[Location, selection, and comparative anatomy of "Taixi" (KI3), "Shuiquan" (KI5), "Fuliu" (KI7), "Jiaoxin" (KI8), "Zhubin" (KI9), and "Yingu"(KI10) acupoints in rabbits].

OBJECTIVE: To investigate the. METHODS: for locating and selecting the acupoints of "Taixi" (KI3), "Shuiquan" (KI5), "Fuliu" (KI7), "Jiaoxin" (KI8), "Zhubin" (KI9), and "Yingu" (KI10) and the morphological structure of these acupoints in rabbits. MethodsAccording to the WHO and national standards for human acupoints and rabbit X-ray images, acupoint locations were marked using the anatomical landmarks on body surface in 10 New Zealand rabbits. The acupoints were dissected to compare the homologous and analogous tissue between rabbits and human body and thus correct the locations of these acupoints. Potentials were measured for the 10 New Zealand rabbits at the corrected locations of the acupoints and around the acupoints, and the final locations of these acupoints were determined by comparing the anatomical results and the data of potentials. Anatomical observation was performed after marking, and the relationship between acupuncture needle and adjacent structure was observed. RESULTS: "Taixi" was located in the ankle area, at the midpoint between the prominence of the medial malleolus and the calca-neal tendon; "Shuiquan" was located in the calcaneal area below "Taixi" in the depression anterior to the calcaneal tuberosity; "Fuliu" was located at the medial side of the calf, at 2 cun above the prominence of the medial malleolus anterior to the calcaneal tendon; "Jiaoxin" was located at the medial side of the calf, at 2 cun above the prominence of the medial malleolus and in the depression posterior to the medial border of the tibia; "Zhubin" was located at the medial side of the calf, at 5 cun above the medial malleolus on the line between "Taixi" and "Yingu"; "Yingu" was located at the medial side of the knee, at the posterior-inferior border of the semitendinosus tendon on the popliteal crease. The results of skin potentials at the acupoints suggested that "Taixi", "Shuiquan", "Fuliu", and "Zhubin" were high-reliability acupoints, "Jiaoxin" was a medium-reliability acupoint, and "Yingu" was a low-reliability acupoint. CONCLUSION: Comparative anatomy combined with imaging, surface anatomy, and electrophysiological techniques of acupoints can help with the accurate localization and selection of acupoints in experimental animals, improve the reliability of acupoint location, and enrich the comparative anatomical data of acupoints.

[Hierarchical structure of Five-shu points and Source-point of Triple Energizer Meridian in rabbits].

OBJECTIVE: To study the position and hierarchical structure of Five-shu points, i．e., "Guanchong" (TE1), "Yemen" (TE2), "Zhongzhu" (TE3), "Yangchi" (TE4) and "Zhigou" (TE6), and the Source-point "Tianjing" (TE10) of the Triple Energizer (TE) Meridian in the rabbit. METHODS: Based on WHO Standard Acupuncture Point Locations in the Western Pacific Region (WHO Standard) and National Standard (GB/T 22103-2008) for Acupuncture Point Locations in human body, and combined with X-ray images, the hierarchical structure of Five-shu points and Source-point of the TE Meridian were observed in ten New Zealand rabbits. The acupoint locations were determined by comparing the same name tissues of the rabbits and human body after dissecting the above-mentioned acupoints. After inserting acupuncture needles into the aforementioned acupoints, the relationship between the acupuncture needle and adjacent structure were dissected and measured. RESULTS: "Guanchong" (TE1) was located on the lateral side of the 4th terminal phalanx, and behind the corner of the onyx root. When needled, the penetrated tissues of the acupuncture needle are skin, superficial fascia, deep fascia, and the root region of the 4th phalanx, respectively. "Yemen" (TE2) was located between the 4th and 5th onyxes, at the depression of intersection of coat hair superior to the fingerweb edge. When needled, the penetrated tissues of the acupuncture needle are the superficial fascia, deep fascia and lumbrical muscles of the forepaw, respectively. "Zhongzhu" (TE3) was located between the 4th and 5th metacarpal bones, at the depression proximal to the 4th metacarpophalangeal joint. When needled, the penetrated tissues are skin, superficial fascia, deep fascia, and lumbrical muscle, respectively. "Yangchi" (TE4) was positioned at the dorsal side of the forepaw, and the surface connection line between the accessory and radial bones intersected with the depression of the extensor digitorum communis on the ulnar side. When needled, the penetrated tissues are skin, superficial fascia, deep fascia, and the ulnar side of the common extensor tendon, respectively. "Zhigou" (TE6) was positioned between the radius and ulna, on the posterior aspect of the forelimb and 3 Bone-cun proximal to the distal dorsal forepaw crease. When needled, the penetrated tissues are skin, superficial fascia, deep fascia, and the extensor digitorum, respectively. "Tianjing" (TE10) was located at the junction of the body of humerus and the lateral condyle of humerus, on the posterior aspect of the elbow and proximal to the prominence of the olecranon. When needled, the penetrated tissues are skin, superficial fascia, deep fascia, and triceps brachii muscle, respectively. CONCLUSION: The Five-shu points and Source-point of the TE Meridian on the forelimb in rabbits are innervated by the cutaneous branches of the ulnar radial nerve and the medial brachial cutaneous nerve at the superficial layer, and by the branches of the ulnar nerve and radial nerve in the deep layer, accompanied with cephalic vein and forearm blood vessels and their branches.

