Model of interstitial pressure as a result of cyclical changes in the capillary wall fluid transport.

Reported interstitial pressures range from -8 to +6 mm Hg in different tissues and from <-20 mm Hg in burned tissue or more than +30 mm Hg in tumors. We have tried to link interstitial pressure to the here proposed cyclical changes in the fluid transport across the capillary wall. In the presented model interstitial pressure is considered as an average of pressures in numerous pericapillary spaces. A single pericapillary pressure is a dynamic difference between the net outward (hydraulic pressure+interstitial colloid osmotic pressure) and inward (plasma colloid oncotic pressure) forces. Hence, dominating net outward forces would result in a positive pericapillary interstitial pressure, while stronger inward forces would produce negative pressures in the pericapillary space. All interruptions of blood flow leave some blood in capillaries with a normal oncotic pressure and no hydrostatic pressure that might act as a strong absorber of interstitial fluid until the blood flow is reestablished. Model assumptions for the systemic circulation capillaries include (a) precapillary sphincters can almost entirely stop the capillary flow, (b) only a minority of sphincters are normally open in the tissue, and (c) hydrostatic pressures in unperfused capillaries are similar to the pressures at their venous ends. The key proposal is that capillaries with closed precapillary sphincters along their entire length have low hydrostatic pressure of 10 to 15 mm Hg. This pressure cannot force filtration, so these capillaries reabsorb interstitial fluid from the pericapillary space along their entire length. In the open capillaries, hydrostatic pressure filtrates fluid to the pericapillary space along most of their length. Fluid enters, moves some 20 or 30 micrometers away and back to be reabsorbed at the same point. Closed periods are periods of intense fluid reabsorption, while the short open periods refill the space with fresh fluid. It can be calculated that subcutaneous tissue interstitial pressure values might develop if the closed periods are 1.14 to 2.66 times longer than the open periods. Positive interstitial pressures observed in some organs might develop if open periods are longer than the closed periods. High interstitial colloid pressure in lungs makes both perfused and unperfused capillaries absorptive, resulting in more negative values of lung interstitial pressure. The same model is used to explain interstitial pressure values in tumors, burned tissue and intestinal villi.

Differentiation of rat neural tissue in a serum-free embryo culture model followed by in vivo transplantation.

AIM: To analyze neural tissue differentiation in a unique, chemically-defined in vitro culture model of gastrulating rat embryo proper by use of transmission electron microscopy (TEM), proliferating cell nuclear antigen (PCNA) expression, and in vivo transplantation after a 2-week culture in serum-free or serum-supplemented media. Influence of protein-free medium unfavorable for differentiation of neural tissue in vitro was compared with favorable serum-free media enriched with transferrin or albumin. Differentiation of mesodermal derivatives in transplants was also investigated. METHODS: We cultivated 9.5-day-old Fischer rat embryos on the gas-liquid interface in the protein-free Eagle's Minimum Essential Medium (MEM), in MEM with either iron-saturated holotransferrin (50 microg/mL) or iron-free apotransferrin (50 microg/mL), and in medium saturated with either bovine serum albumin (BSA) (4 mg/mL or 400 microg/mL) or rat serum (50%). After the two-week culture period, light microscopy, TEM, and immunohistochemical method for detection of PCNA were done. Some explants were transplanted under the kidney capsule of adult male rats to be cultured in vivo for additional two weeks. Chi-square test or Fisher exact test were used to compare the proportion of tissues developed. RESULTS: Proportion of differentiated neural tissue was similar in explants cultivated in apotransferrin- and holotransferrin-supplemented media (13/33 and 9/20, respectively), but higher than in explants cultivated in protein-free medium (1/13). Neurons and glia cells produced a neuropil structure. Myelinization occurred only in serum-supplemented medium. PCNA expression was detected in a small number of neural tissue cells, even in serum-free cultivated embryos. Differentiation of brain-like tissue, cerebrospinal, and vegetative ganglionic cells occurred in all groups of transplants. However, in the transplants derived from protein-free medium, the proportion of neural tissue, cartilage, bone, skeletal and smooth muscle was significantly lower than in transferrin-supplemented media (p<0.01). Albumin seemed to promote differentiation of all tissues except vegetative ganglionic cells. CONCLUSION: Nerve tissue differentiated to a rather high degree in a two-week in vitro postimplantation embryo culture. Transferrin or albumin, as the only proteins used for serum-free precultivation, significantly improved subsequent differentiation of nerve tissue and mesodermal derivatives in transplants in vivo.

Chemically defined protein-free in vitro culture of mammalian embryo does not restrict its developmental potential for differentiation of skin appendages.

In a unique serum- and protein-free chemically defined in vitro culture model of postimplantation mammalian development the epidermis differentiates regularly, although the differentiation of other tissues is impaired due to the lack of the serum. The present study in that model was done to estimate more carefully the degree of epidermal differentiation in defined media supplemented with some growth- or differentiation-stimulating substances. The main objective was to discover by grafting in vivo to the richer environment whether simple protein-free culture conditions restrict an inherent embryonic potential for differentiation of skin appendages. Embryonic parts of E9.5 gastrulating Fischer rat embryos were cultivated for 2 weeks in the protein-free Eagle's minimum essential medium supplemented with holotransferrin, apotransferrin, insulin and/or Na(2)SeO(3) and in controls cultivated in protein-free medium or in serum-supplemented medium. In all experiments there was a high incidence of differentiation of the epidermis. A high level of epidermal differentiation was confirmed for the first time at the ultrastructural level. A well-differentiated cornified layer and cells connected with desmosomes containing keratohyaline masses and cytokeratin filaments were found. A strong immunohistochemical signal for the proliferating cell nuclear antigen was always detected in the basal layer of the epidermis showing that those cells were still able to proliferate. Finally, embryos precultivated for 1 or 2 weeks in the protein-free medium and media supplemented with apotransferrin or serum were grafted under the kidney capsule for an additional 2 weeks. It was discovered that even after spending 2 weeks in the simple protein-free medium in vitro, embryos retained their developmental potential for differentiation of skin appendages (hair and sebaceous glands).