The largest perforator of DIEP flap has a higher rate of continuity with the superficial inferior epigastric artery.

BACKGROUND: In deep inferior epigastric artery (DIEA) perforator (DIEP) flap breast reconstruction, the network with the superficial inferior epigastric artery (SIEA) is key to achieving stable subcutaneous blood flow to the flap. This study investigated how the diameter and location of the DIEA perforator affect continuity with the SIEA. METHODS: A retrospective analysis of 94 specimens from 47 patients who underwent DIEA perforator flap breast reconstruction was performed. Relationships between the diameter and location of the DIEA perforator and its continuity with the SIEA were examined on preoperative multi-slice computed tomography. RESULTS: The largest DIEA perforator on each specimen showed continuity with the SIEA in 94 %, significantly more than the second (80 %; p = 0.027) or third largest perforator (76 %; p = 0.005). Medial perforators from 3 cm above to 3 cm below the umbilicus showed more continuity with the SIEA than lateral perforators (p = 0.008). CONCLUSIONS: Selection of the largest perforator of DIEP flap is advantageous in terms of continuity with the SIEA. Also, near the umbilicus, medial perforators communicate with the SIEA more than lateral perforators.

Distinct types of stem cell divisions determine organ regeneration and aging in hair follicles.

Hair follicles, mammalian mini-organs that grow hair, miniaturize during aging, leading to hair thinning and loss. Here we report that hair follicle stem cells (HFSCs) lose their regenerative capabilities during aging owing to the adoption of an atypical cell division program. Cell fate tracing and cell division axis analyses revealed that while HFSCs in young mice undergo typical symmetric and asymmetric cell divisions to regenerate hair follicles, upon aging or stress, they adopt an atypical 'stress-responsive' type of asymmetric cell division. This type of division is accompanied by the destabilization of hemidesmosomal protein COL17A1 and cell polarity protein aPKCλ and generates terminally differentiating epidermal cells instead of regenerating the hair follicle niche. With the repetition of these atypical divisions, HFSCs detach from the basal membrane causing their exhaustion, elimination and organ aging. The experimentally induced stabilization of COL17A1 rescued organ homeostasis through aPKCλ stabilization. These results demonstrate that distinct stem cell division programs may govern tissue and organ aging.

Stem cell competition orchestrates skin homeostasis and ageing.

Stem cells underlie tissue homeostasis, but their dynamics during ageing-and the relevance of these dynamics to organ ageing-remain unknown. Here we report that the expression of the hemidesmosome component collagen XVII (COL17A1) by epidermal stem cells fluctuates physiologically through genomic/oxidative stress-induced proteolysis, and that the resulting differential expression of COL17A1 in individual stem cells generates a driving force for cell competition. In vivo clonal analysis in mice and in vitro 3D modelling show that clones that express high levels of COL17A1, which divide symmetrically, outcompete and eliminate adjacent stressed clones that express low levels of COL17A1, which divide asymmetrically. Stem cells with higher potential or quality are thus selected for homeostasis, but their eventual loss of COL17A1 limits their competition, thereby causing ageing. The resultant hemidesmosome fragility and stem cell delamination deplete adjacent melanocytes and fibroblasts to promote skin ageing. Conversely, the forced maintenance of COL17A1 rescues skin organ ageing, thereby indicating potential angles for anti-ageing therapeutic intervention.

Clinical outcome and mechanism of soft tissue calcification in Werner syndrome.

Werner syndrome (WS) is an autosomal recessive progeroid disorder caused by mutations in RecQ DNA helicase. Ectopic soft tissue calcification is one of the well known symptoms in WS. However, the prevalence, clinical outcome, and mechanism of such calcification remain to be elucidated. The clinical features and mechanism of ectopic calcification were examined in seven patients with WS whose diagnosis were confirmed by a genomic DNA analysis. X-ray examinations revealed subcutaneous calcification in 35 of 41 major joints (85.3%). The patients complained of dermal pain at 23 joints among 35 joints (65.7%) with calcification. Refractory skin ulcers were found at the area of the skin overlaying the calcification in 16 joints (45.7%). In contrast, no pain or ulcers were observed in the joints without calcification. The presence of ectopic calcification could not be explained by a systemic hormonal abnormality. Cultured fibroblasts from WS patients underwent spontaneous mineralization in vitro in the normal phosphate condition, and overexpressed Pit-1, a transmembrane type III Na-Pi cotransporter both at the mRNA and protein levels. Phosphonophormic acid, a specific inhibitor for Pit-1, inhibited mineralization in the WS fibroblasts. Both calcification and Pit-1 overexpression were detected in the skin of WS in situ. WS showed a high prevalence of ectopic calcification, which was associated with dermal pain and refractory skin ulcers. An overexpression of Pit-1 therefore seems to play a key role in the formation of soft tissue calcification in this syndrome.