Our research divided into three parts. In the first study, to efficiently prevent and treat bovine mastitis and minimize its impact on dairy industry in Taiwan, a sensitive, rapid, and specific test is required for identifying the mastitis-causing pathogens. We used biochip to examine the distribution of mastitis-causing pathogens in Taiwan. The biochip is capable of detecting 6 common species of mastitis-causing pathogens within 6 hours, including Streptococcus bovis, Streptococcus uberis, Streptococcus agalactiae, Streptococcus dysgalactiae, Escherichia coli and Staphylococcus aureus. The technique is based on DNA amplification of genes specific to the target pathogens and consists of 4 basic steps: DNA extraction of bacteria, PCR reaction, DNA hybridization, colorimetric reaction. The Biochip was used for detecting bacteria in bulk tank milk samples from 207 DHI-participating dairy farms. The results show that S. bovis, detected in samples from 163 (78.7%) farms, was the most prevalent species, followed by S. uberis (60.4%), E. coli (45.4%), S. dysgalactiae (30.0%), S. agalactiae (27.5%), and Staph. aureus (9.2%). In the next study, a new biochip capable of detecting 7 species of mastitis-causing pathogens, including Corynebacterium bovis, Mycoplasma bovis, Staphylococcus aureus, S. agalactiae, S. bovis, S. uberis and S. dysgalactiae, within 6 hr was developed. To examine the accuracy and specificity of this biochip, a preliminary test with 82 random quarter milk samples were analyzed and compared to results from conventional microbiological methods conducted simultaneously. Results from all but one sample analyzed by the biochip were in agreement with those analyzed by bacteriology. The biochip could be a feasible tool for rapidly diagnosing mastitis-causing pathogens in milk and providing information for a more effective treatment to cure mastitis. The second study was conducted to treat dairy cows with high somatic cell count (SCC) with Chinese herbal medicine-Pu-Gong-Ying Shan. This formula composed of Taraxacum mongolicum 100 g, Viola patrinu 50 g, Lonicera japonica Thunb. 50 g, Citri reticulatae viride pericarpium 30 g, and Glycyrrhiza uralensis Fischer 30 g per cow. SCCs in raw milk of the cows were all over 50×104 cells/ml. Twenty dairy cows were divided into treatment (n=10) group and control (n=10) group. In treatment group, each cow was fed 260 g complex Chinese herb everyday. Each experiment lasted 14 days. At the beginning and end of the experiments, the SCC in raw milk was measured. The results showed that the mean of SCC in raw milk were 196.6 ± 48.7 × 104 cells/ml and 91.1 ± 71.9 × 104 cells /ml for treatment group at the beginning and end of experiment, respectively. The means of SCC in raw milk were 215.6 ± 59.0 × 104 cells/ml and 317.1 ± 175.2 × 104 cells/ml for control group at the beginning and end of experiment, respectively. There was significant difference between them (P<0.05). In blood chemistry assay, the concentration of asparatate aminotransferase (AST) and blood urea nitrogen (BUN) showed no significant difference between treatment group and control group. The results showed that Pu-Gong-Ying Shan did decrease SCC in raw milk of dairy cow and it had a good potential for preventing and treating bovine mastitis. The anti-inflammatory effects of Taraxacum mongolicum (TM) were investigated in Holstein-Friesian dairy cows, in vitro and in vivo. In vitro: Isolated milk somatic cells were pretreated with various concentrations (31 to 500, μg/ml) of TM extract (TME) and subsequently incubated with lipopolysaccharide (LPS, 1 μg/ml). The results showed that TME treatment had no effect on cell viability; however, it significantly suppressed LPS-induced expression of nitric oxide (NO), interleukin(IL)-8, IL-1β, and tumor necrosis factor (TNF)-α in milk somatic cells, in a dose-dependent manner. In vivo, 14 lactating cows, with subclinical mastitis, were randomly assigned to two groups and fed a diet with (treatment group, n=7, 150 g TM powder per head per day) or without (control group, n=7) TM supplementation for 14 days. Cows fed with TM powder had a significantly (P<0.05) reduced SCC, total bacteria count and IL-8 in milk compared to the control group. In conclusion, the anti-inflammatory effects of TM were associated with down-regulation of NO and pro-inflammatory cytokines. Addition of TM as a dietary supplement might minimize the impact of subclinical bovine mastitis. The third study, the effects of Sheng Hua Tang (SHT) on uterine involution and ovarian activity were investigated in postpartum dairy cows. SHT (70 g) was given to dairy cows (n=10) to evaluate its effects for five days from the first postpartum day. Postpartum cows fed with a basal diet without SHT were used as the control group (n=10). Ultrasounds and blood tests were recorded for four weeks from postpartum day seven with a 3-day interval. The results showed that the areas and diameters of endometria were significantly (P<0.01) reduced in the group that received SHT compared to the control group on the seventh postpartum day. The group that received SHT had an intrauterine fluid volume mean of 1.2 ± 0.6 cm3, which was significantly lower than that of the control group, 2.3 ± 0.8 cm3 (P<0.01) on the 13th postpartum day. In addition, the uterine tension score was a mean of 1.0 ± 0.0 in the group that received SHT, which was also significantly lower than that of the control group, 1.5 ± 0.5 (P<0.01) on the 19th postpartum day. Taken together, the SHT promoted uterine involution and ovarian activity in postpartum dairy cows.