Reaction mass of 4,4'-isopropylidenediphenol and phenol

Impact of new information and summary of toxicokinetics:

"The new information on the toxicokinetics of BPA in humans and in pregnant and nonpregnant

rodents of different ages provides an important contribution to our knowledge of the

kinetic properties of BPA. However, the most significant impact of the new information for

risk assessment purposes arises from the studies in humans. These studies have demonstrated

that at comparable exposure levels the blood concentrations of free BPA in humans are much

lower than those in rodents, indicating that there are important quantitative differences in the

fate of BPA between humans and rodents.

The toxicokinetics of BPA have been well studied in rats both in vivo and in vitro, and have

been investigated to a lesser extent in mice and cynomolgus monkeys. Two studies have

investigated the toxicokinetics and fate of an oral dose of labelled BPA in human volunteers.

Absorption

In the species studied (rats, mice, monkeys, humans), the available evidence suggests that

following oral administration, BPA is rapidly and extensively absorbed from the

gastrointestinal tract. Analysis of plasma AUC values suggests that the extent of absorption

from the GI tract is up to 86% in rats and up to 85% in monkeys. The only relevant human

studies suggest that, on the basis of the recovery of labelled BPA-glucuronide from the urine,

a relatively low dose of BPA (54-88 μg/kg) was completely absorbed after oral dosing.

An in vitro dermal absorption study using human skin found limited absorption of BPA at

millimolar concentrations; the extent of absorption was in the region of 10% of the applied

dose.

There are no data on the toxicokinetics of BPA following inhalation exposure. However, on

the basis of the observed absolute organ weight changes in a repeat inhalation study and the

high partition coefficient, it would be prudent to assume that absorption via the inhalation

route can occur, but the data do not allow a quantitative estimation of absorption to be made.

Furthermore, because first-pass metabolism would not take place following exposure by this

route, or by the dermal route, the systemic bioavailability is likely to be substantially greater

for these routes than is associated with the oral route.

For the purposes of risk characterisation, absorption via the oral and inhalation routes will be

assumed to be 100%; dermal absorption will be taken to be 10%.

Metabolism

The available data indicate that BPA is subject to extensive first-pass metabolism following

absorption from the gastrointestinal tract.

In all species studied, the major metabolic pathway involves conjugation of BPA to BPAglucuronide.

Studies conducted in rats suggest that in neonates the glucuronidation pathway

is more susceptible to saturation than in adults indicating an age-dependent increase in

metabolic capacity. In vitro studies with microsomal preparations also suggest species

differences, with the rank order for the metabolic clearance rate per unit weight of tissue

being mice > rats > humans. When the total clearance rates for the whole liver were

calculated, the rank order was reversed (humans > rats > mice).

In addition to the glucuronidation pathway, in vivo and in vitro studies suggest that in the rat,

BPA may be subject to limited oxididation to bisphenol O-quinone by cytochrome P450, and

also to conjugation to BPA-sulphate and 5-hydroxy-BPA.

A study in pregnant mice given subcutaneous doses of BPA also found that glucuronidation

was the major pathway for the metabolism of BPA, although dehydrated, sulphated and

methoxylated conjugates of BPA were also produced. Some minor metabolites were double

conjugates, such as a double conjugate of BPA with glucuronide and N-acetyl galactosamine

which was found in the intestine, placenta, amniotic fluid and foetal tissue. A study in

cynomolgus monkeys showed that BPA-glucuronide was the major metabolite, although

there was evidence for production of a minor metabolite, possibly BPA-sulphate or 5-

hydroxy-BPA. Studies conducted in humans provide evidence for the glucuronidation of

BPA in man; some studies also found evidence for the sulphation of BPA.

