Nerve regeneration with aid of nanotechnology and cellular engineering

Repairing nerve defects with large gaps remains one of the most operative challenges for surgeons. Incomplete recovery from peripheral nerve injuries can produce a diversity of negative outcomes, including numbness, impairment of sensory or motor function, possibility of developing chronic pain, and devastating permanent disability. In the last few years, numerous microsurgical techniques, such as coaptation, nerve autograft, and different biological or polymeric nerve conduits, have been developed to reconstruct a long segment of damaged peripheral nerve. A few of these techniques are promising and have become popular among surgeons. Advancements in the field of tissue engineering have led to development of synthetic nerve conduits as an alternative for the nerve autograft technique, which is the current practice to bridge nerve defects with gaps larger than 30 mm. However, to date, despite significant progress in this field, no material has been found to be an ideal alternative to the nerve autograft. This article briefly reviews major up-to-date published studies using different materials as an alternative to the nerve autograft to bridge peripheral nerve gaps in an attempt to assess their ability to support and enhance nerve regeneration and their prospective drawbacks, and also highlights the promising hope for nerve regeneration with the next generation of nerve conduits, which has been significantly enhanced with the tissue engineering approach, especially with the aid of nanotechnology in development of the three-dimensional scaffold. The goal is to determine potential alternatives for nerve regeneration and repair that are simply and directly applicable in clinical conditions.     

Long-term effect of vital labelling on mixed Schwann cell cultures

Schwann cell transplantation following neuronal injury could encourage regeneration of spinal cord as well as improving peripheral nerve gap repair. In order to gain a better understanding of the role of transplanted Schwann cells in vivo, it is essential to be able to follow their behaviour after transplantation. Our aim was to evaluate the suitability of two vital fluorescent labels on the proliferation rate and phenotypic stability of Schwann cells, in either pure culture or mixed co-culture. Primary cultures of Schwann cells were obtained from Dark Agouti and Lewis neonatal rats and labelled with H33342 and PKH26, respectively. In mixed cultures, a 50:50 mixture of Dark Agouti and Lewis Schwann cells was present. Labelled cultured cells were examined at 1, 2 and 4 weeks for viability and phenotypic marker expression of S100, GFAP, p75, MHC I, MHC II and compared with corresponding unlabelled cells. The results showed that although there was no deleterious interaction in the mixed cultures, the viability was reduced by the labelling after 2 weeks. Labelled cells could be distinguished up to 4 weeks, but there was leakage of H33342 label after 2 weeks. Labelled Schwann cells showed reduced expression of phenotypic markers, especially p75 when labelled with H33342. In conclusion, H33342 and PKH26 can be used as fluorescent markers of Schwann cells for short-term studies, for a maximum of 2 weeks, but different markers may be needed for longer experiments.     

Purification of potato virus X and preparation of its antiserum

Potato virus X (PVX) isolated from the potato leaf and tuber samples which were collected from various fields in Damavand and Ardabil. The initial isolations of the virus were made from potato by mechanical inoculation on Gomphrena globosa L. and Chenopodium spp. that produce local lesion, and then it causes mosaic on Nicotiana spp. and Datura stramonium L. An isolate of the virus inoculated to Nicotiana glutinosa L. and it was maintained throughout the work. Sap from infected N. glutinosa was ineffective after dilution to 10-6, 10 minutes at 70 degrees and 10 weeks at room temperature. The virus was readily purified from infected leaves and the best protocol was Moreira & Jones 1980 than the other 2 methods of Fribourg 1975 and Shepard & Shalla 1972. Antisera were prepared against native, degraded proteins and micro precipitin test showed that both antisera had a 1/512 titer. Precipitin lines with D - Protein antiserum was better of the native protein antiserum in agar double diffusion test than treated with SDS. The isolate of the virus was not transmitted by none of 2 species of Cuscuta but transmitted from infected leaves to healthy plants with sap inoculation without using Carburandum. This isolate showed positive reaction with gamaglubulin in kate received from CIP centre.     

