Rodent models produce data which underpin biomedical research and non-clinical drug trials, but translation from rodents into successful clinical outcomes is often lacking. There is a growing body of evidence showing that improving experimental design is key to improving the predictive nature of rodent studies and reducing the number of animals used in research. Age, one important factor in experimental design, is often poorly reported and can be overlooked. The authors conducted a survey to assess the age used for a range of models, and the reasoning for age choice. From 297 respondents providing 611 responses, researchers reported using rodents most often in the 6–20 week age range regardless of the biology being studied. The age referred to as ‘adult’ by respondents varied between six and 20 weeks. Practical reasons for the choice of rodent age were frequently given, with increased cost associated with using older animals and maintenance of historical data comparability being two important limiting factors. These results highlight that choice of age is inconsistent across the research community and often not based on the development or cellular ageing of the system being studied. This could potentially result in decreased scientific validity and increased experimental variability. In some cases the use of older animals may be beneficial. Increased scientific rigour in the choice of the age of rodent may increase the translation of rodent models to humans.
1. The objective of the experiments was to explore the modulatory functions of the serotonergic cerebral giant cells (CGCs) of the Lymnaea feeding system by examining their synaptic connections with the central pattern generator (CPG) interneurons and the modulatory slow oscillator (SO) interneuron. 2. One type of modulatory function, "gating," requires that the CGCs fire tonically at a minimum of 7 spikes/min. Above this minimum level the CGCs control the frequency of CPG interneuron oscillation-- "frequency control," a second type of modulation. In an SO-driven fictive feeding rhythm, an increase in the frequency of the rhythm, with increased CGC firing rate, resulted from a reduction in the duration of the N1 (protraction) and N2 (rasp) phases of the feeding cycle with little effect on the N3 (swallow) phase. 3. The CGCs excited the N1 phase interneurons SO and N1M (N1 medial) cells but had no consistent effects on the N1 lateral cells. The CGC-->SO postsynaptic response was probably monosynaptic (< or = 200 ms in duration) with unitary 1:1 excitatory postsynaptic potentials (EPSPs) following each CGC spike. The CGC-->N1M excitatory response was slow and nonunitary, and a burst of CGC spikes evoked a depolarization of the N1M cells that lasted up to 10 s and triggered N1M cell bursts. Both CGC-->SO and CGC-->N1M excitatory responses could be mimicked by the focal application of serotonin (5-HT). 4. Both CGC-->SO and CGC-->N1M excitatory connections systematically increased the N1M cell firing rate within the CGCs' physiological firing range (0-40 spikes/min). This was due to both the direct (CGC-->N1M) and indirect (CGC-->SO-->N1M) excitatory synaptic pathways. The CGC-induced increase in N1M cell firing rate probably accounted for the reduced duration of the N1M cell feeding burst by causing a more rapid reversal of the feeding cycle from the N1 phase to the N2 phase. This phase reversal was due to the previously described recurrent inhibitory pathway (N1-->N2 excitation followed by N2-->N1 inhibition). 5. The CGCs' ability to provide a depolarizing drive to the N1M cells meant that this excitatory connection was also likely to be important for gating. 6. Activity in the CGCs produced nonunitary, long-lasting, excitatory postsynaptic responses on the N2 ventral (N2v) CPG interneurons, and these were likely to be involved in both the gating and the frequency control by the CGCs on the N2 phase of the feeding rhythm. Suppressing CGC tonic firing initially increased the duration of the N2v plateau (which determines the duration of the N2 phase of the feeding cycle, frequency function) but eventually led to a loss of N2v plateauing (gating function). 7. Nonunitary, weakly inhibitory CGC-->N2 dorsal responses were recorded that could be mimicked by the application of 5-HT. 8. Spikes in the CGCs evoked 1:1 monosynaptic EPSPs in the N3 tonic (N3t) CPG interneurons. This excitatory effect could be mimicked by the application of 5-HT. Within the physiological range of CGC firing, this excitation did not appear to infl...
Background: The freshwater snail Lymnaea stagnalis (L. stagnalis) has served as a successful model for studies in the field of Neuroscience. However, a serious drawback in the molecular analysis of the nervous system of L. stagnalis has been the lack of large-scale genomic or neuronal transcriptome information, thereby limiting the use of this unique model.
We aimed to show that the paired N2v (N2 ventral) plateauing cells of the buccal ganglia are important central pattern generator (CPG) interneurons of the Lymnaea feeding system. N2v plateauing is phase-locked to the rest of the CPG network in a slow oscillator (SO)-driven fictive feeding rhythm. The phase of the rhythm is reset by artificially evoked N2v bursts, a characteristic of CPG neurons. N2v cells have extensive input and output synaptic connections with the rest of the CPG network and the modulatory SO cell and cerebral giant cells (CGCs). Synaptic input from the protraction phase interneurons N1M (excitatory), N1L (inhibitory), and SO (inhibitory-excitatory) are likely to contribute to a ramp-shaped prepotential that triggers the N2v plateau. The prepotential has a highly complex waveform due to progressive changes in the amplitude of the component synaptic potentials. Most significant is the facilitation of the excitatory component of the SO --> N2v monosynaptic connection. None of the other CPG interneurons has the appropriate input synaptic connections to terminate the N2v plateaus. The modulatory function of acetylcholine (ACh), the transmitter of the SO and N1M/N1Ls, was examined. Focal application of ACh (50-ms pulses) onto the N2v cells reproduced the SO --> N2v biphasic synaptic response but also induced long-term plateauing (20-60 s). N2d cells show no endogenous ability to plateau, but this can be induced by focal applications of ACh. The N2v cells inhibit the N3 tonic (N3t) but not the N3 phasic (N3p) CPG interneurons. The N2v --> N3t inhibitory synaptic connection is important in timing N3t activity. The N3t cells recover from this inhibition and fire during the swallow phase of the feeding pattern. Feedback N2v inhibition to the SO, N1L protraction phase interneurons prevents them firing during the retraction phase of the feeding cycle. The N2v --> N1M synaptic connection was weak and only found in 50% of preparations. A weak N2v --> CGC inhibitory connection prevents the CGCs firing during the rasp (N2) phase of the feeding cycle. These data allowed a new model for the Lymnaea feeding CPG to be proposed. This emphasizes that each of the six types of CPG interneuron has a unique set of synaptic connections, all of which contribute to the generation of a full CPG pattern.
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