319例352眼眼外伤疗效观察

采用综合治疗，抗炎，散瞳，局部治疗与全身应用免疫抑制疗法，治疗３１９例３５２眼外伤获得了满意的疗效，眼球挫伤１０４例，眼球穿孔伤９３例，化学烧伤７１例，眼炸伤４６例。眼热烧伤５例，治疗包括及时清创胶粘或缝合，清除前房出血合理用皮质类固醇和免疫抑制剂等。眼球挫伤治愈率９７．１２％，穿透伤９３．１８％，热烧伤６６．６７％。３１９例眼外伤治愈率９４．６７％好转５．３３％，并对各种治疗方法进行了讨论。     

Retrorenal colon: implications for percutaneous diskectomy

It has been recommended that computed tomography (CT) with the patient prone be performed in every patient undergoing percutaneous diskectomy; this would enable detection of a retrorenal location of the colon, which could interfere with the percutaneous procedure. In this evaluation of 346 prone CT studies, only one patient (0.29%) was found to have retrorenal or retropsoas bowel that would have been perforated at diskectomy. Because of this extremely low prevalence, the performance of prone CT in every patient undergoing percutaneous lumbar diskectomy is not believed to be necessary.     

Ultrasound biomicroscopic features of spherophakia

Background: Spherophakia is an uncommon diagnosis. This is the first case report of spherophakia evaluated by ultrasound biomicroscopy.
Methods: Ultrasound biomicroscopy is a new diagnostic technique developed by one of the authors and provides images with microscopic resolution of the anterior segment. A patient with spherophakia was evaluated by ultrasound biomicroscopy (Zeiss-Humphrey, 50MHz) before and after YAG laser iridotomy.
Results: Ultrasound biomicroscopic assessment revealed a shallow anterior chamber, a very steep anterior lens curvature, iridolenticular contact, elongated zonules, and an increased distance between the lens equator and the ciliary processes. Angle closure glaucoma was due to a pupil block mechanism. The pupil block was relieved by YAG laser iridotomy.
Conclusions: Ultrasound biomicroscopy is a useful technique to confirm the diagnosis of spherophakia. The pupil block in spherophakia is relieved by YAG laser iridotomy.     

1,6—二磷酸果糖对手术后应激病人应用全肠外营养支持效果的影响

本文在胃癌行全胃或胃大部切除术引起的中等程度应激病人，随机分组对比观察了全肠外营养或ＴＰＮ加用１，６－二磷酸果糖的效果。结果显示，与单纯ＴＰＮ相比，ＴＰＮ加用ＦＤＰ后血清皮质醇和胰高血糖素等应激激素水平有所下降，尿中３－甲基组氨酸排出减少，累积氮平衡增加。     

纤维素固相放射免疫测定甲胎蛋白

本文在国内首次报道了纤维素固相RIA法测定甲胎蛋白。本法简便灵敏,快迅稳定,平均回收率95.7±8.08％,批间变异系数r=7.8±1.7％,批内变异系数r=5.8±2.6％,线性关系较好(r=0.999),灵敏度比液相RIA提高6倍,32份血样品用双位点夹心法和试剂盒的液相RIA进行比较,结果经统计学处理,相关系数分别为r=0.82,r=0.80,均具有显著相关性。     

Mutation spectrum and genotype-phenotype analyses in Cowden disease and Bannayan-Zonana syndrome, two hamartoma syndromes with germline PTEN mutation

The tumour suppressor gene PTEN , which maps to 10q23.3 and encodes a 403 amino acid dual specificity phosphatase (protein tyrosine phosphatase; PTPase), was shown recently to play a broad role in human malignancy. Somatic PTEN deletions and mutations were observed in sporadic breast, brain, prostate and kidney cancer cell lines and in several primary tumours such as endometrial carcinomas, malignant melanoma and thyroid tumours. In addition, PTEN was identified as the susceptibility gene for two hamartoma syndromes: Cowden disease (CD; MIM 158350) and Bannayan-Zonana (BZS) or Ruvalcaba-Riley-Smith syndrome (MIM 153480). Constitutive DNA from 37 CD families and seven BZS families was screened for germline PTEN mutations. PTEN mutations were identified in 30 of 37 (81%) CD families, including missense and nonsense point mutations, deletions, insertions, a deletion/insertion and splice site mutations. These mutations were scattered over the entire length of PTEN , with the exception of the first, fourth and last exons. A 'hot spot' for PTEN mutation in CD was identified in exon 5 that contains the PTPase core motif, with 13 of 30 (43%) CD mutations identified in this exon. Seven of 30 (23%) were within the core motif, the majority (five of seven) of which were missense mutations, possibly pointing to the functional significance of this region. Germline PTEN mutations were identified in four of seven (57%) BZS families studied. Interestingly, none of these mutations was observed in the PTPase core motif. It is also worthy of note that a single nonsense point mutation, R233X, was observed in the germline DNA from two unrelated CD families and one BZS family. Genotype-phenotype studies were not performed on this small group of BZS families. However, genotype-phenotype analysis inthe group of CD families revealed two possible associations worthy of follow-up in independent analyses. The first was an association noted in the group of CD families with breast disease. A correlation was observed between the presence/absence of a PTEN mutation and the type of breast involvement (unaffected versus benign versus malignant). Specifically and more directly, an association was also observed between the presence of a PTEN mutation and malignant breast disease. Secondly, there appeared to be an interdependent association between mutations upstream and within the PTPase core motif, the core motif containing the majority of missense mutations, and the involvement of all major organ systems (central nervous system, thyroid, breast, skin and gastrointestinal tract). However, these observations would need to be confirmed by studying a larger number of CD families.      

