Glutathione and Pulmonary diseases

The extensive surface area and blood supply in our lungs enables them to provide our bodies with sufficient oxygen for us to generate the energy we need to survive. But this makes our lungs particularly susceptible to injury due to the relatively high concentration of free radicals and reactive oxygen species (ROS) which are produced by our normal metabolism. Beyond this, environmental toxins in the air we breathe, including ozone, nitrogen oxides (from smog), mineral dusts (e.g. silica and asbestos), cigarette smoke and car exhaust, may cause further injury [1].

Our lungs have evolved a complex biochemistry to counter these adverse conditions and glutathione is a key player in our defense mechanisms. However, as we age, or with the progression of persistent health issues, cellular glutathione levels can fall below optimal for maintaining good health [2].

Many lung diseases are associated with glutathione deficiency. These include acute respiratory distress syndrome (ARDS), asthma, chronic obstructive pulmonary disease (COPD), cystic fibrosis, idiopathic pulmonary fibrosis, chronic bronchitis and various viral and bacterial infections [3]. An exaggerated inflammatory response is also implicated during the development of many lung diseases which is further exacerbated by depleted glutathione levels.

In the case of cystic fibrosis, a common treatment, nebulized n-acetylcysteine (NAC), helps loosen the mucus that forms in the lungs. This has led some researchers to test NAC in various animal models of inflammatory lung disease. Some have shown partial success, and this is most likely due to NAC’s limited ability to increase glutathione levels [3]. Unfortunately, most human clinical trials that have tested NAC in lung disease have had rather disappointing efficacy [4-6]. This is not surprising since NAC is only effective when cellular glutathione has been acutely (rather than chronically) depleted such as during acetaminophen (paracetamol) overdose.

Supplementation with Glyteine is different. In a human clinical trial, a marked increase in glutathione levels was shown regardless of its initial (basal) concentration. And, most importantly, this increase occurred rapidly (within hours) [7].

References

  1. Biswas, S.K. and I. Rahman, Environmental toxicity, redox signaling and lung inflammation: The role of glutathione Molecular Aspects of Medicine, 2009. 30(1-2): p. 60.
  2. Gould, N.S. and B.J. Day, Targeting maladaptive glutathione responses in lung disease. Biochemical Pharmacology, 2011. 81(2): p. 187-193.
  3. Ghezzi, P., Role of glutathione in immunity and inflammation in the lung. International Journal of General Medicine, 2011. 4: p. 105-113.
  4. Aitio, M.-L., N-acetylcysteine – passe-partout or much ado about nothing? British Journal of Clinical Pharmacology, 2006. 61(1): p. 5-15.
  5. Tam, J., et al., Nebulized and oral thiol derivatives for pulmonary disease in cystic fibrosis. Cochrane Database Syst Rev, 2013(7): p. Cd007168.
  6. Alfonso, H., et al., Effect of N-acetylcysteine supplementation on oxidative stress status and alveolar inflammation in people exposed to asbestos: a double-blind, randomized clinical trial. Respirology, 2015. 20(7): p. 1102-7.
  7. Zarka, M.H. and W.J. Bridge, Oral administration of γ-glutamylcysteine increases intracellular glutathione levels above homeostasis in a randomised human trial pilot study. Redox Biology, 2017. 11: p. 631-636.