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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 54, 2016 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Selena Sironi, Laura Capelli 
Copyright © 2016, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-45-7; ISSN 2283-9216 

Comparison of the Biodegradation of Trimethylamine by 
Hyphomicrobium vulgare and Aminobacter aminovorans  

Alberto Aguirre, Manuel Cáceres, Ricardo San Martín, Juan Carlos Gentina, 
Germán Aroca* 
 
School of Biochemcial Engineering, Faculty of Engineering, P. Universidad Católica de Valparaíso. Av. Brasil 2085, 
Valparaíso, 2362803, CHILE. 
german.aroca@pucv.cl 

 
Trimethylamine (TMA) is the main responsible for the odor often associated with rotting fish and is one of the 
major sources of annoying odors generated in many industrial activities, like composting facilities, fish-meal 
manufacturing plants, wastewater treatment plants, landfills and livestock farms. Traditionally amines can be 
removed by acid scrubbers that require the continuous supply of acid and generates large amounts of 
wastewater. Biofiltration has been proved to be an effective and sustainable technology treating many odorous 
compounds but the efficient removal of TMA using biofilters has not been completely shown. There are 
different microorganisms with the ability to use TMA as nutrient for their growth and presents different rates of 
TMA bio-degradation and biomass yields. Between those Hyphomicrobium vulgare and Aminobacter 
aminovorans are two bacteria known for their capability to use TMA as carbon and energy source.  
In order to select one of these bacteria as inoculum for biofilters, TMA bio-degradation capacity of both 
bacteria was determinated in batch cultures. Each bacterium was cultivated at 30°C and 200 rpm in 125 ml 
shake flasks with a minimum mineral medium and TMA as source of carbon. To determine the effect of H2S 
on the biodegradation of TMA, H2S was added in the headspace of the flasks, the experiments were 
performed using 0, 20 and 70 ppm of H2S as initial concentration in headspace. 
The maximum biomass concentration obtained during the cultures was 1.17 g L-1 for Hyphomicrobium and 
0.44 g L-1 for A. aminovorans, it growth at a maximum specific growth rate of 0.15 h-1, higher than the obtained 
for Hyphomicrobium; 0.09 h-1. The biomass yield for TMA was 0.35 (g g-1) for Hyphomicrobium and 0.10 (g g-
1) for A. aminovorans.  The specific consumption rate was 0.47 h-1 in the culture of A. aminovorans and 0.12 h-
1 in the culture of Hyphomicrobium. Although A. aminovorans shows higher TMA specific consumption rate 
than Hyphomicrobium, its biomass yield value (0.1 g g-1) indicates that in the case of A. aminovorans the 
carbon from TMA was metabolized to other products like carbon dioxide, formaldehyde or formate in detriment 
of biomass production. The biodegradation of TMA by A. aminovorans is negatively affected by H2S, 
meanwhile in the case of Hyphomicrobium sp. the specific rate of biodegradation of TMA is positively 
influenced by the presence of H2S, making it even higher than the one obtained for A aminovorans without the 
presence of H2S. In conclusion, due to its specific growth rate and TMA specific consume rate Aminobacter 
aminovorans is a suitable candidate to be used as inoculum for biofilters designed for removing gas emissions 
containing TMA when there is not H2S in the mixture. However, if H2S is present, Hyphomicrobium vulgare 
would be the best choice for the inoculum or being part of the inoculum of the biofilter. 

