‘Well-being’ is an important trend and issue that requires consumers to be satisfied with various functional fabrics; subsequently, functional fabrics that are highly sensible, functional, and environmentally friendly have a competitive edge (O’Mahony & Braddock, 2002; Hui, Lau & Ng, 2004). Recent interest in environmental protection due to global warming has led to various energy reduction campaigns. Fabric research has focused on developing cool summer fabrics and warm winter fabrics. The selection of a correct textile material is important to form a pleasant clothing climate. New fabric development requires new measurement methods. Warm/cool touch is a major factor that influences thermal clothing comfort. Current measurements of warm/cool touch is mainly assessed by Q-max using Thermo-LaboⅡ. The potential of using an infrared thermography camera (widely used because of its relatively cheap price) on warm/cool touch research has increased because it can visually show changes in clothing surface temperature. Skin temperature is a factor that influences heat exchange between the body and environment. It also indicates the effectiveness of the heat transfer process. It is an important standard to evaluate thermal comfort in thermal physiology. The techniques to measure skin temperature have been investigated to find more accurate data (Min, Chung, Sung, Jeon, & Kim, 2001). A thermometer is generally used to measure body temperature; however, there are some difficulties to accurately measure skin temperature using a thermometer. First, skin temperature was determined by only a few points on the body. Second, heat occurs during exercising due to fabric and thermometer friction that creates difficulties for the accurate measurement of skin temperature. A previous study by Choi & Lee (2008) indicated that it would be possible to evaluate the thermal properties of clothing using infrared thermal images. This study used a garment with different triacetate and PET high absorbance quick dry filament blending ratios and chose three healthy female subjects in their twenties to evaluate wear comfort sensations. They walked at 3.3 km/h for 20 minutes under conditions of 29±2℃ and 75±5% R.H. Subjective assessments of wear coolness, microclimate, and the thermogram image under the clothing were measured before and after exercising. We compared the results of the microclimate and subjective assessments with the results of the thermogram analyses. Clothing, high blended with triacetate, had a small average temperature difference as indicated by infrared thermal image. This result corresponded to subjective thermal sensation, microclimate humidity, and subjective wear comfort.

Clothing comfort indicates the comfortableness of the in varying environmental situations while wearing specific clothing. Various factors affect clothing comfort such as skin moisture perception and heat transmission characteristics via clothing; however, cool and warm touch are the most important factors (Kwon, Yi, & Sung,1999; Hong & Kim, 2007; Manshahia & Das, 2014). The thermal comfort of clothing is perceived through sensory receptors on the skin surface and is highly related to a cool and warm touch. An infrared thermography camera detects infrared-ray-form energy, a type of electromagnetic wave radiated from the subject's surface that assesses the intensity of radiant heat. The changing intensity then presents a real-time infrared thermal distribution using various colors. The advantages of an infrared thermography camera are the ability to use a non-contacting method to measure temperature distribution and analyze temperatures. Therefore, an infrared thermography camera is widely used in material characteristic assessment, boiler heat distribution analysis, process control, and building insulation assessments that indicate system deficiencies. This technique has also recently been used in human-body-related temperature measurements with potential for application to medical fields that include breast cancer examinations, joint muscle disorders, and body reactions under specific conditions. The most significant advantage of infrared thermography cameras to evaluate heat conductivity according to wearing conditions are its inexpensive price, ease-of-use and visual representation of surface heat dispersion on clothing that maintains body temperature and helps dissipate sweat(B. Lee, Hong, & Y. Lee, 2010; Lee, K. Hong, & S. A. Hong, 2007). This technique is also used in a quantitative analysis of thermal sensation when wearing clothes (Choi & Lee, 2008). This study helps develop a method to evaluate the warm feeling of fabrics using an infrared thermal image of a small test specimen. An infrared thermal image helped develop5 types of fabrics for heat storage fabric; consequently, the average temperature difference of the human palm when the fabric is on or off was used for the scale of the fabrics’ warm feeling. The relationshipbetween this average temperature difference on the palm surface Qmax, and warmth keep-ability rate was examined. Fabric had a significant average temperature difference in the infrared thermal image with alow Qmax value and was evaluated with high values in the warmth keep-ability rate. Infrared thermography camera was shown to be effective in the fabric's warm feeling evaluation.

Hereditary dentin defects consists of dentin dysplasia(DD) and denti nogenesis imperfecta(Dr) ‘ The Dl associated with osteogenesis imperfecta has been classified as DI type 1. whereas isolated inherited defects have been categori zed as DI types II and III , However‘ whether DI type III should be considered a distinct phenotype 01' a variation of DI type 1I is debatable , Recent genetic findings have focused attention on the role of the dentin sialo phosphoprotein(DSPP) gene in the etiology of inherited defects of tooth dentin, We have identified novel mlltation( c,727G - > A, p,D243N) at the 243th codon of exon 4 of the DSPP gene in a Korean patient with DI type III The radiographic and histologic features of the patient revealed the classic phenotype of shell teeth These findings sllggest that DI type II and III are not separate diseases bllt rather the phenotypic variation 01' a s ingle disease