Distribution

Most studies investigating the distribution of BPA measured tissue radioactivity levels after

giving labelled BPA to experimental animals. An oral dosing study in rats found that the

tissue concentrations of BPA-derived-radioactivity were highest in the liver, kidney and

carcass, and lowest in the brain and testes, and there were no large differences between adult

and neonatal animals. A number of studies in rats suggest that BPA metabolites and

especially free BPA have a limited distribution to the embryo/foetal or placental

compartments following oral administration. No selective affinity of either yolk sac/placenta

or embryo/foetus for BPA or BPA metabolites relative to maternal plasma or tissues was

observed in a recent study in rats after oral dosing. However, maternal and embryo/foetal

exposure to free BPA did occur, but systemic levels were found to be low due to extensive

first-pass metabolism.

Regarding the distribution of free, unconjugated BPA to tissues after oral dosing, since free

BPA is removed rapidly from the blood after absorption by first pass metabolism, it has been

suggested that in animals the availability of free BPA to extrahepatic tissues is likely to be

limited following oral exposure. In adult rats it has been estimated that no more than 5-10%

of the administered dose of free BPA is available to the tissues, although this figure may be

higher in neonates. In humans, the systemic availability of free BPA is very low as

enterohepatic recirculation of BPA does not occur.

In summary, there are differences between humans and rodents in the distribution of BPA.

After oral administration, BPA is rapidly metabolised in the gut wall and the liver to BPAglucuronide.

This metabolite is devoid of endocrine activity. In humans, the glucuronide is

released from the liver into the systemic circulation and cleared by urinary excretion. Due to

the rapid biotransformation and excretion (t1/2 = 5 hours) and plasma protein binding, peak

free BPA concentrations in humans after oral exposure that are available for estrogen

receptor binding are very low. In contrast, BPA glucuronide is eliminated in bile in rodents

and undergoes enterohepatic recirculation after cleavage to BPA and glucuronic acid by

glucuronidase in the intestinal tract. The enterohepatic recirculation results in slow excretion

(t1/2 = 15-22 hours) and increased systemic availability of free BPA in rodents.

This conclusion is supported by the observation that in urine of rats dosed orally with BPA, a

part of the dose was excreted as free BPA in urine (1 -4 % of applied dose, whereas BPAglucuronide

in urine accounted for 20-40 % of applied dose). In both of the human studies

and the monkey study free BPA was below the limit of detection in all urine and blood

samples (equivalent to a ratio of free BPA to BPA-glucuronide of < 0.5 %). Since free BPA

found in urine is translocated from blood to urine in the kidney, these observations of higher

free BPA levels in urine of rats compared with primates further support the existence of

species differences in blood levels of free BPA between rodents and humans with higher

AUCs for free BPA in rats.

Excretion

The major route of elimination in the rat is via the faeces. The available data indicate that the

percentage of the administered dose recovered in the faeces is in the range 50% to 83%.

Urinary excretion is of secondary importance in the rat, with 13% to 42% of the administered

dose being recovered in the urine. Over 7 days post-dosing approximately 80% and 70% of

the administered dose was eliminated in the faeces in males and females, respectively.

Elimination was rapid; the majority of the dose was excreted by 72 hours post-dosing. A sex

difference was also observed for urinary elimination, with females excreting approximately

twice as much radioactivity (24-28%) than males (14-16%). A study in female SD rats found

that excretion was not affected by pregnancy at 3 different stages of gestation. Data from a

number of studies suggest limited excretion of BPA in the milk. However, the data do not

allow a reliable quantitative determination to be made.

Following oral administration to rats, a high proportion of the administered dose (45-66%)

was rapidly excreted in the bile in the form of BPA-glucuronide, with the rate of biliary

excretion tending to be higher in males than females. Most of the faecal radioactivity was

found to be in the form of free BPA. Since BPA has a high oral bioavailability in the rat, the

free BPA found in the faeces is more likely to be derived from BPA-glucuronide excreted in

the bile and hydrolysed to free BPA in the gastrointestinal tract rather than representing

unabsorbed BPA which might have passed along the gastrointestinal tract into the faeces

unchanged. Most of the urinary radioactivity was found to be in the form of BPA-glucuronide

(82%) with free BPA and BPA-sulphate making minor contributions (14% and 4%

respectively).