1. Introduction 
Volatile amines are one of the main responsible of odour nuisances in many industrial activities, usually they 
are generated by the decay or biological degradation of organic material. In particular, trimethylamine (TMA) 
(CH3)3N, is the main responsible for the odor often associated with rotting fish and is one of the major sources 
of annoying odors generated in many industrial activities like fish-meal manufacturing processes [Sandberg 
and Ahring, 1992, Hwang et al 1994, Kim et al., 2001], wastewater treatment plants (Shieh and Keenan, 
1986), waste disposal landfills, livestock farming, and hog manure [Shieh and Keenan 1986, Leson and Winer, 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1654051

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Aguirre A., Cáceres M., San Martin R., Gentina J.C., Aroca G., 2016, Comparision of the bio-degradation of 
trimethylamine by hyphomicrobium vulgare and aminobacter aminovorans, Chemical Engineering Transactions, 54, 301-306   
DOI: 10.3303/CET1654051 

301



1991; Cao et al., 1997; Chang et al., 2004, Ho et al, 2008]. The source of TMA is not fully established, but 
there is evidence that it is produced by the activity of microorganisms on choline, betaine or trimethylamine N-
oxide (López-Caballero et al., 2001). The reported TMA odour threshold is in the range of; 0.2 – 0.4 μg·m−3 
(Yaws et al, 2001) while characteristic concentrations of TMA emitted in such discharges ranged in 5–100 
ppm (Shieh and Keenan,1986; Hodge and Devinny, 1994). Dimethylamine (DMA) and methylamine (MA) are 
catabolic products of trimethylamine breakdown catalyzed by microorganisms, therefore they may be also 
present in the streams containing TMA  (Rappert and Muller, 2005). 
In the last decade there has been also an increased concern related to the presence of amines in gaseous 
emmisions due to their toxic effects on human health due to its potentially toxic and carcinogenic effects (Xue 
et al. 2013). The cost of using physico-chemical operations for depleting their presence in gaseous streams 
and the potential adverse effects resulting from the presence of residually persistent unknown by-products in 
the treated stream, have made that biological systems have been preferentially adopted (Liffourrena and 
Lucchesi, 2014). Under the proper conditions, high removal efficiencies can be achieved by biofiltration of the 
gaseous contaminated emission ( Kennes and Thalasso, 1989; Burgess et al, 2001). 
Biological removal of amines could be accomplished by aerobic and anaerobic microorganisms (Meiberg and 
Harder, 1978; Rappert and Muller, 2005). In aerobic conditions, TMA is oxidized to DMA and formaldehyde by 
a TMA dehydrogenasa. A second pathway for utilization of TMA is due to a TMA monooxygenase that oxidize 
TMA to TMA N-oxide that is subsequently demethylated by a TMA demethylase to DMA and formaldehyde. 
DMA is oxidized to MA and formaldehyde by a DMA monooxygenase. MA is oxidized by a MA dehydrogenase 
or by a MA oxidase to formaldehyde and ammonia, that can be used as a source of carbon and nitrogen for 
biomass formation. There are other routes proposed for the conversion of MA to formaldehyde through 
glutamate by a N-methylglutamate synthase, g-glutamylmethylamide synthetase and a N-methyl glutatmate 
dehydrogenase (Lidstrom, 2006). Thus, microbial degradation would be an efficient way of eliminating TMA 
from contaminated environments (Kim et al 2001).  
The biodegradation of TMA has been reported by several microorganisms, such as Paracoccus sp., 
Hyphomicrobium sp., Pseudomonas sp., Methylophilus sp., Arthrobacter sp., Aminobacter sp., 
Haloanaerobacter sp., Nitrosomonas sp., and Bacillus sp., which are known to readily utilize it as a sole 
carbon and energy source (Colby and Zatman, 1973; Anthony, 1975; Lobo et al., 1997; Roseiro et al, 1999, 
Kim et al, 2001; Chang et al., 2004; Liffourrena et al., 2010). Bioreactors packed with Nitrosomonas sp. have 
been used to remove TMA in wastewater, (Yang et al., 1994; Zita and Hermansson, 1994). 
There are a few reports about biofiltration of amines as individual compounds or in complex mixtures. Chang 
et al. (2004) applied an aerobic biofiltration system containing entrapped mixed microbial cells to treat TMA-
containing waste gas, the microbial cells were obtained from activated sludge for swan wastewater treatment, 
obtaining removal efficiency is higher than 90% at TMA inlet loading below 27.2 mgN·h-1, using retention time 
of 5.3 min.. TMA degradation in two three-stage biofilters packed with compost or sludge was investigated by 
Ding et al. (2007), they report the complete oxidation of TMA to NO3

