Temperature and impulse velocity in giant axon of squid Loligo pealei

Inferential statistics from Black Hispanic breast cancer survival data

In this paper we test the statistical probability models for breast cancer survival data for race and ethnicity. Data was collected from breast cancer patients diagnosed in United States during the years 1973–2009. We selected a stratified random sample of Black Hispanic female patients from the Surveillance Epidemiology and End Results (SEER) database to derive the statistical probability models. We used three common model building criteria which include Akaike Information Criteria (AIC), Bayesian Information Criteria (BIC), and Deviance Information Criteria (DIC) to measure the goodness of fit tests and it was found that Black Hispanic female patients survival data better fit the exponentiated exponential probability model. A novel Bayesian method was used to derive the posterior density function for the model parameters as well as to derive the predictive inference for future response. We specifically focused on Black Hispanic race. Markov Chain Monte Carlo (MCMC) method was used for obtaining the summary results of posterior parameters. Additionally, we reported predictive intervals for future survival times. These findings would be of great significance in treatment planning and healthcare resource allocation.

A comparison of propagated action potentials from tropical and temperate squid axons: different durations and conduction velocities correlate with ionic conductance levels

To determine which physiological properties contribute to temperature adaptation in the squid giant axon, action potentials were recorded from four species of squid whose habitats span a temperature range of 20°C. The environments of these species can be ranked from coldest to warmest as follows: Loligo opalescens>Loligo pealei>Loligo plei>Sepioteuthis sepioidea. Action potential conduction velocities and rise times,recorded at many temperatures, were equivalent for all Loligospecies, but significantly slower in S. sepioidea. By contrast, the action potential's fall time differed among species and correlated well with the thermal environment of the species (`warmer' species had slower decay times). The biophysical underpinnings of these differences were examined in voltage-clamped axons. Surprisingly, no differences were found between the activation kinetics or voltage-dependence of Na+ and K+currents. Conductance levels, however, did vary. Maximum Na+conductance (gNa) in S. sepiodea was significantly less than in the Loligo species. K+ conductance (gK) was highest in L. pealei, intermediate in L. plei and smallest in S. sepiodea. The time course and magnitude of gK and gNa were measured directly during membrane action potentials. These data reveal clear species-dependent differences in the amount of gK and gNa recruited during an action potential.

Effects of temperature on escape jetting in the squid Loligo opalescens

In Loligo opalescens, a sudden visual stimulus (flash) elicits a stereotyped, short-latency escape response that is controlled primarily by the giant axon system at 15 C. We used this startle response as an assay to examine the effects of acute temperature changes down to 6 C on behavioral and physiological aspects of escape jetting. In free-swimming squid, latency, distance traveled and peak velocity for single escape jets all increased as temperature decreased. In restrained squid, intra-mantle pressure transients during escape jets increased in latency, duration and amplitude at low temperature. Recordings of stellar nerve activity revealed repetitive firing of the giant motor axon accompanied by increased activity in the non-giant motor axons that run in parallel. Selective stimulation of giant and non-giant motor axons in isolated nerve-muscle preparations failed to show the effects seen in vivo, i.e. increased peak force and increased neural activity at low temperature. Taken together, these results suggest that L. opalescens is able to compensate escape jetting performance for the effects of acute temperature reduction. A major portion of this compensation appears to occur in the central nervous system and involves alterations in the recruitment pattern of both the giant and non-giant axon systems.

Phase transitions and ion currents in a model ferroelectric channel unit

The hypothesis of ferroelectric electrodiffusion is examined mathematically. A thermodynamic potential, the elastic Gibbs function, written in polynomial form, provides the dielectric equation of state for the model. The other equations of electrodiffusion theory complete the model. This system reduces to a second-order partial differential equation, which is formally solved by the phase-plane method. This solution, applied to the Na channel, leads to a propagating phase-transition wave accompanied by movement of ionic charge. This may be readily interpreted as a transmembrane wave traveling along a ferroelectric unit within, and transporting ions through, the channel. Comparison of the temperature dependence of axonal conduction velocity with that of the spontaneous polarization of Rochelle salt suggests that the Na channel of squid axon contains a ferroelectric unit having a lower Curie point, but decomposing before reaching its upper Curie point. Comparison with data from reconstitution experiments suggests that the ferroelectric unit is a carbohydrate enclosed in an intrinsic protein structure to form a glycoprotein channel. The value experimentally estimated for the surface charge of the Na channel is within the range of spontaneous polarizations of typical ferroelectric crystals. It is argued that the ferroelectric probably is a single crystal of the order-disorder type, which undergoes a first-order transition between a ferroelectric and a paraelectric state during excitational activity. The hypothesis of ferroelectric channel units is consistent with the existence and directionality of the observed "gating" currents.