Immunization of Aotus Monkeys with Recombinant Plasmodium falciparum Hybrid Proteins Does Not Reproducibly Result in Protection from Malaria Infection

Plasmodium falciparum antigens SERP, HRPII, MSAI, and 41-3 have shown promise as vaccine components. This study aimed at reproducing and extending previous results using three hybrid molecules. Antibody responses were reproduced in Aotus monkeys, but solid protection from a P. falciparum blood-stage challenge that showed an unintendedly enhanced pathogenicity was not observed.The increasing drug resistance of Plasmodium falciparum, the most pathogenic human malaria parasite, underlines the need for an effective malaria vaccine. Identification, testing, and optimization of candidate molecules originating from all developmental stages of the parasite are under way. Previously, a successful trial in Aotus monkeys employed the Escherichia coli-expressed hybrid proteins MS2/SERP/HRPII and SERP/MSAI/HRPII (11). Both hybrid proteins contain a region of the serine repeat protein SERP (1, 9), including two putative T-cell epitopes (13) and previously shown to induce a partial protective response in Aotus monkeys (5), and the C-terminal half of the histidine-rich protein HRPII (14), which has also been shown to induce a partially protective response (5, 8). SERP/MSAI/HRPII contains in addition a conserved N-terminal region of the merozoite surface antigen MSAI (7) that includes at least four T-cell epitopes (3, 6). Here we report on further analysis of three hybrid proteins of this type in a vaccination trial with Aotus monkeys. Two of the proteins, SERP/HRPII and SERP/MSAI/HRPII, are improved versions of the hybrid proteins mentioned above, obtained by deleting nonmalaria protein regions and changing an internal restart residue (methionine-729 of SERP) into alanine. Thus, the SERP/HRPII hybrid protein comprises residues 630 to 893 of SERP fused to the 189 C-terminal residues of HRPII, and SERP/MSAI/ HRPII comprises residues 630 to 764 of SERP fused to residues 146 to 259 of MSAI, which is fused to the 189 C-terminal residues of HRPII. SERP/41-3/HRPII contains the same components as SERP/HRPII, and additionally includes residues 77 to 188 of antigen 41-3 (10), which was previously shown to confer protection against a P. falciparum challenge (5). The internal restart residue (methionine-100) was also mutagenized into alanine and another residue, arginine-319, was changed into leucine to prevent proteolytic degradation. SERP/MSAI/HRPII was partially purified to a final purity of about 30%, as described previously (8), in order to match the quality of the proteins used in the successful previous trials (5, 11). The other two hybrid proteins were purified from bacterial lysates to over 90% purity by size exclusion chromatography (SERP/41-3/HRPII) or by sequential cation and anion exchange and then size exclusion chromatography (SERP/ HRPII) (data not shown). The final products were dialyzed against phosphate-buffered saline–3 M urea and adjusted to 100 μg of protein per ml. Efficacy was tested following an experimental protocol identical to the one used in the previous successful trial (11).Fifteen laboratory-raised Aotus azarae boliviensis karyotype VI monkeys were randomly assigned to one of four experimental groups (three groups of four and one group of three monkeys) and immunized with 1 ml of antigen or with the diluent alone (control group), both mixed with 100 μl of polyalphaolefin (4) as an adjuvant, on days 0, 21, and 42. Each vaccine dose was administered subcutaneously at two separate sites in the right and left flank and was well tolerated. The seroconversion results, as measured by enzyme-linked immunosorbent assay with SERP/HRPII as the solid-phase antigen and peroxidase-labelled rabbit anti-human immunoglobulin G (1:10,000 dilution; Pierce) as the secondary antibody, are shown in Fig. ​Fig.1.1. All experimental monkeys developed comparable antibody responses to SERP/HRPII, irrespective of the immunogen. Control monkey sera did not react significantly (not shown). A boosting effect is obvious after the second injection in all three groups (Fig. ​(Fig.1),1), as well as after the third SERP/41-3/HRPII injection (Fig. ​(Fig.1C).1C). This is similar to the seroconversion pattern observed previously (11). Prechallenge sera were also tested by immunofluorescence (IFA) for reactivity with P. falciparum schizonts. All preimmune sera and control group immune sera were negative (1:100 dilution). IFA titers from the experimental animals were all 1:1,600, except for animals A381 and A462 (titer, 1:800) and A452 and A292 (titer, 1:3,200). Thus, antibodies specific for native parasite determinants were induced. The relatively low IFA titers were comparable to those obtained in previous successful trials (5, 11). Open in a separate windowFIG. 