- in the compost biofilter due to the 
presence of nitrifying bacteria. Chung (2007) analysed the performance of a biofilter, using compost and 
activated carbon and inoculated with activated sludge, for treating a mixture of nitrogen containing compounds 
(TMA, DMA, MA, NH3), sulphur containing compounds (H2S, (CH3)2S2, CH3SH, C2H5SH), fatty acids and 
hydrocarbons generated in a compost process unit.  The maximum removal for TMA was 95% (at a loading 
rate of 6365 gTMA·m-3·h-1) and 99% for MA (at a loading rate of 646 gMA·m-3·h-1). The removal of the other 
compounds was higher than 90%. These values are the highest removal of TMA, DMA and MM reported in 
the literature for high loading rates of these amines. Liffourrena & Lucchesi (2014) have shown that the 
immobilisation of Pseudomonas putida A in calcium alginate are capable of degrading higher concentrations 
of TMA than free cells. Recently, Wei et al (2015) have reported a TMA removal efficiency up to 99.9% in a 
Biotrickling Filter operating at thermophilic condition; 56 ºC, at a bed contact time of 25.8 s the elimination 
capacity was 375.2 gTMA·m–3·h–1.  
To decrease the accumulation of NH3 during amine biodegradation, some nitrifying microorganisms have 
been tested inside biofilters with good results. Ho et al. (2008) worked with a biofilter of granulated activated 
carbon inoculated with Paraccocus and Arthrobacter, a denitryfing bacteria, and at high loading rate (93 g 
TMA·m-3·h-1) achieved a TMA removal higher than 85%. The same authors also achieved good DMA and MA 
removal, higher than 90%, at high loading rates; 89,4 gDMA·m-3·h-1 and 70 gMA·m-3·h-1). 
Aminobacter aminovorans is a microorganism known for its ability to use TMA as carbon and energy source 
but Rappert and Muller (2005) reported that the degradation of TMA is strongly inhibited by dimethyl disulfide, 
therefore the efficiency of the oxidation of amines would be reduced when sulphur compounds are present, it 
is a common situation in industrial emissions causing odor nuisance. On the other hand, Hyphomicrobium 

302



vulgare is a bacterium with a wide range of metabolic abilities that allow to degrade TMA in the presence of 
other compounds including reduced sulphur compounds. The main objective of this work was to determine the 
rates of TMA biodegradation of those two microorganisms, Hyphomicrobium vulgarae and Aminobacter 
aminovorans and the effect of H2S, in order to select one of them for inoculating biofilters for the removal of 
TMA from odorous gas emissions. 

2. Materials and Methods 
Hyphomicrobium vulgarae (ATCC 27499) and Aminobacter aminovorans (DSM 7048) were used in all the 
experiments. They were cultivated in specific ATCC minimum mineral salts mediums (Table 1) using an initial 
concentration of 2.4 g·L-1 TMA as sole carbon and energy source. To determine the effect of H2S on the 
biodegradation of TMA, H2S was added in the headspace of the flasks, the experiments were performed using 
0, 20 and 70 ppm of H2S as initial concentration in headspace.  
The liquid cultures were incubated in an orbital shaker at 30 °C and 200 rpm. Experiments were performed in 
stoppered flasks of 125 mL provided with mininert valves (VICI, USA) with 23 mL of medium at pH 7.0 and 
inoculated with 2 mL of an active culture with a cell concentration of 0.01 g L-1.  
Gas samples of 0.5 mL were taken from headspace of the flasks to determine the concentration of TMA by 
gas chromatography (Clarus 500, Perkin Elmer), using a packed column (Carbopack B/4% Carbowax 
20M/0.8% KOH, Supelco) and a flame ionization detector (FID). The carrier gas used was helium at a gas flow 
rate of 20 mL min-1. The temperatures at the injector and detector were 100 and 200 °C, respectively. The 
oven was heated from 90°C to 150°C at rate of 4°C min-1. The concentration of H2S was determined by GC 
using a Supelpack S column and a flame photometric detector (FPD), the temperatures at the injector and 
detector were 60 and 400 °C respectively, using helium as carrier flow gas at 30 ml/min. 
The concentration of biomass was determined by measuring optical densities at 600 nm and converted to dry 
weight of biomass using calibration curves previously made for each microorganism. 

