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Abstract
Introduction
Protocol
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Behavior

Verhaltensstörungen: Ein innovativer Ansatz die Modulatorischer Auswirkungen einer Nutraceutical-Diät zu überwachen

Published: January 03, 2017
doi:
10.3791/54878
, , , , ,
1School of Specialization in Clinical Biochemistry,“G. d’Annunzio” University, 2Department of Veterinary Medicine, Pathology and Veterinary Clinic Section,University of Sassari, 3Research and Development Department,Forza10 USA Corp.

Summary

We report a simple approach to evaluate the effectiveness of a specific diet in positively modulating the daily activity and clinical and behavioral symptoms of dogs with evident behavioral disturbances.

Abstract

In dogs, diets are often used to modulate behavioral disturbances related to chronic anxiety and stress caused by intense and restless activity. However, the traditional ways to monitor behavioral changes in dogs are complicated and not efficient. In the current clinical evaluation, a new, simple monitoring system was used to assess the effectiveness of a specific diet in positively modulating the intense and restless activity of 24 dogs of different ages and breeds. This protocol describes how to easily and rapidly evaluate improvement in a set of symptoms related to generalized anxiety by using a specific sensor, a mobile phone app, a wireless router, and a computer. The results showed that dogs treated with specific diets showed significant improvement in the times spent active and at rest after 10 days (p < 0.01 and p < 0.05, respectively). These dogs also showed an overall significant improvement in clinical and behavioral symptoms. A specific sensor, along with its related hardware, was demonstrated to successfully monitor behavioral changes relating to movement in dogs.

Introduction

Hunde sind wie die meisten gewidmet domestizierte Tiere allgemein anerkannt, die mit den Menschen leben. Sie werden oft als Familienmitglieder , deren Verhaltensänderungen gelten als ernsthafte Bedenken betrachtet, vor allem , wenn diese Veränderungen ihre körperliche Unversehrtheit und das allgemeine Wohlbefinden bedrohen 1. Daher nähert sich die Entwicklung von Adjuvans zu gemeinsamen Therapien für Hunde-Verhaltensstörungen lindern würde Familien helfen , die Lebensqualität ihrer Hunde zu verbessern, unerwünschte Phänomene wie Hund Verzicht und Euthanasie zu vermeiden 2. Die meisten dieser Verhaltensstörungen sind im Zusammenhang mit Angst , die durch Stress verursacht werden , und die Angst , ohne angemessene Intervention 1,3 pathologisch werden kann.

Es wurde vermutet, dass Angststörungen bei Hunden verursacht werden, nicht nur durch signifikante Veränderungen im Leben, sondern auch durch chronische oder posttraumatische Belastungen, die ihre Homöostase verändern und kann somit zu Anpassung d führenisorders 1,3. Diese Studie basiert auf einer klinischen Bewertung von Verhaltensstörungen hauptsächlich generalisierter Angstzugeschrieben. Die typischen klinischen Symptome dieser Erkrankung sind konstante oder steigende Reaktivität, Körper und Umweltforschung, Aktivierung, Wachsamkeit und übermäßiges Bellen; es wirkt sich auch oft die sozialen Interaktionen zwischen Hund und Besitzer 1,4,5. Die prädisponierenden Faktoren könnten intrinsische, wie Genetik, oder extrinsische, wie Umweltreize 1,6. In der Tat können die oben genannten klinischen Symptome häufiger auch ohne Triggerung Umgebungsreiz. In diesem Sinne wird die Studie über den Ursprung dieser Faktoren wesentlich für die richtige Diagnose und die anschließende Therapie.

