Normal olfactory acuity will usually return over time if the cause is environmental, even if it is untreated. The hyperosmic person may need to be removed from strong odorants for a period of time if the sensation becomes unbearable. Before they had been discontinued due to undesirable side effects, butyrophenones or thioridazine hydrochloride, both of which are dopamine antagonists, have been used to treat hyperosmia.

There has not been extensive research into environmental causes of hyperosmia, but there are some theories of some possible causes.

In a study by Atianjoh et al., it has been found that amphetamines decrease levels of dopamine in the olfactory bulbs of rodents. On this basis, it has been hypothesized that amphetamine use may cause hyperosmia in rodents and humans, but further research is still needed. Anecdotal support for the belief that amphetamines may cause hyperosmia comes from Oliver Sacks's account of a patient with a heightened sense of smell after taking amphetamines.

It has been observed that the inhalation of hydrocarbons can cause hyperosmia, most likely due to the destruction of dopaminergic neurons in the olfactory bulb.

Methotrexate, administered in the treatment of psoriasis, has been known to cause hyperosmia, and may be more likely to do so in patients with a history of migraines. However, this is only an observation and not part of a study, therefore it is yet to be verified.

Due to the rareness of the disorder there is no well-defined treatment. Sometimes the patients are just told to live with the disorder or the patients end up performing "stereotypical methods" that might help in reducing the severity of the odor. This might include forced crying, bending over holding knees while holding breath, rinsing the nose with saline water and gagging. All these behaviours at the end fail to resolve the hallucination. Various treatments like prophylactic have been suggested but more research is needed for its confirmation. Also, due to being a poorly understood disorder, and having analogies to some psychiatric conditions, some patients are told that they have a mental illness. It is also usual for these patients to have suicidal thoughts as they are not provided with much support or hope from many physicians.

One of the surgical treatments proposed has included olfactory bulb ablation through a bifrontal craniotomy approach. But a counter-argument by Leopold, Loehrl and Schwob (2002) has stated that this ablation process results in a bilateral permanent anosmia and includes risks associated with a craniotomy. According to them, the use of transnasal endoscopic exhibition of olfactory epithelium is a safe and effective treatment for patients with unremitting Phantosmia with the olfactory function being potentially spared.

It is also cautioned that the surgery is challenging one and is associated with major risks, and that it should be restricted to expertise centres.

On the other hand, many cases have also reported that the strength of their symptoms have decreased with time. (Duncan and Seidan, 1995)

A case involving long term phantosmia has been treated with the use of an anti depressive medication by the common name Venlafaxine. The brand name of the drug is Effexor. The relation between mood disorders and phantosmia is unknown, and is a widely researched area. In many cases, the symptoms of phantosmia have been reduced by the use of anti seizure and anti depressants that act on the central and peripheral neurons.

The most commonly used treatment method is the removal of the olfactory epithelium or the bulb by means of surgery to alleviate the patient from the symptoms.

Other traditional methods include the use of topical anesthetics (Zilstorff-Pederson, 1995) and use of sedatives.

This antidepressant medication is a serotonin norepinephrine reuptake inhibitor (SNRI). In the case study of a 52-year-old female suffering from phantosmia for 27 years, a dose of 75 mg a day relieved and eliminated her symptoms. The drug was prescribed initially in order to treat her depression.

On June 16, 2009, the US Food and Drug Administration sent a warning letter to Matrixx Initiatives, manufacturer of an over-the-counter nasal spray for the common cold, Zicam. The FDA cited complaints that the product caused anosmia. The manufacturer strongly denies these allegations, but has recalled the product and has stopped selling it.

In fact, Matrixx has received more than 800 reports of Zicam users who were losing their sense of smell but did not provide those reports to the FDA.

Though anosmia caused by brain damage cannot be treated, anosmia caused by inflammatory changes in the mucosa may be treated with glucocorticoids. Reduction of inflammation through the use of oral glucocorticoids such as prednisone, followed by long term topical glucocorticoid nasal spray, would easily and safely treat the anosmia. A prednisone regimen is adjusted based on the degree of the thickness of mucosa, the discharge of oedema and the presence or absence of nasal polyps. However, the treatment is not permanent and may have to be repeated after a short while. Together with medication, pressure of the upper area of the nose must be mitigated through aeration and drainage.

Anosmia caused by a nasal polyp may be treated by steroidal treatment or removal of the polyp.

There have also been cases where the use of acupuncture have successfully treated anosmia.

Although very early in development, gene therapy has restored a sense of smell in mice with congenital anosmia when caused by ciliopathy. In this case a genetic condition had affected cilia in their bodies which normally enabled them to detect air-borne chemicals, and an adenovirus was used to implant a working version of the IFT88 gene into defective cells in the nose, which restored the cilia and allowed a sense of smell.

Many chemicals have been reported to trigger MCS symptoms. Substances with strong scents are the most commonly reported triggers. These include a variety of cleaning agents, pesticides, perfumes, vehicle exhaust, the products used in barber shops and beauty salons, new carpeting, new furniture, chlorine and fluoride in drinking water, fresh ink, and less commonly wood smoke and secondhand tobacco smoke. Food items reported as triggers include tartrazine (a.k.a. FD&C Yellow #5 or E102), and other azo dyes (in the absence of an allergy), caffeine, and monosodium glutamate.

One proposed hypothesis for the cause of multiple chemical sensitivity is immune system dysfunction after being sensitized by a chemical exposure.