Table 1. Culture media used in the cultivation of Aminobacter and Hyphomicrobium. 

 
Compound Aminobacter Hyphomicrobium 

K2HPO4 1.20 g L
-1

 - 
Na2HPO4 - 2.13 g L

-1
 

KH2PO4 0.62 g L
-1

 1.36 g L
-1

 
(NH4)2SO4 0.50 g L

-1
 0.50 g L

-1
 

MgSO4x7H2O 0.20 g L
-1

 0.20 g L
-1

 
NaCl 0.10 g L

-1
 - 

CaCl2x6H2O 0.05 g L
-1

 - 
CaCl2x2H2O - 0.006 g L

-1
 

ZnSO4x7H2O 0.07 mg L
-1

 - 
H3BO3 0.01 mg L

-1
 - 

MnSO4x5H2O 0.01 mg L
-1

 - 
MnSO4xH2O - 1.00 mg L

-1
 

Na2MoO4x2H2O 0.01 mg L
-1

 1.50 mg L
-1

 
CoCl2x6H2O 0.005 mg L

-1
 - 

CuSO4x5H2O 0.005 mg L
-1

 - 
FeSO4x7H2O 1 mg L

-1
 3.0 mg L

-1
 

FeCl3x6H2O 1 mg L
-1

 - 

3. Results and discussion 
The maximum biomass concentration obtained during the cultures was 1.17 g L-1 for Hyphomicrobium and 
0.44 g L-1 for A. aminovorans (Figure 1). The biomass yield for TMA was 0.35 (g g-1) for Hyphomicrobium and 
0.10 (g g-1) for A aminovorans. The maximum specific growth rate of A. aminovorans was 0.15 h-1, higher than 
the obtained with Hyphomicrobium; 0.09 h-1.  
The consumption of TMA in both cultures is shown in Figure 2. The specific consumption rates of TMA were 
0.47 h-1 and 0.12 h-1 for A. aminovorans and H. vulgare respectively (Table 2). Although A. aminovorans 
shows higher TMA specific consumption rate than Hyphomicrobium, its yield in biomass value (0.1 g g-1) 
indicates that in the case of A. aminovorans the carbon from TMA can be metabolized to carbon dioxide, in 
detriment of biomass production, according to the reports found in literature. The metabolic versatility of 
Hyphomicrobium, could be a an advantage over A. aminovorans for its selection as inoculum for systems 
dealing with the removal of TMA in mixtures with other compounds, i.e.: reduced sulfur compounds, usually 
present in gaseous emissions from industrial operations where is present. Successful TMA removal in 

303



biofilters has been reported (Wan et al. 2011) using mixed cultures; therefore both microorganisms could be 
used as inoculum of biological system designed to remove amines from a complex gas mixture. 
 

 

Figure 1. Biomass growth for Hyphomicrobium (▲) and Aminobacter (□) in batch cultures using TMA as sole 
carbon and energy source. 

Table 2. Maximum specific growth rate (µmax), biomass yield (Yx/s) and specific rate of TMA bio-degradation 
(rTMA) for Hyphomicrobium and Aminobacter. 