Die am häufigsten verwendeten Therapien für generalisierte Angst stützen sich auf Gegenkonditionierung und Desensibilisierung Techniken, wo der Hund lernt, wie man einmal mit einem Reiz, der Angst verursacht konfrontiert zu verhalten, oder auf einer pharmakologischen approACH basierend auf anxiolytische Arzneimittelverabreichung 7. 10 Tage Basierend auf diesen Überlegungen, 24 von Verhaltensstörungen betroffen Hunde vor allem auf generalisierte Angstzugeschrieben erhielt eine Gegenkonditionierung und Desensibilisierung Verhaltenstherapie mit einem Nahrungsergänzungsmittel Ernährung kombiniert. Die Ernährung bestand aus einer Mischformel Fischproteine, Reis Kohlenhydrate, Punica granatum, Valeriana officinalis, Rosmarinus officinalis, Tilia spp, Tee – Extrakt und L-Tryptophan, mit einem omega 3: -6 – Verhältnis von 1: 0,8. Literatur meldet eindeutig belegt , dass P. granatum verwendet wird , chronische Angst und Schlaflosigkeit 1,8, zu behandeln , während Valeriana officinalis für leichte Schlafstörungen und nervöse Spannung 9,10 verwendet wird. Darüber hinaus Anti-Angst – und Anti-Depressiva Effekte wurden nach Rosmarinus officinalis 11-14 und Tilia spp 15,16 Verbrauch beobachtet. L-Theanin, eine der Tee Bestandteile, hat sich gezeigt, ar spielenole in Stress zu reduzieren und die Herzfrequenz bei chronischen Angst 17,18 abnimmt. Umgekehrt 19,20 viele Studien berichtet das Auftreten von Angstzuständen, Stimmung und depressive Symptome nach L-Tryptophan Abreicherung und / oder eine Omega-3 – Mangel.

Generalisierter Angstverhalten und klinische Symptome, einschließlich der Kennzeichnung, Angst, Schüchternheit, unregelmäßiger Biorhythmus, Reaktivität, Aktivierung, Reizbarkeit, Wachsamkeit, Umweltforschung, Körper Exploration, Aufmerksamkeit Anforderung, Schuppen, Juckreiz, Flush, Seborrhoe, Pelz Opazität, Erbrechen, Durchfall, Blähungen , Tränenfluss, und anal sac repletion, wurden ebenfalls bewertet. Die meisten dieser Symptome wurden von Zeichen begleitet, die Hunden induziert, um mehr Zeit wach und aktiv verbringen, anstatt in Ruhe ist oder schläft. Daher ist es durch jeden Hund verbrachte Aktivität und Ruhezeiten vor und nach der Auswertung beurteilt. Um kontinuierlich täglich Verbesserungen der Aktivität überwachen und Zeit ruhen, mit einem handelsüblichen Sensor, der auf Fest wurdedie Kragen der Hunde und verbunden mit einem Mobiltelefon oder zu einem Wi-Fi-Station verwendet wurde.

