Olfaction is detecting odors by means of smell and is rapidly becoming a field of fascinating discoveries. The human nose is designed to detect a trillion smells,1 which is significantly more than previous estimates. The millions of people who have temporarily lost their sense of smell (chemosensation) due to COVID 19 infection have ensured that studies and research in this field will only increase.
The basic anatomy of the process of smelling has been determined.
The Lord Jesus has designed these complex sensory neurons in our nasal cavity (as well as mammals and other terrestrial animals) that recognize odorant molecules such as pizza, perfume or fresh-brewed coffee.
As a person inhales through the nose, the air with the ordorant molecules goes across millions of olfactory neurons (a lot more in dogs) in the nasal cavity. These specially-designed neurons have surface receptors called GPCRs (G-Protein Coupled Receptors).3 The odorant molecule—called a ligand—specifically binds with a G-protein receptor and immediately causes a biochemical cascade of reactions (intracellular adenyl cyclase components) within the neuron.
When a volatile molecule [ligand] is recognized by a [G-protein] receptor, it is activated and generates a signal that is transmitted to the olfactory bulb in the brain, a signal that is then translated into an odor. The olfactory system responds to highly variable environments and must be able to adapt very quickly.4
How do these receptors actually function? Evolutionists do not know.
Recently, it was found that “Each olfactory neuron expresses only one gene coding for an olfactory receptor, chosen from a repertoire of about 450 in humans and 1,200 in mice.”6 But scientists at the Faculty of Science and the Faculty of Medicine of the University of Geneva (UNIGE) researched the gene expression profile of olfactory neurons and discovered olfaction not only affecting the gene coding for the receptor, but also other genes.
They also made a surprising discovery regarding genes and a double role the receptor plays in olfaction, “Neurons expressing the same receptor do not only share this receptor but also differ in the expression of hundreds of other genes. Genes whose expression level seems to be directed by the expressed olfactory receptor, which would thus play a double role.”6
To conclude, God designed olfactory neurons to adapt to the surrounding environment.
Clearly, olfaction in people and terrestrial animals did not evolve, “the precise evolutionary and developmental delineation of the olfactory system becomes blurry when one considers the details.”7 The smelling process has all the earmarks of complex organization and creative design from the mind of the Creator.
References
1. Williams, S. Human nose can detect a trillion smells. Science. Posted on science.org March 20, 2014, accessed May 30, 2022.
2. Jiang, K. New study reveals how the brain organizes information about odors. Medical Express. Posted on medicalexpress.com July 2, 2020, accessed May 30, 2022.
3. Sherwin, F. Those Amazing G Protein Receptors. Creation Science Update. Posted on ICR.org December 1, 2006, accessed May 22, 2022.
4. Staff Writer. Olfactory neurons adapt to the surrounding environment. Medical Express. Posted on medicalexpress.com May 30, 2022, accessed May 30, 2022.
5. Staff Writer. By dark of night, how do bats smell their way to fruit? National Science Foundation. Posted on Nsf.gov March 3, 2014, accessed May 30, 2022.
6. Staff Writer. Olfactory neurons adapt to the surrounding environment. Medicalexpress.com May 30, 2022 accessed May 30, 2022.
7. Poncelet, G. and S. Shimeld. 2020. The Evolutionary Origins of the Vertebrate Olfactory System. Open Biology 10:200330.
8. Philippians 4:18
*Dr. Sherwin is Research Scientist at the Institute for Creation Research. He earned an M.A. in zoology from the University of Northern Colorado and received an Honorary Doctorate of Science from Pensacola Christian College.