 
Microorganism µmax (h

-1) Yx/s (gbiomass g-1TMA) rTMA  (h
-1) 

Hyphomicrobium v. 0.09 0.35 0.12 
Aminobacter a. 0.15 0.10 0.47 
 
 

 

Figure 2. TMA consumption by Hyphomicrobium (▲) and Aminobacter (□) 

304



A
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 (
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)

0,0

0,1

0,2

0,3

0,4

0,5

0,6

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      0                 18                                                     69
       H2S (ppmv)

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 (

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-1

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0,0

0,2

0,4

0,6

0,8

1,0

1,2

 0                      16                                                50

            H2S (ppmv)
 

Figure 3. Specific consumption rate of Trimethylamine by a. Aminobacter aminovorans and b. 
Hyphomicrobium vulgare. 

Figure 3 shows the effect of H2S on the biodegradation of TMA, measured as initial specific rate of TMA 
consumption (gTMAconsumed · g

-1 
biomass · h

-1) for both microorganisms. As can be seen in the figures, even 
though the specific rate of consumption of TMA is higher for A. aminovorans, the presence of H2S have a 
strong influence the specific rate of consumption of TMA. The biodegradadtion of TMA by A. aminovorans is 
negatively affected by H2S, meanwhile in the case of Hyphomicrobium sp. the specific rate of biodegradation 
of TMA is positively influenced by the presence of H2S, making it even higher than the one obtained for A 
aminovorans without the presence of H2S. 

4. Conclusions 
In conclusion, due to its specific growth rate and TMA specific consume rate Aminobacter aminovorans is a 
suitable candidate to be used as inoculum for biofilters designed for removing gas emissions containing TMA 
when there is not H2S in its composition. However, if H2S is in the gaseous mixture, Hyphomicrobium vulgare 
would be the best choice for the inoculum or being part of the inoculum. 

Acknowledgments  

The authors acknowledge the financial support provided by CONICYT through the Project FONDECYT 
1151201 and the Pontificia Universidad Católica de Valparaíso. 

References 

Anthony C., 1975, The biochemistry of methylotrophic microorganisms, Sci. Prog. Oxf. 62, 167. 
Burgess J.E., Parsons S.A., Stuetz R.M., 2001, Developments in odour control and waste gas treatment 

biotechnology: A review, Biotechnol. Adv. 19, 35–63. 
Cao N.J., Du J.X., 1997, Production of fumaric acid by immobilized Rhizopus using rotary biofilm contactor, 

Appl. Biochem. Biotechnol. 63, 387–394. 
Chang C.T., Chen B.Y., Shiu I.S., Jeng F.T., 2004, Biofiltration of trimethylamine containing waste gas by 

entrapped mixed microbial cells, Chemosphere 55, 751–756. 
Chung Y., 2007, Evaluation of gas removal and bacterial community diversity in a biofilter developed to treat 

composting exhaust gases, J Hazard Mat. 144, 377-385. 
Colby J., Zatman L.J., 1973, Trimethylamine metabolism in obligate facultative methylotrophs. Biochem. J. 

132, 101-107. 
Ding Y., Shi J-Y., Wu W-X., Yin J., Chen Y-X., 2007, Trimethylamine (TMA) biofiltration and transformation in 

biofilters. J. Hazardous Mat. 143, 341–348. 
Ho K.L., Chung Y.Ch., Lin Y.H., Tseng Ch.P., 2008, Biofiltration of trimethylamine, dimethylamine and 

methylamines by immobilized paracoccus sp. CP2 and Arthrobacter sp. CP1, Chemosphere 72, 250.256. 
Hodge D.S., Devinny,J.S., 1994, Biofilter treatment of ethanol vapors, Environ. Prog. 13 (5), 167–173. 
Hwang Y., Matsuo T., Hanaki K., Suzuki N., 1994, Removal of odorous compounds in wastewater by using 

activated carbon, ozonation and aerated biofilter, Water Res. 28, 2309–2319. 
Kim S.G., Bae H.S., Lee S.T., 2001, A novel denitrifying bacterial isolate that degrades trimethylamine both 

aerobically and anaerobically via two different pathways, Arch. Microbiol. 176, 271–277. 