Protocol

Das Protokoll wurde von der Veterinärethikkommission vor dem Beginn der Studie geprüft und genehmigt. Die Empfehlungen der ANKOMMEN Leitlinien in der Tierforschung wurden ebenfalls konsultiert und 21-25 betrachtet. 1. Hundeauswahl und Nahrungsergänzung Wählen Sie 24 Hunde verschiedener Rassen (mittleres Alter und Gewicht ± SEM: 2,9 ± 0,3 Jahre und 32,01 ± 1,17 kg; 14 Männer, 10 Frauen) mit offensichtlichen klinischen Symptome von Verhaltensstörungen, wie Angst, Schüchternheit, unregelmäßiger Biorhythmus, Reaktivität, Aktivierung , Reizbarkeit, Wachsamkeit und konstante Umweltforschung. teilen Randomly die Tiere in zwei Gruppen und legen jeweils in eine 215.278 sq ft einzigen Box. Nach den Anweisungen des Herstellers, geben Sie die entsprechende Dosis von Standarddiät (SD, n = 12) oder Nutraceutical – Diät (ND, n = 12) für 10 Tage, je nach den Gewichten der Tiere (Tabelle 1). </li> Komplette zwei Veterinärkontrollen der Hunde vor (T0) und 10 Tage nach (T1) der Behandlung. 2. Verhalten Symptome Erwerb und Scoring Haben Sie einen zertifizierten Veterinär behaviorist die Verhaltensnote (Markierung, Angst, Schüchternheit, unregelmäßiger Biorhythmus, Reaktivität, Aktivierung, Reizbarkeit, Wachsamkeit, Umwelt Exploration und Aufmerksamkeit Bedarf) und klinischen (Schuppen, Juckreiz, Flush, Seborrhoe, Pelz Opazität, Erbrechen, Durchfall, Blähungen, Tränenfluß und anal sac repletion) Bedingungen für jeden Hund. Für jeden Hund, versammeln sich eine Partitur vor und nach der 10-Tage-Test wie folgt: 1 = Fehlen von Symptomen; 2 = moderate Vorhandensein von Symptomen; 3 = markiert Vorhandensein von Symptomen. Am Ende der Auswertung zusammenfassen, für jedes Symptom, die Partituren der Hunde jeder Gruppe vor und nach 10 Tagen. Zeichnen Sie die Daten auf einer statistischen Software. 3. Der Sensor <p class= "Jove_content"> Hinweis: Der Sensor hat einen 3-Achsen-Beschleunigungsmesser, so dass er Bewegung in jeder Richtung (x, y, z) zu sammeln. Es wiegt 8 g und ist extrem klein (41 x 28 x 11 mm). Darüber hinaus ist es kompatibel mit jedem mobilen Gerät, das eine globale drahtlose Kommunikation verfügt. Es verfügt über einen Akku, der für 14 Tage nach der Aufladung dauern kann. Die Datenausgabe wird in Punkten berechnet, die die Einheiten der Zeit damit verbracht aktiv und in Ruhe während des Tages von jedem Hund sind. Sicherzustellen, dass der Kragen nicht breiter als 30 mm für den optimalen Sitz des Sensors ist. Unter Verwendung des Verfahrens in den Abschnitten 3 und 4, die im Zusammenhang mit Verhaltensänderungen auswerten ausgegeben, die aktiv ist und in Ruhe vor und nach der Behandlung mit dem speziellen Diät. 4. Sensor Einstellung Öffnen Sie die Micro-USB-Kappe auf der Unterseite des Geräts und nehmen Sie das Kabel vorgesehen, um den Sensor auf den Computer des USB-1x / 2.0-Anschluss oder an eine Klasse 2 / begrenzte Stromversorgung mit einem U zu verbindenSB ausgegeben. Wenn eine LED zu blinken beginnt, laden Sie den Sensor für mindestens 90 min. Downloaden und installieren Sie das dedizierte kostenlose Handy-App aus dem Web-Shop. 5. Activity Monitoring und Analyse Schließen Sie die Stecker von einem Wireless-Router und der speziellen Wi-Fi-Basisstation in zwei verschiedene Steckdosen. Warten Sie, bis der Router bereit ist und das Wi-Fi-Basisstation beginnt zu blinken. Aktivieren Sie Bluetooth auf dem mobilen Gerät und stellen Sie sicher, dass es mit dem Internet verbunden ist. Öffnen Sie die App und anmelden. Tippen Sie dann auf "Hinzufügen neuer Hund" und die folgenden Schritte aus. Nehmen Sie ein Bild von dem Hund und bieten ihren Namen. Passender gesetzt, das Geschlecht, Alter, Gewicht, Zustand kastrieren, und die Position des Hundes. Legen Sie die primäre und die sekundäre Rasse des Hundes. Wählen Sie ggf. das Vorhandensein von Allergien (Haut, Ohr, etc.), Arthritis, Hirnalterung, Krebs, Diabetes, Herzerkrankungen, oder übermäßige wiright. Wählen Sie eine der drei zur Verfügung stehenden Lebensstile, mit ihren jeweiligen Punkte, je nach persönlichen Anforderungen (1. Durchschnitt, 2. Aktive oder 3. Olympian). HINWEIS: Je nach Alter des Hundes, werden die Punkte eines jeden Lebensstil zu ändern. Da das Ziel dieser Bewertung war die Hyperaktivität und den Stress der Hunde zu verringern, die erste Lebensstil, "Average", wurde als das letzte Ziel gesetzt, zu erreichen. Tippen Sie auf "Wi-Fi-Basisstation" und dann auf "Paar eine Basisstation", um den Sensor mit dem Wi-Fi-Basisstation verbinden. Warten Sie, bis das Wort "FitBark" erscheint unter "Paar eine Basisstation." Clip einen geladenen Sensor an dem Kragen des Hundes. Wiederholen Sie die Schritte 4,3-4,4 für jeden Hund. 6. Bark Aufnahme Fix ein digitales Diktiergerät an der Wand jedes Feld zu Beginn der Studie. Starten Sie die Rinde der Aufzeichnung der Aktivität. Jeden Tag, bevor eincquiring neue Daten, schließen Sie das digitale Voice Recorder an einen Computer mit Hilfe eines versenkbarem USB-Stecker zusammen mit dem Recorder zur Verfügung gestellt. Ziehen Sie den Ordner mit Sprachdaten vom Gerät an den Computer und benennen Sie sie mit dem aktuellen Datum. Wiederholen Sie die Schritte 6.2.1 – 6.2.2 jeden Tag für 10 Tage. Am Ende der Auswertungs Transformation (in s), die Rinde Zeit aufgezeichnet. Fassen Sie die Rinde Zeit für jede Gruppe vor und nach 10 Tagen. Zeichnen Sie die Daten auf einer statistischen Software.