1Development of antibody responses in Aotus monkeys during the immunization period as determined by enzyme-linked immunosorbent assay. Monkeys in different immunization groups were immunized at weeks 0, 3, and 6 (indicated by arrows) and challenged at week 8 (indicated by an asterisk). All sera were tested for reactivity with SERP/HRPII in a 1:100 dilution. The hybrid antigens used for immunization were SERP/MSAI/HRPII (A), SERP/HRPII (B), and SERP/41-3/HRPII (C). Sera of the three control monkeys remained negative in this assay (not shown). OD, optical density.At week 7 all monkeys were splenectomized, and at week 8 they received intravenously 2 × 10⁶ parasitized erythrocytes, which had been isolated from an Aotus monkey infected with an in vivo-passaged FUP-Cayenne isolate of P. falciparum (a kind gift of W. E. Collins) (Fig. ​(Fig.1).1). Monkey A293 appeared to have no spleen, although there was no prior history of splenectomy. The immunoglobulin G response of monkey A293 was nevertheless comparable to that of the other animals (Fig. ​(Fig.1B).1B). Figure ​Figure22 shows the course of parasitemia after challenge. Two of three control animals rapidly developed a parasitemia which required mefloquine therapy (20 mg/kg of body weight orally) when parasitemia reached 10% (day 8 for A371 and day 10 for A320). In A432, parasitemia developed to 8.6% (day 10) and then fluctuated until rapidly reaching 19% (day 21), at which point mefloquine was administered (Fig. ​(Fig.2A).2A). None of the three immunized groups showed a solid protective response (Fig. ​(Fig.2B2B to D). A340 (SERP/HRPII group) (Fig. ​(Fig.2C)2C) and A292 (SERP/41-3/HRPII group) (Fig. ​(Fig.2D)2D) showed low fluctuating parasitemias with a peak around 2.5% at the end of the observation period (day 25). Otherwise, parasitemias of the experimental animals did not significantly differ from those of the controls. No obvious correlation between prechallenge antibody levels and protection was evident. Open in a separate windowFIG. 2Course of infection with the FUP-Cayenne isolate of P. falciparum in control Aotus monkeys (A) and in Aotus monkeys immunized with SERP/MSAI/HRPII (B), SERP/HRPII (C), and SERP/41-3/HRPII (D). Parasitemias of ≥10% were cured with mefloquine.It seems unlikely that small conservative changes designed to improve SERP/HRPII and SERP/MSAI/HRPII expression in E. coli and to remove nonrelevant sequences adversely affected immune response development. After challenge, parasitemia developed markedly faster than in the previous trial, which had shown protection. Challenge with 2 × 10⁶ parasitized erythrocytes now resulted in high parasitemias on days 7 to 9 in 2 of the 3 controls and in 6 of the 12 experimental animals, whereas previously controls were untreated until day 14 (11). Also, one control and three experimental animals suffered recrudescence, which was not seen previously (11) or with later infections with the same parasite stock (5). It is remarkable that this apparent enhanced pathogenicity developed after a single passage in A. nancymai just before the present trial started. It is likely that this unintended pathogenicity influenced the experimental outcome. The protection of two monkeys in the SERP/HRPII and SERP/41-3/HRPII group may, however, reveal some protective effect of these vaccine candidates.For demonstration of the protective potential of antigens in the primate model the pathogenicity of the challenge strain in the respective primate (sub)species, i.e., the equilibrium of immune response and pathogenicity, seems to be crucial (2, 12). The disturbance of this equilibrium may explain the discrepancy between previous successful trials (5, 11) and the present study. Recombinant proteins shown to be protective in the Aotus model (5, 11) failed to protect Saimiri monkeys, in which the course of parasitemia is quite different from that observed in Aotus monkeys. Similarly, no protection could be demonstrated in A. nancymai against the same challenge strain as was used in the successful trials with A. azarae boliviensis and A. lemurinus griseimembra (7a). The poor standardization of these models due to the scarcity of monkeys susceptible to human malaria remains an obstacle for the evaluation of human malaria vaccine candidates.