Clinical Application of Nutrigenomics

Mi Sun Kwak; Ki Baik Hahm; HJ Joung

doi:10.5124/jkma.2006.49.2.163

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Kwak, Hahm, and Joung: Clinical Application of Nutrigenomics

Continuing Education Column

Journal of the Korean Medical Association

Journal of the Korean Medical Association 2006; 49(2): 163-172.

Published online: 28 February 2006

DOI: https://doi.org/10.5124/jkma.2006.49.2.163

Clinical Application of Nutrigenomics

Mi Sun Kwak, Ph.D.¹, Ki Baik Hahm, M.D.¹, HJ Joung, Ph.D.²

¹Department of Gastroenterology/Genome Research Center for Gastroenterology, Ajou University College of Medicine & Hospital, Korea. ms8686@hanmail.net, hahmkb@hotmail.com

²Postgraduate School of Public Health and Institute of Health and Environment, Seoul National University, Korea. hjjoung@snu.ac.kr

Abstract

Nutritional genomics (nutrigenomics) is the application of high-throughput functional genomics technologies to nutritional science lying in the interface between the nutritional environment and genetic process. It seeks to provide a molecular genetic understanding of how common dietary nutrition affects health by altering the expression or structure of an individual's genetic makeup. On the other hand, nutrigenetics is significantly different from nutrigenomics since nutrigenetics has been used for decades in certain rare monogenic diseases such as phenylketonuria, and has the potential to provide a basis for personalized dietary recommendation based on the individual's specific genetic background in order to prevent common multifactorial disorders decades before their clinical manifestation. The human genome maps and SNP databases, together with the rapid development of tools suitable for investigating genetic and epigenetic changes in small tissue biopsies provide the means to begin the test hypothesis about the mechanisms by which diet influences disease risk including cancer directly in human subjects, could be inevitable flatforms for clinical application to achieve targeted therapy in near future.

Keywords: Nutrigenomics, Nutrigenetics, SNP, Genome

Figures and Tables

Figure 1

What's different between nutrigenetics and nutrigenomic?

Figure 2

Nutrigenomics; How dose it influence disease pathogenesis?

Figure 3

Implication of nutrition in the generation and progression of various diseases

Figure 4

Kind and application of high throughput analysis for nutrigenomics

Figure 5

History of nutritional research associated with clinical disease

Figure 6

Perspective of nutrigenomics

Table 1

Definite or probable evidence showing the contribution of nutrition on disease

Table 2

Examples of genomic polymorphisms on putative nutritional impact

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