ABSTRACT
Both clinical practice and basic research of acupuncture have pointed out that acupuncture treatment has specific tissue and cellular targets. In addition to the known fixed tissue targets such as nerves and blood vessels, the author analyzes the biological characteristics of other skin resident cells in the skin and concludes that cutaneous mast cells are the most suitable candidate for the cellular target of acupuncture. A hypothesis of the bionic acupuncture is proposed to explain the biological principles by which the innate immunity and healing system respond to acupuncture. The distribution of mast cells in the human skin is characterized by "approaching to the terminals and gathering at the orifices", and the cell density is highly correlated with the density of acupoints and the micro-acupuncture systems. These evidences all support that mast cells are the mobile target cells for acupuncture, which can explain some clinical phenomena and principles of acupuncture, and suggest mast cells as one of the tissue markers for acupoints.
Subject(s)
Humans , Acupuncture , Acupuncture Points , Acupuncture Therapy , Mast Cells , SkinABSTRACT
Niosomes are a novel drug delivery system, in which the medication is encapsulated in a vesicle. Niosomes are formations of vesicles by hydrating mixture of cholesterol and nonionic surfactants. Different novel approaches used for delivering these drugs include liposomes,microspheres, nanotechnology, micro emulsions, antibody loaded drug delivery, magnetic microcapsules, implantable pumps and niosomes. Niosomes and liposomes are equiactive in drug delivery potential and both increase drug efficacy as compared with that of free drug. Niosomes are now widely studied as an alternative to liposomes . They improve the therapeutic performance of the drug molecules by delayed clearance from the circulation, protecting the drug from biological environment and restricting effects to target cells. The application of niosomal technology is widely used to treat a number of diseases.
ABSTRACT
Campylobacter fetus is the etiological agent of bovine genital campylobacteriosis, a sexually transmitted disease which is associated with reproductive losses in bovines. Campylobacter colonizes the vagina and the uterus and then infects the epithelial cells of the endometrium. The objective of this work was to develop an ex vivo model to quantify the adhesion of Campylobacter to its natural specific target cells; this is a key step for the establishment of infection and studies regarding the adherence and cytotoxicity on the natural host cells are not available. The assays were carried out by seeding Campylobacter fetus venerealis on bovine vaginal and uterine epithelial cell cultures. HeLa cells were used as control. Bacterial adhesion was corroborated by optical microscopy and determination of the percentage of adherent bacteria was performed on immunochemically-stained slides. Results are presented as percentage of cells with adherent Campylobacter and as number of bacteria per cell. In comparison to the control HeLa cells, the statistical analysis revealed that primary cultures show a higher percentage of infected cells and a lower variation of the evaluated parameters. This primary culture model might be useful for studies on cytopathogenicity and adhesion of different field strains of Campylobacter fetus.
Campylobacter fetus é o agente etiológico da campilobacteriose genital bovina, uma doença sexualmente transmissível que está associada com perdas reprodutivas em bovinos. Campylobacter coloniza a vagina e o útero e então infecta as células epiteliais do endométrio. O objetivo deste trabalho foi desenvolver um modelo ex vivo para quantificar a adesão de Campylobacter às células-alvo naturais específicas; este é um passo fundamental para o estabelecimento da infecção e estudos acerca da adesão e citotoxicidade sobre as células do hospedeiro natural não estão disponíveis. Os ensaios foram realizados a través da semeadura de Campylobacter fetus venerealis em culturas celulares epiteliais vaginais e uterinas.Células HeLa foram utilizadas como controle.A aderência bacteriana foi confirmada por microscopia óptica e a determinação da porcentagem de bactérias aderidas foi realizada em lâminas tingidas imunoquimicamente. Os resultados são apresentados como porcentagem de células com Campylobacter aderente e como o número de bactérias por células. Em comparação com as células HeLa controle, a análise estatística revelou que as culturas primárias mostram uma maior porcentagem de células infectadas e uma menor variação dos parâmetros avaliados. Este modelo de cultura primária pode ser útil para estudos sobre citopatogenicidade e adesão de diferentes cepas de campo de Campylobacter fetus.
