (oxaliplatin >R,R -(DACH)PtC4> ormaplatin >S,S -(DACH)PtCl4>S,S -(DACH)Pt oxalato > cisplatin > carboplatin > JM216) correlated with the frequency of neurotoxicity in patients (r> 0.99;P< 0.05). Ranking the compounds by their peripheral nerve accumulation was cisplatin > carboplatin > oxaliplatin >R,R -(DACH)PtCl4≈S,S -(DACH)PtCl4and did not correlate with neurotoxicity. Log P ranged from – 2.53 to –0.16 but did not correlate with neurotoxicity. Log P correlated inversely with platinum accumulation in dorsal root ganglia (r2= 0.99;P = 0.04), sural nerve (r2= 0.85;P = 0.025), sciatic nerve (r2= 0.98;P = 0.0012), spinal cord (r2= 0.97, P = 0.018) and brain (r2= 0.98, P = 0.001). Reactivity correlated with neurotoxicity potency in rats (r2= 0.89, P = 0.0005) and with the frequency of neurotoxicity in patients (r2= 0.99, P = 0.0002). The hydrophilicity of platinum drugs correlates with platinum sequestration in the peripheral nervous system but not with neurotoxicity. Differences in the reactivity of platinum complexes accounts for some of the variation in their neurotoxicity.

Nucleolar damage correlates with neurotoxicity induced by different platinum drugs.

Platinum-based drugs are very useful in cancer therapy but are associated with neurotoxicity in the clinic. To investigate the mechanism of neurotoxicity, dorsal root ganglia of rats treated with various platinum drugs were studied. Cell body, nuclear and nucleolar dimensions of dorsal root ganglia sensory nerve cells were measured to determine morphological toxicity. Sensory nerve conduction velocity was measured to determine functional toxicity. After a single dose of oxaliplatin (10 mg kg–1), no significant change in nuclear and cell body diameter was seen but decreased nucleolar size was apparent within a few hours of treatment. Changes in nucleolar size were maximal at 24 hours, recovered very slowly and showed a non-linear dependence on oxaliplatin dose (r2= 0.99). Functional toxicity was delayed in onset until 14 days after a single dose of oxaliplatin but eventually recovered 3 months after treatment. Multiple doses of cisplatin, carboplatin, oxaliplatin, R, R -ormaplatin and S, S -ormaplatin were also associated with time-dependent reduction in nucleolar size. A linear correlation was obtained between the rate of change in nucleolar size during multiple dose treatment with the series of platinum drugs and the time taken for the development of altered sensory nerve conduction velocity (r2= 0.86;P< 0.024). Damage to the nucleolus of ganglionic sensory neurons is therefore linked to the neurotoxicity of platinum-based drugs, possibly through mechanisms resulting in the inhibition of rRNA synthesis.

Lobaplatin: a new antitumour platinum drug.

Lobaplatin (D-19466) is a diastereometric mixture of platinum(II) complexes containing a 1,2-bis(aminomethyl)cyclobutane stable ligand and lactic acid as the leaving group. Its antitumour activity results from the formation of DNA-drug adducts, mainly as GG and AG intra-strand cross-links. Lobaplatin influences the expression of the c-myc gene, which is involved in oncogenesis, apoptosis and cell proliferation. Lobaplatin has activity in a wide range of preclinical tumour models and appears to overcome tumour resistance to cisplatin and carboplatin in some of these models. In the body, lobaplatin remains largely intact until removed by glomerular filtration. Exposure of the body to lobaplatin (AUC) correlates with dose, creatinine clearance and the degree of thrombocytopoenia. Phase I clinical trials of three quite different administration schedules found the same dose-limiting toxicity (thrombocytopoenia) and similar maximum tolerated doses (60 mg/m2 per 3 - 4 weeks). In Phase II trials, lobaplatin showed activity in patients with a variety of tumour types. Many of the patients who responded to lobaplatin may also have responded to cisplatin and carboplatin because they had had no prior chemotherapy or had a prolonged remission after earlier treatment. In conclusion, lobaplatin is a new platinum drug, which overcomes some forms of cisplatin resistance in preclinical tumour models. Several potential clinical applications remain unexplored, such as its use in relapsed testicular cancer and in combination with other cancer chemotherapeutic agents and ionising radiation.

Stereoselective peripheral sensory neurotoxicity of diaminocyclohexane platinum enantiomers related to ormaplatin and oxaliplatin

