Triclocarban (sometimes abbreviated as TCC) is an antibacterial chemical once common in, but now phased out of, personal care products like soaps and lotions.

[2] Although the mode of action is unknown, TCC can be effective in fighting infections by targeting the growth of bacteria such as Staphylococcus aureus.

[3] Additional research seeks to understand its potential for causing antibacterial resistance and its effects on organismal and environmental health.

[5] It was commonly found in personal care products as an antimicrobial in soaps, lotions, deodorants, toothpaste, and plastic.

[5] In 2011 United States consumers were spending nearly 1 billion dollars annually on products containing triclocarban and triclosan.

[7] In December 2013, the Food and Drug Administration (FDA) required all companies to prove within the next year, that triclocarban is not harmful to consumers.

While triclocarban has two chlorinated phenyl rings, it is structurally similar to carbanilide compounds often found in pesticides (such as diuron) and some drugs.

Generally, in vitro, triclocarban enhances the gene expression of other steroid hormones, including androgens, estrogens, and cortisol.

[5] Exposure of organisms like fish, algae, and humans to low levels of triclocarban and other antibacterial chemicals kills weak microbes and allows the stronger, resistant strains to proliferate.

The risk of bacterial antibiotic resistance has been studied by quantitatively monitoring the abundance of the tetQ gene in wastewater microcosms.

[19] TetQ gene expression in bacteria was also found to be significantly increased when multiple antimicrobials such as tetracycline, triclosan, and triclocarban were added to an experimental system at the same time.

Discharge of effluent from these treatment plants and disposal of sludge on land is the primary route of environmental exposure to triclocarban.

Research shows that triclocarban and triclosan have been detected in sewage effluents and sludge (biosolids) due to their incomplete removal during wastewater treatment.

[20] Studies show that substantial quantities of triclocarban (227,000 – 454,000 kg/y) can break through wastewater treatment plants and damage algae on surface waters.

[6] Triclocarban has a hazard quotient rating of greater than one, which indicates the potential for adverse effects on organisms due to toxicity.

Specifically, triclocarban has been shown to be toxic to amphibians, fish, invertebrates, and aquatic plants, and traces of the compound have been found in Atlantic dolphins.

Triclocarban and triclosan have been observed in multiple organisms, including algae, aquatic blackworms, fish, and dolphins.

These constructed wetlands are considered a cost-effective treatment option for the removal of PPCPs, including triclocarban and triclosan, from domestic water effluent.

In case of exposure to triclocarban, the individual is suggested to wash the area with water or to clear the respiratory pathways.

[20] Legal action by the Natural Resources Defense Council in 2010 forced the FDA to review triclocarban and triclosan.

[20] On September 2, 2016, the Food and Drug Administration announced that triclosan and triclocarban must be removed from all antibacterial soap products by late 2017.

[20] These next generation chemicals should aim to act on a broad spectrum of microbes and pathogens while also being minimally toxic and bioaccumulating in non-target species.

[citation needed] Synthesis of these compounds could be improved upon by finding renewable sources for their production that lacks occupational hazards.