Attention-deficit/hyperactivity disorder (ADHD) is a mental disorder with a heterogeneous origin with a global incidence that continues to grow. Its causes and pathophysiological mechanisms are not fully understood. It includes a combination of persistent symptoms such as difficulty in concentration, hyperactivity and impulsive behavior. Maternal methamphetamine (MA) abuse is a serious problem worldwide, it can lead to behavioral changes in their offspring that have similarities with behavioral changes seen in children with ADHD. There are several types of ADHD animal models, e.g. genetic models, pharmacologically, chemically and exogenously induced models. One of the exogenously induced ADHD models is the hypoxia-induced model. Our studies, as well as those of others, have demonstrated that maternal MA exposure can lead to abnormalities in the placenta and umbilical cord that result in prenatal hypoxia as well as fetal malnutrition that can result in irreversible changes to experimental animals. Therefore, the aim the present study was to compare the cognitive impairments in MA exposure model with those in established model of ADHD – prenatal hypoxia model, to test whether MA exposure is a valid model of ADHD. Pregnant Wistar rats were divided into four groups based on their gestational exposure to MA: (1) daily subcutaneous injections of MA (5 mg/kg), (2) saline injections at the same time and volume, (3) daily 1-hr hypoxia (10 % O2), and (4) no gestational exposure (controls). Male rat offspring were tested for short-term memory in the Novel Object Recognition Test and the Object Location Test between postnatal days 35 and 40. Also their locomotor activity in both tests was measured. Based on the present results, it seems that prenatal MA exposure is not the best animal model for ADHD since it shows corresponding symptoms only in certain measures. Given our previous results supporting our hypothesis, more experiments are needed to further test possible use of prenatal MA exposure as an animal model of the ADHD.
Rhagoletis pomonella (Diptera: Tephritidae) flies were exposed for 3 days in laboratory cages to yellowish, green or white surrogate leaves with or without food (sucrose) on the leaf surface. When tested in an arena minutes after fly removal from an exposure cage, yellowish surrogate leaves were more attractive to tested flies than green surrogate leaves irrespective of the nature of surrogate leaves to which flies had been exposed. However, flies exposed to green surrogate leaves having food exhibited greater propensity to alight on green surrogate leaves than flies exposed to yellowish or white surrogate leaves having food. This propensity disappeared when flies were tested 24 h after termination of exposure to green surrogate leaves having food. There was no evidence of enhanced propensity of flies exposed to yellowish surrogate leaves having food to alight on yellowish surrogate leaves when tested minutes after removal from an exposure cage. We discuss the potential ecological significance of the evidence presented here that R. pomonella flies are capable of learning to associate the presence of food with green color of leaf surface on which food could be found.
Nociceptors belong to Ad and C afferents that are equipped in the periphery with receptors for detecting potentially damaging physical and chemical stimuli. This review summarizes experimental evidence that these receptors represented by ionic channels are also functionally expressed on the cell bodies of sensory neurones in short-term cultures. The nociceptors belong predominantly to the small and medium size DRG neurones in which algogens such as weak acids, capsaicin, bradykinin and serotonin produce inward currents that can generate impulse activity. It seems likely that the neurones which are not sensitive to algogens but to GABA, ATP or glutamate, agents not producing pain in humans, belong to other categories of DRG neurones equipped for detecting other modalities of sensation. New techniques for physical stimulation of DRG neurones in culture may be of great help in the search for complementing the criteria for distinguishing nociceptors among other neurones in culture. It is suggested that such an in vitro model will be useful for studying cellular mechanisms of nociception.
The skin histology from the Danubian spined loach Cobitis elongatoides disputes the notion that the spawning marks (lighter spots on the body sides of the females) are the result of physical damage to the epidermis by a male during spawning. Physiological changes that induce a specific local decrease in lateral pigmentation in some individuals appear to be a more likely source.