LRG1 promotes corneal angiogenesis and lymphangiogenesis in a corneal alkali burn mouse model.

AIM: To investigate the potential effect and mechanism of leucine-rich α-2-glycoprotein-1 (LRG1) on corneal angiogenesis and lymphangiogenesis. METHODS: Corneal neovascularization and lymphatics were induced by establishing alkali burn mouse model. Immunofluorescence staining was performed to detect the location of LRG1 in cornea tissues and to verify the source of LRG1-positive cells. Corneal whole-mount staining for CD31 (a panendothelial cell marker) and lymphatic endothelial hyluronan receptor-1 (LYVE-1; lymphatic marker) was performed to detect the growth of blood and lymphatic vessels after local application of exogenous LRG1 protein or LRG1 siRNA. In addition, expressions of the proangiogenic vascular endothelial growth factor (VEGF) related proteins were detected using Western blot analysis. RESULTS: LRG1 was dramatically increased in alkali burned corneal stroma in both the limbal and central areas. LRG1-positive cells in the corneal stroma were mainly derived from Vimentin-positive cells. Local application of exogenous LRG1 protein not only aggravated angiogenesis but also lymphangiogenesis significantly (P<0.01). LRG1 group upregulated the levels of VEGF and the vascular endothelial growth factor receptor (VEGFR) family when compared with the phosphate-buffered saline (PBS) control group. We also found that LRG1-specific siRNA could suppress corneal angiogenesis and lymphangiogenesis when compared with the scramble siRNA-treated group (P<0.01). CONCLUSION: LRG1 can facilitate corneal angiogenesis and lymphangiogenesis through heightening the stromal expression of VEGF-A, B, C, D and VEGFR-1, 2, 3; LRG1-specific siRNA can suppress corneal angiogenesis and lymphangiogenesis in corneal alkali burn mice.

Study on the Genetic Differentiation of Geographic Populations of Calliptamus italicus (Orthoptera: Acrididae) in Sino-Kazakh Border Areas Based on Mitochondrial COI and COII Genes.

Calliptamus italicus L. is an important pest on the desert and semidesert steppes along the Sino-Kazakh border. To elucidate the molecular mechanism of its continuous outbreaks, we studied 11 different geographic populations of C. italicus to determine: 1) the complete sequences of the entire mitochondrial cytochrome oxidase subunit I (COI) and mitochondrial cytochrome oxidase subunit II (COII) genes, and 2) performed genetic diversity, differentiation, gene flow, and molecular variation analyses. Of the 11 populations, the Yining County (YNX) population had the highest haplotype diversity and Pi values. There are significant differences in Tajima's D and Fu's Fs (P < 0.05). The fixation index Fst values of the total C. italicus population were 0.03352, and its gene flow Nm values of the total C. italicus population were 15.32. Taken together, there were five main findings: 1) the current genetic differentiation of C. italicus arose within populations; 2) genetic exchange levels were high between geographical populations; 3) genetic variation level was low; 4) C. italicus populations likely expanded in recently, and 5) there was no significant correlation between genetic distance and geographic distance for any geographic population. Findings from this study indicate that frequent gene exchange between populations may enhance the adaptability of C. italicus along the Sino-Kazakh border, leading to frequent outbreaks.