In contrast to the findings in rodents, in cynomolgus monkeys given BPA orally most of the

administered dose (82–85%) was recovered in the urine, with only 2-3% of the dose being

recovered in the faeces. In two studies in human volunteers given a low dose of BPA orally,

the administered dose was completely recovered in the urine as BPA-glucuronide. No free

BPA was detected and no gender differences in the kinetics of BPA-glucuronide in plasma

and urine were reported.

The study is comparable to OECD Guideline 417 with acceptable restrictions (different routes of exposure but only one dose level studied; partly limited documentation, e.g. fasting period; expiration not measured [minor restriction, no main route of elimination]).

Female F344 rats (n=3 -4 per group) received 0.03 mg/kg bw 14C-labelled phenol via oral, dermal, intratracheal, or i.v. administration. Radioactivity in urine and feaces was analysed after sampling in metabolism cages; the animals were sacrificed 72 h after application and radioactivity in organs, carcass and washings determined. Rapid and complete absorption of the administered radioactivity was found after oral and intratracheal exposure: 70-85% of the recovered dose was excreted in urine 4h after administration and urinary elimination was essentially complete by 12 h, after 72 h totally 95% of the applied dose were excreted via urine and only 1 -3% were excreted via faeces. Slightly reduced absorption rates were detected after dermal application: total amount of applied radioactivity excreted via urine was 75%, 3% were measured in faeces, 14% in skin washing at 72 h, 2% in the treated skin, and 2.5% in plastic blisters. The total dermal absorption rate was ca. 80% of the applied dose. Independent on the route of exposure low amounts (1 -5% of the recovered dose) retained in the rat 72 h after application. Phenol was distributed throughout the body. At a dose level of 0.033 mg/kg bw phenol was metabolized in rats to the sulphate (main metabolite) and glucuronide conjugates after absorption from the four routes of exposure.

The study meets scientific standards with acceptable restrictions (partly limited documentation; low number of animals per studied species).

Three volunteers ingested a single dose of 0.01 mg 14C-labelled phenol/kg bw and 17 mammalian species plus chicken received orally the labelled phenol at dose levels between 20 and 50 mg/kg bw. Metabolites were determined in 24h-urine by radiochromatogram scanning. Four peaks which corresponded to phenylsulphate, phenylglucuronide, hydroquinone (quinol) monosulphate and hydroquinone monoglucuronide were detected. Catechol conjugates did not appear to be formed in sufficient quantities. In three men 90% of an oral dose was excreted in 24 h mainly as phenylsulphate (77% of 24 h excretion) and phenylglucuronide (16%) with very small amounts of hydroquinone sulphate and glucuronide. The above four metabolites of phenol were also detected in the urine of the following species: rat, mouse, jerboa, gerbil, hamster, lemming, and guinea pig. Three metabolites were excreted by some species, namely, phenol and quinol glucuronides and phenylsulphate by the squirrel monkey and capuchin monkey, and phenol and quinol sulphates and phenylglucuronide by the ferret, dog, hedgehog and rabbit. Only 2 metabolites were excreted by the rhesus monkey, fruit bat and hen (phenylsulphate and phenylglucuronide) and by the cat (phenylsulphate and quinol sulphate). One metabolite (phenylglucuronide) only was excreted by the pig.

In humans 90% (range 85 -98) of the applied dose was excreted via the 24 h-urine indicating nearly complete oral absorption. Similar results were obtained with rats. Furthermore, the amount of specified metabolites excreted are very similar in rats and humans.

Conclusion: Significant species differences in metabolism of phenol has been shown. Humans and rats showed similar metabolic pathways and quantities of metabolites in urine. Comparing 18 different mammalian species including humans highest absorption rates were found in humans and rats after oral application. The rat is likely a good surrogate for human metabolism of phenol.