Coprostanol

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Coprostanol
Coprostanol
General
Systematic name 5β-cholestan-3β-ol
Other names 5β-coprostanol
coprostanol
Molecular formula C27H48O
SMILES CC(C)CCCC(C)C1CCC2C3
CCC4CC(O)CCC4(C)C3CCC12C
Molar mass 388.6756 g/mol
Appearance
CAS number [360-68-9] [1]
Properties
Density and phase xxx g/ml, solid at room temperature
Solubility in water xxx mg/l
Melting point 102°C
Boiling point xxx
Structure
MSDS External MSDS
Main hazards xxx
Flash point non-flammable
R/S statement R: xxx
S: xxx
Related Stanols 24-ethyl coprostanol
5α-cholestanol
epi-coprostanol
Except where noted otherwise, data are given for
materials in their standard state (at 25 °C, 100 kPa)
Infobox disclaimer and references

5β-Coprostanol (5β-cholestan-3β-ol) is a 27 carbon stanol formed from the biohydrogenation of cholesterol (cholest-5en-3β-ol) in the gut of most higher animals and birds. This compound has frequently been used as a biomarker for the presence of human faecal matter in the environment.

Contents

[edit] Chemical Properties

[edit] Solubility

5β-coprostanol has a low water solubility and consequently a high octanol – water partition coefficient (log Kow = 8.82). This means that in most environmental systems, 5β-coprostanol will be associated with the solid phase.

[edit] Degradation

In anaerobic sediments and soils, 5β-coprostanol is stable for many hundreds of years enabling it to be used as an indicator of past faecal discharges.

[edit] Chemical Analysis

Since the molecule has a hydroxyl (-OH) group, it is frequently bound to other lipids including fatty acids; most analytical methods, therefore, utilise a strong alkali (KOH or NaOH) to saponify the ester linkages. Typical extraction solvents include 6% KOH in methanol. The free sterols and stanols are then separated from the polar lipids by partitioning into a less polar solvent (e.g. hexane). Prior to analysis, the hydroxyl group is frequently derivatised with BSTFA (bis-trimethyl silyl trifluoroacetamide) to replace the hydrogen with the less exchangeable trimethylsilyl (TMS) group. Instrumental analysis is frequently conducted on Gas Chromatograph (GC) with either a Flame Ionisation Detector (FID) or Mass Spectrometer (MS). The mass spectrum for 5β-coprostanol - TMS ether can be seen in the Figure.
Mass fragmentation pattern for 5β-coprostanol at 70eV on a Fisons MD800 mass spectrometer

[edit] Isomers

As well as the faecally derived stanol, two other isomers can be identified in the environment; 5α-cholestanol (5α-cholestan-3β-ol) and epi-coprostanol (5β-cholestan-3α-ol).

[edit] Formation and Occurrence

[edit] Faecal Sources

5β-coprostanol is formed in the hind? gut of most higher animals by intestinal bacteria. The general scheme for its production via a ketone intermediate can be seen in the Figure proposed by Grimalt et al., 1990.

Proposed pathway for the formation of reduced forms of cholesterol

A list of the animals in which 5β-coprostanol has been identified in the faecal matter.
Animals Producing Coprostanol Animals NOT Producing Coprostanol
Humans dogs
Cattle ?
Sheep ?
Birds ?


There a small number of animals, however, that have been shown NOT to produce 5β-coprostanol and these can be seen in the Table.

[edit] Non-Faecal Sources

Some Phytoplankton?

[edit] Use as a Tracer for Sewage

The principal source of 5β-coprostanol in the environment is from human wastes. The concentration of 5β-coprostanol in raw, untreated sewage is around 2-6% of the dry solids. This relatively high concentration and its stability allows it to be used in the assessment of the faecal matter in samples, especially sediments.

