Long-term Maintenance of Reduced Intraocular Pressure by Daily or Twice Daily Topical Application of Prostaglandins to Cat or Rhesus Monkey Eyes

Substantial evidence indicates that a single topical application of prostaglandins (PGs) can reduce intraocular pressure (IOP) in the eyes of several species. However, earlier literature, dealing with ocular hypertensive and inflammatory responses, shows the development of tachyphylaxis to subsequent doses of PGs. If similar tolerance developed to the ocular hypotensive effects of PGs, it would preclude the use of these agents in the treatment of chronic glaucoma. The present study shows, however, that although tachyphylaxis to the ocular hypotensive effects of PGs develops in rabbits, this is not a typical response among mammals. Significant IOP reduction was maintained in cats for up to 9 months by topical application of PGE 2 at 12-, 24-, or 48-hr intervals. The IOP reduction was jeopardized seriously only when the PG was applied every other day for several days or when, on a few occasions, 3 days were allowed to elapse between PGE 2 applications. Ocular hypotension was also maintained during the course of topical treatment of rhesus monkey eyes with PGF 2a . Short periods of pupillary constriction followed the application of each dose of PGF 2a to cat eyes, but the miotic response of rhesus monkeys to PGF 2a and cats to PGE 2 was negligible. Other apparent side effects were noted, but none of these were severe or progressive. These results clearly demonstrate that tachyphylaxis, or tolerance, is not expected to present an obstacle to the development of eicosanoids and/or their derivatives as therapeutic agents for the long-term treatment of ocular hypertension and chronic glaucoma. Invest Ophthalmol Vis Sci 24: [312][313][314][315][316][317][318][319] 1983 Early studies on the effects of prostaglandins (PGs) on the eye, primarily designed to determine the role of these autacoids in the ocular irritative response, concluded that exogenous PGs can produce increased intraocular pressure (IOP) and breakdown of the blood-aqueous barrier. 1 It has recently been shown, however, that appropriate doses of PGF 2a topically applied to the eyes of rabbits, 2 owl monkeys, 3 rhesus monkeys, and cats 4 can, in fact, reduce rather than increase IOP. In the rabbit there is only a narrow margin between the hypotensive dose of PGF 2a and a dose that causes initial hypertension. 2 Ten-to 100-fold higher PGF 2a doses than those that reduce IOP in the rabbit are required to produce the same effect in owl monkeys, rhesus monkeys, and cats, but eve

Human Perception of Fear in Dogs Varies According to Experience with Dogs

To investigate the role of experience in humans’ perception of emotion using canine visual signals, we asked adults with various levels of dog experience to interpret the emotions of dogs displayed in videos. The video stimuli had been pre-categorized by an expert panel of dog behavior professionals as showing examples of happy or fearful dog behavior. In a sample of 2,163 participants, the level of dog experience strongly predicted identification of fearful, but not of happy, emotional examples. The probability of selecting the “fearful” category to describe fearful examples increased with experience and ranged from.30 among those who had never lived with a dog to greater than.70 among dog professionals. In contrast, the probability of selecting the “happy” category to describe happy emotional examples varied little by experience, ranging from.90 to.93. In addition, the number of physical features of the dog that participants reported using for emotional interpretations increased with experience, and in particular, more-experienced respondents were more likely to attend to the ears. Lastly, more-experienced respondents provided lower difficulty and higher accuracy self-ratings than less-experienced respondents when interpreting both happy and fearful emotional examples. The human perception of emotion in other humans has previously been shown to be sensitive to individual differences in social experience, and the results of the current study extend the notion of experience-dependent processes from the intraspecific to the interspecific domain

The parent?infant dyad and the construction of the subjective self

Developmental psychology and psychopathology has in the past been more concerned with the quality of self-representation than with the development of the subjective agency which underpins our experience of feeling, thought and action, a key function of mentalisation. This review begins by contrasting a Cartesian view of pre-wired introspective subjectivity with a constructionist model based on the assumption of an innate contingency detector which orients the infant towards aspects of the social world that react congruently and in a specifically cued informative manner that expresses and facilitates the assimilation of cultural knowledge. Research on the neural mechanisms associated with mentalisation and social influences on its development are reviewed. It is suggested that the infant focuses on the attachment figure as a source of reliable information about the world. The construction of the sense of a subjective self is then an aspect of acquiring knowledge about the world through the caregiver's pedagogical communicative displays which in this context focuses on the child's thoughts and feelings. We argue that a number of possible mechanisms, including complementary activation of attachment and mentalisation, the disruptive effect of maltreatment on parent-child communication, the biobehavioural overlap of cues for learning and cues for attachment, may have a role in ensuring that the quality of relationship with the caregiver influences the development of the child's experience of thoughts and feelings

The development of spontaneous facial responses to others’ emotions in infancy. An EMG study

Viewing facial expressions often evokes facial responses in the observer. These spontaneous facial reactions (SFRs) are believed to play an important role for social interactions. However, their developmental trajectory and the underlying neurocognitive mechanisms are still little understood. In the current study, 4- and 7-month old infants were presented with facial expressions of happiness, anger, and fear. Electromyography (EMG) was used to measure activation in muscles relevant for forming these expressions: zygomaticus major (smiling), corrugator supercilii (frowning), and frontalis (forehead raising). The results indicated no selective activation of the facial muscles for the expressions in 4-month-old infants. For 7-month-old infants, evidence for selective facial reactions was found especially for happy faces (leading to increased zygomaticus major activation) and fearful faces (leading to increased frontalis activation), while angry faces did not show a clear differential response. This suggests that emotional SFRs may be the result of complex neurocognitive mechanisms which lead to partial mimicry but are also likely to be influenced by evaluative processes. Such mechanisms seem to undergo important developments at least until the second half of the first year of life