305



Kennes C., Thalasso F., 1989, Waste gas biotreatment technology, J. Chem. Technol. Biotechnol. 72, 303–
319. 

Leson G., Winer A.M., 1991, Biofiltration - An innovative air pollution control technology for VOC emission, J. 
Air Waste Manage. Assoc. 41, 1045–1054. 

Lidstrom M., 2006, Aerobic Methylotrophic Prokaryotes, In: Prokaryotes. Chapter 1. 20: 618-634. Springer. 
Liffourrena A.S., Salvano M.A., Lucchesi, G.I., 2010, Pseudomonas putida A ATCC 12633 oxidizes 

trimethylamine aerobically via two different pathways, Arch. Microbiol. 192, 471-478. 
Liffourrena G., Lucchesi I., 2014, Degradation of trimethylamine by immobilized cells of Pseudomonas putida 

A (ATCC 12633), International Biodeterioration & Biodegradation 90, 88-92. 
Lobo N., Rebelo A., Partidario P.J., and Roseiro J.C., 1997, A bubble column continuous fermentation system 

for trimethylamine conversion by Aminobacter aminovorans, Enz. Microb. Technol. 21, 191. 
López-Caballero M.E., Sánchez-Fernández J.A., Moral A., 2001, Growth and metabolic activity of Shewanella 

putrefaciens maintained under different CO2 and O2 concentrations. Int. J. Food Microbiol. 64, 277e287. 
Meiberg J., Harder W., 1978, Aerobic and Anaerobic Metabolism of Trimethylamine, Dimethylamine and 

Methylamine in Hyphomicrobium x, J. Gen. Microbiol. 106, 265 - 276. 
Rappert S., Muller R., 2005, Microbial degradation of selected odorous substances. Waste Manag. 25, 940-

954. 
Roseiro J.C., Partidario P.J., Lobo N., Marcal M.J., 1999, Physiology and kinetics of trimethylamine 

conversion by two methylotrophic strains in continuous cultivation systems, Appl. Microbiol. Biotechnol. 52, 
546–552. 

Sandberg M., Ahring B.K., 1992, Anaerobic treatment of fish meal process wastewater in a UASB reactor at 
high pH, Appl. Microbiol. Biotechnol. 36, 800–804. 

Shieh W.K., Keenan D.J., 1986, Fluidized bed biofilm reactor for wastewater treatment, Biochem. Eng. 33, 
132–168. 

Wan S, Li G, Zu L, An T., 2011, Purification of waste gas containing high concentration trimethylamine in 
biotrickling filter inoculated with B350 mixed microorganisms. Bioresource Tech. 102, 6757–6760. 

Xue N, Wang Q, Wang J, Sun X., 2013, Odorous composting gas abatement and microbial community 
diversity in a biotrickling filter, Int. Biodet. Biodeg. 82, 73 - 80. 

Yang P.Y., Ma T., See T.S., Nitisoravut N., 1994, Applying entrapped mixed microbial cell techniques for 
biological wastewater treatment, Water Sci. Technol. 29 (2), 487–495. 

Yaws C.L., 2001, Matheson Gas Data Book, seventh ed. McGraw-Hill Professional, New York, pp. 819. 
Wei Z., Huang Q., Ye Q., Chen Z., Li B., Wang J., 2015, Thermophilic biotrickling filtration of gas–phase 

trimethylamine. Atmospheric Pollution Research 6, 428 - 433.  
Zita, A., Hermansson, M., 1994, Effects of ionic strength bacterial adhesion and stability of floc in a 

wastewater actived sludge system, Appl. Environ. Microbiol. 60 (12), 3041–3048. 

306