Detection of Alfalfa mosaic virus (AMV) in pea field in Iran

During the spring and summer, in 2003-2004, pea viruses were identified in twenty pea fields of Tehran. Some leaf samples were collected randomly from pea fields of Tehran. Samples were tested by Double Antibody Sandwich Enzyme Linked Immunosorbent Assay (DAS-ELISA) technique using polyclonal antiserum of Alfalfa mosaic virus (AMV), AS-0001, DSMZ, Braunschweig, Germany). The samples were extracted in 0.1 M Phosphate buffer pH 7 to 7.5 and inoculated on Chenopodium amaranticolor, Chenopodium quina, Phaseolus valgaris, Vicia faba, Vignia unguiculata. Pea cultivars were infected by AMV, causing mild mosaic, translucent veins and a diffuse green-yellow of tender parts and spots may also was involved necrosis of tissue. Infected plants grow slowly and malformed pods produce fewer ovules. In Chenopodium amranticolor, C. quina chlorotic and necrotic flecks, and Vicia faba systemic mosaic had produced. Phaselous vulgaris and Viginia unguiculata are good assay hosts for strains that produce local lesions after 3-5 days in these plants. Back inoculated on Pisum sativum and Vicia faba and tested with DAS-ELISA that had been confirmed the results. This is the first report of AMV on pea from Iran.     

First report of occurrence of two viruses on pea field in Iran

An intensive survey was conducted to identify virus diseases affecting pea crops in Tehran province of Iran. A total of 270 pea samples were collected randomly from pea fields. samples were tested by Double Antibody Sandwich Enzyme Linked Immunosorbent Assay (DAS-ELISA) using polyclonal antisera prepared against PSBMV (AS-0129, DSMZ, Braunschweig, Germany) and TSWV (AS-0580, DSMZ, Braunschweig, Germany). Virus disease incidence in pea samples was followed by PSBMV (33%) TSWV (24.4%) and PSBMV+TSWV (17.77). The positive samples with PSBMV were extracted in 0.05M phosphate buffer pH 6.5-7 containing 2% pvp and inoculated on Pisum sativum, Vicia faba, Chenopodium quinoa, Chenopodium amaranticolor. That produced in Pisum sativum; leaflets roll downwards, shoots curl, internodes shorten and plants are rosetted. Early infections reduce flower and fruit formation or eliminate their development. Broad bean has symptoms accompanied by a certain margin rolling and leaflet distortion. In Chenopodium amaranticolor necrotic local lesions and Chenopodium quinoa chlorotic local lesions had produced. The positive samples with TSWV were extracted in 0.01 M phosphate buffer containing 1% Na2 SO3 and inoculated on Petunia hybrida, Pisum sativum. TSWV causes several symptoms in infected peas, including brown leaf petiole and stem coloration, leaflet spotting, vein necrosis. In petunia hybrida after approximately 5 days showed local necrotic lesion. Biological purification in TSWV with chlorotic local lesions in Petunia hybrida and in PSBMV; chlorotic local lesions in Chenopodium quinoa were done. In PSBMV, back inoculated on Pisum sativum and Vicia faba also tested with DAS-ELISA. RT-PCR confirmed the results. This is the first report of PSBMV and TSWV naturally infecting pea in Iran.     

Identification of PVY-N on potato and tobacco in Tehran and Mazandaran provinces

During two growing seasons in years of 2003 and 2004 potato and tobacco of virus infected plants were collected from fields in Tehran (Damavand) and Mazandaran (Behshahr) provinces. Serological methods of TAS-ELISA and DIBA were performed by using PVY antiserum (DSMZ - Plant Virus Collection; Germany) but only PVY was detected. The strain of samples was determined by using MAb of potato virus Y (AS-0403/1; DSMZ; Germany). The molecular weight of the virus coat protein was approximately 34 kDa in SDS-PAGE and Western blotting. Total RNA was extracted for RT-PCR. Immunocapture RT-PCR and RT-PCR products were 974 bp by using specific primers of PVY. IC-RT-PCR has given the best results.     

Occurrence and physico-serological properties of potato virus S (PVS) in Iran

1818 collected samples of potato plant showing virus infection symptoms from 85 fields were tested for PVS infection using DAS-ELISA. Average of infection to this virus varied from 0 to 100%. Least infection was belonging to fields with new introduced varieties. On the other hand native and old introduced cultivars showed heavy infection. In field condition, PVS infected plants didn't show very obvious symptoms, so some infected plants may be missed in field sample collecting. The physical properties of 3 isolates, Avaj, Stanboly and Agria No 15 were determined. TIP 55-60 degrees C, DEP 10(-3) and Liv measured 3-4 days. Ouchterlony agar double diffusion test using SDS was useful for virus detection and precipitation lines didn't show any spur between isolates, although isolates differs slightly in symptomatology. SDS-Page and Western blotting methods used successfully for virus detection and determining and measuring viral protein components.