A novel simplified transperineal prostate biopsy guided by perineal ultrasound.

BACKGROUND: Prostate biopsies are mainly performed through transrectal or perineal approaches, while ultrasound probes are located in the rectum for guidance. However, reports on the use of perineal ultrasound-guided transperineal prostate biopsy (PG-TPPB) are few. METHODS: A retrospective case-control study was designed. A total of 111 patients who underwent PG-TPPB from February 2019 to December 2020 were investigated retrospectively. Simultaneously, 188 patients who underwent transrectal prostate biopsy (TRPB) were included as control. The prostate cancer detection rates (PCDR), complication rates, and application values were compared between the 2 groups. RESULTS: The overall PCDR in the PG-TPPB and TRPB groups were 33.3% (37/111) and 39.9% (75/188), respectively (P = .258). There was no significant difference in the PCDR between the 2 groups under each prostate-specific antigen level (all P > .05). The single-needle PCDR in the PG-TPPB and TRPB groups were 21.5% (277/1 287) and 24.0% (513/2 134), respectively (P = .091). The incidence of complications in the PG-TPPB group was significantly lower than that in the TRPB group (8.1% vs 21.3%, P = .003). CONCLUSIONS: The PCDRs of PG-TPPB and TRPB were the same. However, the postoperative complication rate of PG-TPPB was significantly lower than that of TRPB. Moreover, PG-TPPB required simpler equipment and did not require enema administration, which is suitable for patients with rectal contraindications. ADVANCES IN KNOWLEDGE: The reports on PG-TPPB are few. Our study indicated that PG-TPPB reduced the postoperative complication rate. Moreover, PG-TPPB required simpler equipment. Importantly, PG-TPPB is suitable for patients with rectal contraindications.

Construction and Validation of the Postgraduate Research Innovation Ability Scale (PRIAS): A Three-Dimensional Structural Model Based on Componential Theory of Creativity.

Purpose: To explore the structure of postgraduate research innovation ability and verify the Postgraduate Research Innovation Ability Scale. Patients and Methods: This study was based on the componential theory of creativity. First, we drafted an item pool from the literature review, semi-structured interviews, and group discussions. A total of 125 postgraduates were selected for the pre-test. After item selection and exploratory factor analysis, an 11-item, 3-factor postgraduate research innovation ability scale was formed. The scale was applied to a sample of 330 postgraduates from various domestic universities. Exploratory factor analysis and confirmatory factor analysis were used to examine the factor structure of the scales. Results: The results support a three-factor model including creativity-relevant processes, domain-relevant skills, and intrinsic motivation for the Postgraduate Research Innovation Ability Scale. The scale showed good internal consistency (α =0.89) and test-retest reliability (r=0.86). Exploratory factor analysis showed that the KMO value was 0.87, and the Bartlett's sphericity test results were significant. Confirmatory factor analysis confirmed that the three-factor construct demonstrated a good model fit (χ2/df=1.945, GFI=0.916, CFI=0.950, RMSEA=0.076). Conclusion: The Postgraduate Research Innovation Ability Scale has good reliability and validity, and it can be used for future research in related fields.

Moderate nitrogen application improved salt tolerance by enhancing photosynthesis, antioxidants, and osmotic adjustment in rapeseed (Brassica napus L.).

Salt stress is a major adverse environmental factor limiting plant growth. Nitrogen (N) application is an effective strategy to alleviate the negative effects of salt stress on plants. To improve the knowledge of the mechanism of N application on alleviating salt stress on rapeseed seedlings, a pot experiment was conducted with four N application treatments (0, 0.1, 0.2, and 0.3 g N kg-1 soil, referred to as N0, N1, N2, and N3, respectively) and exposed to non-salt stress (0 g NaCl kg-1 soil, referred to as S0) and salt stress (3 g NaCl kg-1 soil, referred to as S1) conditions. The results indicated that in comparison with non-salt stress, salt stress increased the Na content (236.53%) and reactive oxygen species (ROS) production such as hydrogen peroxide (H2O2) (30.26%), resulting in cell membrane lipid peroxidation characterized by an increased content of malondialdehyde (MDA) (122.32%) and suppressed photosynthetic rate (15.59%), finally leading to inhibited plant growth such as shorter plant height, thinner root neck, lower leaf area, and decreased dry weight. N application improved the plant growth, and the improvement by N application under salt stress was stronger than that under non-salt stress, suggesting that rapeseed seedlings exposed to salt stress are more sensitive to N application and require N to support their growth. Moreover, seedlings exposed to salt stress under N application showed lower ROS accumulation; increased photosynthesis; higher antioxidants such as catalase (CAT), superoxide dismutase (SOD), glutathione reductase (GR), and ascorbic acid (AsA); and greater accumulation of osmotic substances including soluble protein, soluble sugar, and proline, as compared with seedlings without N application. In particular, the best improvement by N application under salt stress occurred at the N2 level, while too high N application could weaken the improvement due to inhibited N metabolism. In summary, this study suggests that moderate N application can improve photosynthesis, antioxidants, and osmoregulation to alleviate the adverse effects of salt stress in rapeseed seedlings.