Subject(s)
Animals , Cattle , Cattle , Sexually Transmitted Diseases/veterinaryABSTRACT
PURPOSE: Breast Cancer is an inter-tumoral and intra-tumoral heterogeneous disease. It remains unclear whether this heterogeneity results from different target cells or from different subsets of genetic abnormalities, otherwise from both. We postulated that in addition to genetic cloning, a variety of cells that exist during the defined developmental stages of the human mammary gland could give rise to the heterogeneity of breast cancer. To verify this postulation, we have analyzed pure ductal carcinoma in situ (DCIS) for the expression of the biomarkers that represent the mammary stem cell, the early progenitor cells, and the glandular and myoepithelial cells of the mammary gland. METHODS: We investigated the relationship between the immnuohistochemical expression of the mammary development-associated biomarkers {cytokeratin-18 (CK18), cytokeratin-6 (CK6), alpha-smooth muscle actin (SMA), Wnt-1, Notch 3} and some other factors {the menopausal status, the estrogen receptor (ER) status, the progesterone receptor (PR) status, c-erbB-2, and the number of tumor foci} in 26 cases of DCIS. RESULTS: All 26 cases included in this study showed the positive expressions of CK18 and SMA. The expression of all the markers was not correlated with the menopausal status. The positive expression of CK6 had a statistically significant relationship with a negative estrogen receptor (p=0.014), positive c-erbB-2 (p=0.048), high nuclear grade (p=0.001), and single focus of DCIS (p=0.017). The expression of Wnt-1 and Notch 3 did not have significant correlation with any factors. However, the positive expression of Wnt-1 showed a tendency of a negative ER (p=0.061) and the positive expression of Notch 3 also showed a tendency of a negative ER (p=0.086) and a high nuclear grade (p=0.086). CONCLUSION: The CK6 positive tumor is thought to originate from the more primitive cells compared to the CK6 negative tumor. Unifocality of the CK positive tumor might result from the arrest of differentiation of the original cell after disease affection. DCISs could be categorized into the CK6 positive and negative groups.
Subject(s)
Actins , Biomarkers , Breast Neoplasms , Carcinoma, Ductal , Carcinoma, Intraductal, Noninfiltrating , Clone Cells , Cloning, Organism , Estrogens , Keratin-6 , Mammary Glands, Human , Population Characteristics , Receptors, Progesterone , Stem CellsABSTRACT
Objective To explore the target cells of SARS coronavirus infection in vivo and to provide the evidence of multi organ injuries produced by SARS coronavirus infection. Methods Three biotin labeling oligonucleotide probes were synthesized according to the published gene sequence of SARS coronavirus. The location, distributtion and quantity of SARS coronavirus in 2 autopsy cases of SARS were studied by in situ hybridization and electron microscopic examination. Results SARS coronavirus particles were identified in multiple organs. In lungs, SARS coronaviruses were located predominantly in the cytoplasm of bronchiolar and alveolar epithelial cells, in a part of macrophages and endothelial cells as well as a few infiltrated lymphocytes. In situ hybridization showed that in target cells SARS coronavirus distribution presented a cytoplasmic or inclusive pattern, and the mean number of positive cells in the pulmonary tissue was 80?25 per 200? field. Electron microscopic examination showed that the coronaviral particles were 100~150 nm in diameter, with low density electron cores with halo or garland envelopes. About 15% of renal tubular epithelial cells harbored SARS coronavirus, and a few parenchymal cells and sinusoid capillary endothelial cells of adrenal glands were hybridization positive. In the gastro intestinal tract, SARS coronaviruses were seen in the cytoplasm of mucosal and crypt epithelial cells, mostly in 2/3 of superficial mocosa. Under both electron microscopy and in situ hybridization observation, SARS coronaviruses were found focally distributed in some cardiomyocytes. The SARS coronavirus positive particles were also noted in macrophages/histocytes, sinusoid endothelial cells, as well as a few lymphocytes in thoracic and celiac lymph nodes. In addition, coronavirus particles were also seen in a few testicular epithelial cells and Leydig's cells. Conclusion SARS coronavirus could attack multiple target cells, implicating that SARS might cause multi organ damages, with lungs as the predominant organ of injury.