Nodular basal cell carcinoma in vivo vs in vitro. Establishment of pure cell cultures, cytomorphologic characteristics, ultrastructure, immunophenotype, biosynthetic activities, and generation of antisera

BACKGROUND AND DESIGN: In this study we developed an in vitro model of nodular basal cell carcinoma (BCC). We obtained pure cultures of BCC cells and compared the morphologic characteristics, ultrastructure, immunophenotype, and behavior of cultured tumor cells with those of their in vivo counterparts. Tumors were excised from patients undergoing Mohs micrographic surgery. We established 69 primary cell cultures from 32 patients with nodular BCC. RESULTS: Three cell types grew in primary cultures: fibroblasts, normal-appearing keratinocytes, and cells with dual (spindle and epithelioid) morphologic characteristics. Contaminating fibroblasts were removed using 0.125% trypsin-0.02% edetic acid, and normal-appearing keratinocytes were cornified and eliminated by temporarily increasing the concentration of calcium in the growth medium. The cells with dual morphologic characteristics remained intact and exhibited relentless growth in pure cultures. That these seemingly immortal cell strains represent true nodular BCC was demonstrated by (1) their biphasic morphologic characteristics and very slow cell growth rate, (2) their capability for anchorage-independent growth in soft agar, (3) their ultrastructural similarities to freshly excised nodular BCC, (4) their ability to generate antibodies selectively labeling nodular BCC tumor nests in vivo, and (5) their immunophenotypic similarities to BCC in vivo on more than 20 different cell markers. CONCLUSIONS: This study provides a simple technique for establishing pure cell cultures of nodular BCC and describes extensively the in vitro parameters of tumor cell growth. The striking differences in behavior of cultured tumor cells in the presence or absence of normal-appearing keratinocytes suggest that normal human epidermal keratinocytes can suppress the growth of BCC cells.     

Calcium induced contracture stimulates Na,K-pump rate in isolated sheep cardiac Purkinje fibers

By keeping intracellular Na+ (aiNa) low, the Na,K-pump can prevent Ca2+ overload of cardiomyocytes. We therefore examined whether Ca2+ stimulates Na,K-pump activity in sheep cardiac Purkinje fibers. By removing Ca2+, Mg2+ and K+, the fibers depolarized and aiNa rose to 70 mM. After addition of 6 mM Mg2+ and lowering extracellular Na2+ to 29 mM, 30mM Rb+ was added, and over 10-15 min aiNa recovered to 3-7 mM. Two load-recovery cycles were conducted in 10 fibers. During one of the cycles Ca2+ (0.1-1.0 mM) was added before Rb+, causing a contracture. During recovery aiNa fell faster during Ca2+ contracture than in control cycles. Between 30 and 20 mM the rates were -10.0+/-1.6 and -5.4+/-0.6 mM/min, respectively (P<0.05). In Ca2+-exposed fibers tension fell almost parallel with aiNa. Na, K-pump reactivation caused membrane potential (Vm) to hyperpolarize transiently to -70 mV. Ca2+ did not affect membrane conductance. For a given aiNa during reactivation, Vm was more negative during Ca2+ contracture and depolarized faster (P<0.05). Intracellular pH (pHi) fell from 7.11+/-0.05 to 6.92+/-0.08 (n.s.) during control load-recovery cycles and was 6.83+/-0.14 at the end of the Ca2+ cycles. ATP content of the fibers did not change significantly through two complete load-recovery cycles, but creatine phosphate (CrP) fell by about 40%. By fitting the data to a model incorporating the Hill equation we show that during Ca2+-induced contracture maximum Na,K-pump rate (Vmax) was increased by about 40% and aiNa that causes 50% pump activation (k0.5) was lowered from 21. 2+/-1.6 to 15.5+/-1.4 mM.     

Influence of conductive electroactive polymer polyaniline on electrochemical performance of LiMn1·95Al0·05O4 cathode for lithium ion batteries

Conductive electroactive polymer polyaniline is utilized to substitute conductive additive acetylene black in the LiMn_1·95Al_0·05O₄ cathode for lithium ion batteries. Results show that LiMn_1·95Al_0·05O₄ possesses stable structure and good performance. Percolation theory is used to optimize the content of conductive additive in cathode. It shows that the conductivity of cathode reaches its maximum value when the content of conductive additives is 15 wt%. This is in agreement with the results of charge and discharge experiments. The application of polyaniline can evidently enhance the electrochemical performance of cathode. The discharge capacity of cathode using 15 wt% polyaniline is 95·9 mAh g^???1 at the current density of 170 mA g^???1. The charge transfer resistance under different depths of discharge of cathode is much lower compared with the use of acetylene black. It can be concluded that the application of polyaniline in cathode can greatly improve the electrochemical performances of LiMn_1·95Al_0·05O₄ cathode.