Survival improvements of marine mammals in zoological institutions mirror historical advances in human longevity.

An intense public debate has fuelled governmental bans on marine mammals held in zoological institutions. The debate rests on the assumption that survival in zoological institutions has been and remains lower than in the wild, albeit the scientific evidence in support of this notion is equivocal. Here, we used statistical methods previously applied to assess historical improvements in human lifespan and data on 8864 individuals of four marine mammal species (harbour seal, Phoca vitulina; California sea lion, Zalophus californianus; polar bear, Ursus maritimus; common bottlenose dolphin, Tursiops truncatus) held in zoos from 1829 to 2020. We found that life expectancy increased up to 3.40 times, and first-year mortality declined up to 31%, during the last century in zoos. Moreover, the life expectancy of animals in zoos is currently 1.65-3.55 times longer than their wild counterparts. Like humans, these improvements have occurred concurrently with advances in management practices, crucial for population welfare. Science-based decisions will help effective legislative changes and ensure better implementation of animal care.

Transmission beam pattern and dynamics of a spinner dolphin (Stenella longirostris).

Toothed whales possess a sophisticated biosonar system by which ultrasonic clicks are projected in a highly directional transmission beam. Beam directivity is an important biosonar characteristic that reduces acoustic clutter and increases the acoustic detection range. This study measured click characteristics and the transmission beam pattern from a small odontocete, the spinner dolphin (Stenella longirostis). A formerly stranded individual was rehabilitated and trained to station underwater in front of a 16-element hydrophone array. On-axis clicks showed a mean duration of 20.1 µs, with mean peak and centroid frequencies of 58 and 64 kHz [standard deviation (s.d.) ±30 and ±12 kHz], respectively. Clicks were projected in an oval, vertically compressed beam, with mean vertical and horizontal beamwidths of 14.5° (s.d. ± 3.9) and 16.3° (s.d. ± 4.6), respectively. Directivity indices ranged from 14.9 to 27.4 dB, with a mean of 21.7 dB, although this likely represents a broader beam than what is normally produced by wild individuals. A click subset with characteristics more similar to those described for wild individuals exhibited a mean directivity index of 23.3 dB. Although one of the broadest transmission beams described for a dolphin, it is similar to other small bodied odontocetes.

Training techniques to enhance the care and welfare of nonhuman primates.

Nonhuman primates are excellent subjects for the enhancement of care and welfare through training. The application of positive reinforcement techniques to specific aspects of the management of captive nonhuman primates spans a wide range of species, social contexts, and housing situations (eg, laboratories, zoos, and sanctuaries). There is an increased interest from regulatory and accrediting agencies to insure improved conditions for captive nonhuman primates, apparent by the various standard guidelines, accreditation standards, and protocols available for the 3 primary types of nonhuman primate holding facilities.

Enhancing nonhuman primate care and welfare through the use of positive reinforcement training.

Nonhuman primates are excellent subjects for the enhancement of care and welfare through training. The broad range of species offers tremendous behavioral diversity, and individual primates show varying abilities to cope with the stressors of captivity, which differ depending on the venue. Biomedical facilities include small single cages, pair housing, and breeding corrals with large social groups. Zoos have social groupings of differing sizes, emphasizing public display and breeding. Sanctuaries have nonbreeding groups of varying sizes and often of mixed species. In every venue, the primary objective is to provide good quality care, with minimal stress. Positive reinforcement training improves care and reduces stress by enlisting a primate's voluntary cooperation with targeted activities, including both husbandry and medical procedures. It can also improve socialization, reduce abnormal behaviors, and increase species-typical behaviors. This article reviews the results already achieved with positive reinforcement training and suggests further possibilities for enhancing primate care and welfare.

The use of positive reinforcement training techniques to enhance the care, management, and welfare of primates in the laboratory.

Handled frequently and subjected to a wide range of medical procedures that may be particularly invasive, nonhuman animals in a laboratory setting have unique needs. To produce the most reliable research results and to protect and enhance the well-being of the animals, it is desirable to perform these procedures with as little stress for the animals as possible. Positive reinforcement training can use targeted activities and procedures to achieve the voluntary cooperation of nonhuman primates. The benefits of such work include diminished stress on the animals, enhanced flexibility and reliability in data collection, and a reduction in the use of anesthesia. Training also provides the means to mitigate social problems, aid in introductions, reduce abnormal behavior, enhance enrichment programs, and increase the safety of attending personnel. This article describes the application of operant conditioning techniques to animal management.

Positive reinforcement training as a technique to alter nonhuman primate behavior: quantitative assessments of effectiveness.

Many suggest that operant conditioning techniques can be applied successfully to improve the behavioral management of nonhuman primates in research settings. However, relatively little empirical data exist to support this claim. This article is a review of several studies that discussed applied positive reinforcement training techniques (PRT) on breeding/research colonies of rhesus macaques (Macaca mulatta) and chimpanzees (Pan troglodytes) at The University of Texas M. D. Anderson Cancer Center and measured their effectiveness. Empirical analyses quantified the amount of time required to train rhesus monkeys to come up, station, target, and stay. Additionally, a study found that time spent affiliating by female rhesus was changed as a function of training low affiliators to affiliate more and high affiliators to affiliate less. Another study successfully trained chimpanzees to feed without fighting and to come inside on command. PRT is an important behavioral management tool that can improve the care and welfare of primates in captivity. Published empirical findings are essential for managers to assess objectively the utility of positive reinforcement training techniques in enhancing captive management and research procedures.

Behavioral management: it's everyone's job.

In this day and age of regulatory demands and with the ever-increasing flow of environmental enhancement data and opinions, it can become very confusing for animal programs to create and maintain a successful behavioral management program. Behavioral management as a concept provides a common ground from which animal facilities may start to build a successful facility behavioral program. In addition, the implementation of a behavioral management program can help to break down barriers between members of the various disciplines within the biomedical community. It is everyone's responsibility and duty to work together with this common goal: to provide the best care and environment we can for the animals in our charge. Working together to improve animal behavior can help us to achieve this goal.