Temperature-induced changes in fatty acid composition of myelinated and non-myelinated axon phospholipids

The olfactory (non-myelinated) and trigeminal (myelinated) nerve axons of garfish show changes in phospholipid fatty acid composition when these fish are acclimated to temperatures ranging from 11 to 35 degrees C. Myelinated and non-myelinated nerve axons show similar changes in the percent saturated, percent 16-carbon, percent 18-carbon, and percent 20-carbon-and-greater unsaturated fatty acids. The observed changes in phospholipid fatty acid composition fit a linear regression model suggesting a gradual change in axonal phospholipid fatty acid composition with temperature. The temperature-induced changes in garfish nerve phospholipid fatty acid composition are consistent with the general observation of increased saturated fatty acid residues in plasma membrane phospholipids of organisms acclimated to higher environmental temperatures. The garfish data are similar to data previously obtained for goldfish tissues and Tetrahymena.

Properties of sodium and potassium channels of the squid giant axon far below 0 degrees C

Squid giant axon could be excited in concentrated glycerol solutions containing normal concentrations of electrolytes, when osmolalities of solutions inside and outside the axon were matched. These glycerol solutions did not freeze at the temperature as low as -19 degrees C. The nerve excitation in these solutions were observed at this low temperature. The excitation process at this low temperature was slowed down and time constants of the excitation kinetics were several hundredfold larger than those in normal seawater at 10 degrees C, under which temperature the squid habituated. The temperature coefficients for the electrophysiological membrane parameters under this condition were larger than those in normal seawater above 0 degrees C. The Q10 value for the conduction velocity was 2.0 and that of the duration of the action potential was around 8.5. The time course of the membrane currents was also slowed with the Q10 value of around 5 and the magnitude decreased with the Q10 value of around 2 as the temperature was lowered. The Q10 values for the kinetics of the on process of the Na-channel were around 4.5 and were almost the same as those of the off process of the Na-channel in the wide range of the temperature below 0 degrees C. The Q10 value of the on process of K-channel was around 6.5 and was larger than those for Na-channel. The Q10 values increased gradually as the temperature was lowered.

Changes in unmyelinated fibers including sympathetic postganglionic fibers of a skin nerve after peripheral neuroma formation

Conduction velocities of unmyelinated fibers and proportions of postganglionic fibers which can be activated from the lumbar sympathetic trunk were determined for the superficial peroneal nerve of the cat's hindlimb. The nerve was either left intact (4 control experiments) or cut and ligated peripherally 6-245 days before the experiments so that neuromata developed (15 experiments). Additionally, 3 control experiments were performed on the sural nerve. Our findings are that about 20-30% of all unmyelinated fibers in intact skin nerves are postganglionic sympathetic fibers. This percentage of postganglionic axons, which can be activated from the preganglionic side, decreases to 0-7% 100 days or more after the nerve section. In intact skin nerves the conduction velocity of the afferent unmyelinated fibers is greater (mean +/- 1 S.D.: 0.88 +/- 0.17 m/s) than that of postganglionic axons (0.69 +/- 0.14 m/s). The conduction velocities in both types of axons decrease by 25-30% in nerves with peripheral neuroma. This occurs largely during the first 15 days following the nerve section described.

Excitation of squid giant axons below 0 degree C

The excitation of the squid giant axon that had been perfused intra- and extracellularly with solutions containing a high concentration of glycerol could be observed below 0 degree C. The action potential could be elicited at normal strengths of electrical stimuli. The time-course of the action potential was slowed, whereas the resting potential and the amplitude of the action potential changed only slightly. The membrane current under the voltage clamp at -6.3 degrees C was about 100-fold slower than that in normal sea water at 8.7 degrees C because of the large viscosity of glycerol solutions and the low temperature. The Q10 values of the magnitude and the time-course of the membrane current were 2.3 and 1/4.0, respectively.