[edit] 5β-Coprostanol / Cholesterol Ratio

Since 5β-coprostanol is formed from cholesterol in the vertebrate gut, the ratio of the product over reactant can be used to indicate the degree of faecal matter in samples. Raw untreated sewage typically has a 5β-coprostanol / cholesterol ratio of ~10 which decreases through a sewage treatment plant (STP) such that in the discharged liquid wastewaters the ratio is ~2. Undiluted STP wastewaters may be identified by this high ratio. As the faecal matter is dispersed in the environment, the ratio will decrease as more (non-faecal) cholesterol from animals is encountered. Grimalt & Albaiges have suggested that samples with a 5β-coprostanol / cholesterol greater than 0.2 may be considered as contaminated by faecal material.

[edit] 5β-Coprostanol / (5β-Coprostanol + 5α-Cholestanol) Ratio

Another measure of human faecal contamination is the proportion of the two 3β-ol isomers in the 5β form. 5α-Cholestanol is formed naturally in the environment by bacteria and generally does not have a faecal origin. Samples with ratios greater than 0.7 may be contaminated with human faecal matter; samples with values less than 0.3 may be considered uncontaminated. Samples with ratios between these two cut-offs can not readily be categorised on the basis of this ratio alone.
Two measures of faecal contamination in sediments from the Ria Formosa, Portugal.

Sediments falling in the red region are classed as “contaminated” by both of the two ratios and those in the green region are classified as “uncontaminated” by the same measures. Those in the blue region are “uncontaminated” according to the 5β-coprostanol / cholesterol ratio and “uncertain” in the 5β-Coprostanol / (5β-Coprostanol + 5α-Cholestanol) ratio. The majority of the samples between the 0.3 and 0.7 cut-offs are considered as “uncontaminated” according to the 5β-coprostanol / cholesterol ratio and so the 0.3 value must be considered as somewhat conservative.

[edit] 5β-Coprostanol / Total Sterols Ratio

Cut-off values etc.

[edit] 5β-Coprostanol / 24-Ethyl Coprostanol

Herbivores such as cows and sheep consume terrestrial plant matter (grass) which contains β-sitosterol as the principal sterol. β-Sitosterol is the 24-ethyl derivative of cholesterol and can be used as a biomarker for terrestrial plant matter (see Section). In the gut of these animals, bacteria biohydrogenate the double bond in the 5 position to create 24-ethyl coprostanol and so this compound can be used as a biomarker for faecal matter from herbivores. Typical values in different source materials can be seen in the Table after Gilpin.

Source 5β-cop / 24-ethyl cop
Septic tanks 2.9 – 3.7
Community wastewater 2.6 – 4.1
Abattoir – sheep, cattle 0.5 – 0.9
Dairy shed wash-down 0.2

[edit] Epi-Coprostanol / 5β-Coprostanol

During sewage treatment, 5β-coprostanol may be converted to 5β-cholestan-3α-ol form, epi-coprostanol. There is also a slow conversion of 5β-coprostanol to epi-coprostanol in the environment and so this ratio will indicate either the degree of treatment of sewage or its age in the environment. A cross-plot of the 5β-coprostanol / cholesterol ratio with the epi-coprostanol / 5β-coprostanol can indicate both faecal contamination and treatment.

[edit] Related Markers

[edit] 5α-Cholestanol / Cholesterol

In the environment, bacteria preferentially produce 5α-cholestan-3β-ol (5α-cholestanol) from cholesterol rather than the 5β isomer. This reaction occurs principally in anaerobic reducing sediments and the 5α-cholestanol / cholesterol ratio may be used as a secondary (process) biomarker for such conditions. No cut-off values have been suggested for this marker and so it is used in a relative sense; the greater the ratio, the more reducing the environment. Reducing environments are frequently associated with areas experiencing high organic matter input; this may include sewage derived discharges. The relationship between reducing conditions and the potential source can be seen in a cross plot with a sewage indicator.

It may be suggested from this relationship that sewage discharges are in part responsible for the anaerobic reducing conditions in the sediments.

[edit] Further reading

Mudge, S.M. & Ball, A.S. (2006) Sewage In: Environmental Forensics: A Contaminant Specific Approach Eds. Morrison, R. and Murphy, B. Elsevier, pp533.


[edit] External links