Position and Orientation Insensitive Wireless Power Transmission for EnerCage-Homecage System.

We have developed a new headstage architecture as part of a smart experimental arena, known as the EnerCage-HC2 system, which automatically delivers stimulation and collects behavioral data over extended periods with minimal small animal subject handling or personnel intervention in a standard rodent homecage. Equipped with a four-coil inductive link, the EnerCage-HC2 system wirelessly powers the receiver (Rx) headstage, irrespective of the subject's location or head orientation, eliminating the need for tethering or carrying bulky batteries. On the transmitter (Tx) side, a driver coil, five high-quality (Q) factor segmented resonators at different heights and orientations, and a closed-loop Tx power controller create a homogeneous electromagnetic (EM) field within the homecage 3-D space, and compensate for drops in power transfer efficiency (PTE) due to Rx misalignments. The headstage is equipped with four small slanted resonators, each covering a range of head orientations with respect to the Tx resonators, which direct the EM field toward the load coil at the bottom of the headstage. Moreover, data links based on Wi-Fi, UART, and Bluetooth low energy are utilized to enables remote communication and control of the Rx. The PTE varies within 23.6%-33.3% and 6.7%-10.1% at headstage heights of 8 and 20 cm, respectively, while continuously delivering >40 mW to the Rx electronics even at 90° rotation. As a proof of EnerCage-HC2 functionality in vivo, a previously documented on-demand electrical stimulation of the globus pallidus, eliciting consistent head rotation, is demonstrated in three freely behaving rats.

Cavity Resonator Wireless Power Transfer System for Freely Moving Animal Experiments.

OBJECTIVE: The goal of this paper is to create a large wireless powering arena for powering small devices implanted in freely behaving rodents. METHODS: We design a cavity resonator based wireless power transfer (WPT) system and utilize our previously developed optimal impedance matching methodology to achieve effective WPT performance for operating sophisticated implantable devices, made with miniature receive coils (<8 mm in diameter), within a large volume (dimensions: 60.96 cm × 60.96 cm × 30 cm). We provide unique cavity design and construction methods which maintains electromagnetic performance of the cavity while promoting its utility as a large animal husbandry environment. In addition, we develop a biaxial receive resonator system to address device orientation insensitivity within the cavity environment. Functionality is demonstrated with chronic experiments involving rats implanted with our custom designed bioelectric recording device. RESULTS: We demonstrate an average powering fidelity of 93.53% over nine recording sessions across nine weeks, indicating nearly continuous device operation for a freely behaving rat within the large cavity resonator space. CONCLUSION: We have developed and demonstrated a cavity resonator based WPT system for long term experiments involving freely behaving small animals. SIGNIFICANCE: This cavity resonator based WPT system offers an effective and simple method for wirelessly powering miniaturized devices implanted in freely moving small animals within the largest space.

A Wirelessly-Powered Homecage With Segmented Copper Foils and Closed-Loop Power Control.

A new wireless electrophysiology data acquisition system, built around a standard homecage, is presented in this paper, which can power up and communicate with sensors and actuators/stimulators attached to or implanted in small freely behaving animal subjects, such as rodents. Key abilities of the energized homecage (EnerCage) system is enabling longitudinal experiments with minimal operator involvement or interruption, while providing test subjects with an enriched environment closer to their natural habitat, without the burden of being tethered or carrying bulky batteries. The magnetic resonant multi-coil design used in the new EnerCage-HC2 automatically localizes the transmitted electromagnetic power from a single transmitter (Tx) coil at the bottom of the cage toward the receiver coil (Rx), carried on/in the animal body, obviating the need for tracking the animal or switching the coils. In order to increase the resonators' quality factor (Q > 166) at the desired operating frequency of 13.56 MHz, while maintaining a high self-resonance frequency [Formula: see text], they are made of wide copper foils and optimally segmented based on a set of design rules that can be adopted for experimental arenas with different shapes and dimensions. The Rx rectified voltage is regulated at a user-defined window [Formula: see text] by a Tx-Rx closed-loop power control (CLPC) mechanism that creates a volume inside the homecage with 42 mW of power delivered to the load (PDL), and a homogeneous power transfer efficiency (PTE) plane of 14% on average at ∼7 cm height, plus stability against angular mis-alignments of up to 80°.

RFID Technology for Continuous Monitoring of Physiological Signals in Small Animals.

Telemetry systems enable researchers to continuously monitor physiological signals in unrestrained, freely moving small rodents. Drawbacks of common systems are limited operation time, the need to house the animals separately, and the necessity of a stable communication link. Furthermore, the costs of the typically proprietary telemetry systems reduce the acceptance. The aim of this paper is to introduce a low-cost telemetry system based on common radio frequency identification technology optimized for battery-independent operational time, good reusability, and flexibility. The presented implant is equipped with sensors to measure electrocardiogram, arterial blood pressure, and body temperature. The biological signals are transmitted as digital data streams. The device is able of monitoring several freely moving animals housed in groups with a single reader station. The modular concept of the system significantly reduces the costs to monitor multiple physiological functions and refining procedures in preclinical research.

Considerations for the selection of a generator as a back-up power source for an animal facility.

Loss of power, whether or not it is related to a disaster, is a potential problem for animal facilities. The lack of light and the inability to operate mechanical systems related to ventilation, security, access, water, sewer and environmental control; to use laboratory instruments and equipment such as cage-washers and automatic watering systems; and to access computers and electronic files, potentially including animal health records and environmental monitoring data, present substantial challenges to facility operation. Therefore, an animal research facility must develop a contingency plan to address loss of power and other potential threats. Use of a back-up power source such as a generator is a common component of such a plan. Here the author discusses factors that should be considered in the selection of a generator as a back-up power source for an animal facility.

Energia metabolizável nas raçöes e desempenho de frangos de corte criados com separaçäo de sexo / Effects of metabolizable energy levels in the rations on sexed broilers performance

Realizou-se um trabalho experimental com 3.600 pintos comerciais de um dia para corte, sexados, para avaliar o desempenho até 42 dias de idade, utilizando-se raçöes isoprotéicas e três níveis de energia metabolizável denominados alto, normal e baixo, em dois tipos de raçäo para frango de corte, inicial e engorda. Foram avaliadas as seguintes variáveis: consumo de raçäo, ganho de peso, conversäo alimentar e mortalidade. Observou-se que os diferentes níveis de energia metabolizável näo afetaram o consumo de raçäo, conversäo alimentar, mortalidade; afetaram somente o peso médio, onde a raçäo contendo alta energia foi superior às demais (P<0,01). Em relaçäo ao sexo, somente a conversäo alimentar näo foi afetada, as demais variáveis mostraram um efeito altamente significativo (P< 0,01) dos machos em relaçäo às fêmeas