Application of colonoscopic tattooing with India ink for localization of colorectal lesions in laparoscopic surgery / 中国内镜杂志

Objective?To investigate the use of submucosal injection of India ink for localization of colorectal lesions in laparoscopic surgery, and to evaluate its efficiency and safety.?Methods?A retrospective study of 146 patients with colorectal lesions from January 2015 to November 2017, who underwent preoperative colonoscopic marking with India ink and subsequently received laparoscopic colectomy was conducted. 1.0 ml of physiologic saline solution was first injected into the submucosa to produce an artificial submucosal elevation, and then 0.2 ml of 1 : 10 diluted India ink followed with another 1ml of physiologic saline solution was injected. Operation time, success rate, complications, location efficiency, and postoperative pathology were evaluated.?Results?The India ink tattooing was easily applied for all patients without complication. At laparoscopic surgery, all lesions could be clearly visualized. No ink diffusion, leakage, and local inflammatory responses were observed. The surgical margins of all samples were tumor negative.?Conclusion?Preoperative submucosal tattooing with India ink is recommended as an easy, safe and economical procedure.

Mapping quantitative trait loci for seed size traits in soybean (Glycine max L. Merr.).

Seed size traits in soybean--length, width and thickness--and their corresponding ratios--length-to-width, length-to-thickness and width-to-thickness--play a crucial role in determining seed appearance, quality and yield. In this study, an attempt was made to detect quantitative trait loci (QTL) for the aforementioned seed size traits in F(2:3), F(2:4) and F(2:5) populations from the direct and reciprocal crosses of Lishuizhongzihuang with Nannong 493-1, using multi-QTL joint analysis (MJA) along with composite interval mapping (CIM). A total of 121 main-effect QTL (M-QTL), six environmental effects, eight environment-by-QTL interactions, five cytoplasmic effects and 92 cytoplasm-by-QTL interactions were detected. Fifty-two common M-QTL across MJA and CIM, 21 common M-QTL in more than two populations and 5 M-QTL in all three populations showed the stability of the results. Five M-QTL had higher heritability, greater than 20%. In addition, 28 cytoplasm-by-QTL and 4 environment-by-QTL interactions were confirmed by CIM. Most M-QTL were clustered in eight chromosomal regions. Our results provide a good foundation for fine mapping, cloning and designed molecular breeding of favorable genes related to soybean seed size traits.

[A simulated study on mapping QTL in a segregating sub-population].

For mapping QTLs, phenotypes of the traits in segregating population derived from the cross between two isogenic lines of the targeted QTL may reflect its genotype if the effect of the QTL is relatively large. In order to map the QTL, it is necessary to use a large sample under the high density of markers around the QTL. However, it increases experimental costs. In order to save the costs, it is possible to map the QTL using the sub-population that consists of plants with homogenous recessive. In this paper, the sub-population was used to estimate the recombination fraction between the marker and the QTL, and its standard error for F2, backcross (BC), double haploid (DH) and recombinant inbred lines (RIL) populations, respectively. The results from Monte Carlo simulation showed that the estimation of recombination fraction based on the sub-population is consistent with that obtained from the full population, and the precision of the former is same as that of the later under the same sample size.