The diaminocyclohexane platinum (Pt(DACH)) derivatives ormaplatin and oxaliplatin have caused severe and dose-limiting peripheral sensory neurotoxicity in a clinical trial. We hypothesized that this toxicity could vary in relation to the biotransformation and stereochemistry of these Pt(DACH) derivatives. We prepared pure R,R and S,S enantiomers of ormaplatin (Pt(DACH)Cl4), oxaliplatin (Pt(DACH)oxalato) and their metabolites (Pt(DACH)Cl2 and Pt(DACH)methionine) and assessed their peripheral sensory neurotoxicity and tissue distribution in the rat and in vitro anti-tumour activity in human ovarian carcinoma cell lines. The R,R enantiomers of Pt(DACH)Cl4, Pt(DACH)oxalato and Pt(DACH)Cl2, induced peripheral sensory neurotoxicity at significantly lower cumulative doses (18 +/- 5.7 vs 32 +/- 2.3 micromol kg(-1); P < 0.01) and at earlier times (4 +/- 1 vs 6.7 +/- 0.6 weeks; P = 0.016) during repeat-dose treatment than the S,S enantiomers. Pt(DACH)methionine enantiomers showed no biological activity. There was no difference between Pt(DACH) enantiomers in the platinum concentration in sciatic nerve, dorsal root ganglia, spinal cord, brain or blood at the end of each experiment. Three human ovarian carcinoma cell lines (41 M, 41 McisR and SKOV-3) showed no (or inconsistent) chiral discrimination in their sensitivity to Pt(DACH) enantiomers, whereas two cell lines (CH-1 and CH-1cisR) showed modest enantiomeric selectivity favouring the R,R isomer (more active). In conclusion, Pt(DACH) derivatives exhibit enantiomeric-selective peripheral sensory neurotoxicity during repeated dosing in rats favouring S,S isomers (less neurotoxic). They exhibited less chiral discrimination in their accumulation within peripheral nerves and in vitro anti-tumour activity.

Paclitaxel induces nucleolar enlargement in dorsal root ganglion neurons in vivo reducing oxaliplatin toxicity

Paclitaxel and oxaliplatin are promising drugs for combination trials but both induce peripheral neurotoxicity. To investigate this toxicity, 10-week-old female Wistar rats were given single intraperitoneal doses of paclitaxel and oxaliplatin, alone or in combination. Neurotoxicity was assessed by L5 dorsal root ganglion morphometry and H-reflex-related sensory nerve conduction velocity. Platinum concentrations in dorsal root ganglia and plasma were measured by inductively coupled plasma mass spectrometry. Dorsal root ganglion nucleolus size was significantly increased following single doses of paclitaxel of 10 and 20 mg kg−1 at 24 h and 6 days (P<0.02). In contrast, dorsal root ganglion nucleolus size was significantly decreased following single doses of oxaliplatin ranging from 3 to 30 mg kg−1 at time points ranging from 2 h to 14 days. Sensory nerve conduction velocity was altered after a single dose of oxaliplatin but not after paclitaxel. In combination with oxaliplatin, paclitaxel did not alter the plasma pharmacokinetics or dorsal root ganglion accumulation of oxaliplatin-derived platinum. However, prior paclitaxel inhibited oxaliplatin-induced reductions of dorsal root ganglion nucleolar diameter (P<0.02). Sensory nerve conduction velocity was reduced after oxaliplatin alone (P<0.05) but unchanged when paclitaxel was given before oxaliplatin. In conclusion, paclitaxel induces nucleolar enlargement in dorsal root ganglion neurons after pharmacologically relevant doses in vivo and reduces oxaliplatin nucleolar damage and neurotoxicity.

Neuroprotective Interactions In Rats Between Paclitaxel And Cisplatin

Paclitaxel and cisplatin are associated with dose-limiting neurotoxicity that may result from their differing effects on microtubule stability in peripheral nerves. We hypothesized that such different actions of paclitaxel and cisplatin could be exploited to minimize their neurotoxicity by giving them in combination. Paclitaxel (9-18 micromol/kg/week or 7.7-15.4 mg/kg/week) and cisplatin (5-10 micromol/kg/week or 1.5-3 mg/kg/week) were given alone and in combination to female Wistar rats. Treatment was given once per week for a total of 7-10 weeks. Paclitaxel and cisplatin were given 24 h apart when they were given in combination. Changes in sensory nerve conduction velocity (SNCV) and dorsal root ganglia (DRG) morphology were measured. The nature of their interaction was analyzed using an isobologram. Their antitumor activity alone or in combination was also determined in C57B1/6 mice bearing colon 38 tumors. Reductions in SNCV occurred with paclitaxel alone (P = 0.009), cisplatin alone (P = 0.012), and cisplatin given 24 h before paclitaxel (P < 0.0001). In contrast, there was no significant change in SNCV with paclitaxel given 24 h before cisplatin (P = 0.11). An isobologram showed that the SNCV effects of the drug combinations were less than additive or antagonistic. Cisplatin-induced morphometric changes in DRG neurons were less marked when cisplatin was given with paclitaxel (P = 0.004). Concentrations of platinum in dorsal root ganglia, sural nerves, and sciatic nerves were not altered by giving paclitaxel before cisplatin. Tumor growth delays (TGD) were greater after treatment with paclitaxel (23.4 micromol/kg or 20 mg/kg) given 24 h before cisplatin (23.3 micromol/kg or 7 mg/kg) (TGD = 7.5 days) than after paclitaxel (23.4 micromol/kg or 20 mg/kg) (TGD = 2.0 days) or cisplatin (23.3 micromol/kg or 7 mg/kg) (TGD = 3.5 days) alone. Paclitaxel and cisplatin antagonized each others neurotoxicity in Wistar rats. Combining cytotoxic agents with opposing effects on peripheral nerves has potential for minimizing neurotoxicity in patients.