Representative Results

Table 1 shows the daily amount of nutraceutical diet suggested by the manufacturer. In Figure 1, the daily mean activity and rest times spent by dogs belonging to the SD and ND groups during the evaluation period are shown. For instance, a significant decrease from a T0 value of 7,343 ± 611.7 to a T1 value of 5,093 ± 526.5 was observed in the ND group after 10 days, while no significant difference was observed in the SD group (Figure 1A, *p < 0.05). Conversely, the daily mean rest time significantly increased from a T0 value of 7.6 ± 0.3 h to a T1 value of 9.5 ± 0.3 h in the ND group after 10 days (**p < 0.01), while no significant difference was observed in the SD group (Figure 1B). Regarding behavioral symptoms, a reduction of the mean intensity of marking, from 2.50 to 2.41, was observed in dogs belonging to ND group, while no difference was observed in those belonging to the SD group (Figure 2A). On the contrary, anxiety, diffidence, and irregular biorhythm showed a significant reduction in dogs belonging to the ND group, from a T0 value of 2.50 ± 0.19 to a T1 value of 1.16 ± 0.11 (***p < 0.001, Figure 2B), from a T0 value of 2.08 ± 0.28 to a T1 value of 1.17 ± 0.12 (Figure 2C, *p < 0.05), and from a T0 value of 2.08 ± 0.28 to a T1 value of 1.08 ± 0.08 (Figure 2D, **p < 0.01), respectively. No significant difference was observed in the respective SD groups. Also, reactivity, activation, irritability, alertness, environmental exploration, and attention requirement mean intensities showed significant reductions after ND supplementation. In particular, reactivity decreased from a T0 value of 2.16 ± 0.27 to a T1 value of 1.25 ± 0.13 (Figure 2E, **p < 0.01), activation decreased from a T0 value of 2.25 ± 0.25 to a T1 value of 1.33 ± 0.14 (Figure 2F, *p < 0.05), irritability decreased from a T0 value of 2.66 ± 0.18 to a T1 value of 1.66 ± 0.22 (Figure 2G, **p < 0.01), alertness decreased from a T0 value of 2.50 ± 0.19 to a T1 value of 1.66 ± 0.22 (Figure 2H, *p < 0.05), environmental exploration decreased from a T0 value of 2.33 ± 0.18 to a T1 value of 1.66 ± 0.22 (Figure 2I, **p < 0.01), and attention requirement decreased from a T0 value of 2.24 ± 0.15 to a T1 value of 1.55 ± 0.21 (Figure 2J, *p < 0.05). No significant difference was observed in the respective SD group. In Figure 3, the mean intensities of clinical symptoms in dogs belonging to the SD and ND groups, before (T0) and after the 10-day evaluation period (T1), are shown. Dandruff significantly decreased from a T0 value of 2.33 ± 0.14 to a T1 value of 1.08 ± 0.08 (Figure 3A, ***p < 0.001). Also, itchiness, flush, seborrhea, and fur opacity significantly decreased from a T0 value of 2.08 ± 0.26 to a T1 value of 1.04 ± 0.05, from a T0 value of 2.11 ± 0.24 to a T1 value of 1.16 ± 0.11, from a T0 value of 2.35 ± 0.25 to a T1 value of 1.33 ± 0.14, and from a T0 value of 2.22 ± 0.13 to a T1 value of 1.41 ± 0.15, respectively (Figure 3B-E, *p < 0.05). A similar trend was observed for vomiting, diarrhea, flatulence, lachrymation, and anal sac repletion scores, which significantly decreased from a T0 value of 2.75 ± 0.10 to a T1 value of 1.58 ± 0.17 (Figure 3F, *p < 0.001), from a T0 value of 2.69 ± 0.12 to a T1 value of 2.06 ± 0.19 (Figure 3G, *p < 0.01), from a T0 value of 1.75 ± 0.13 to a T1 value of 1.25 ± 0.13 (Figure 3H, *p < 0.05), from a T0 value of 2.16 ± 0.11 to a T1 value of 1.32 ± 0.03 (Figure 3I, *p < 0.05), and from a T0 value of 2.28 ± 0.12 to a T1 value of 1.30 ± 0.14 (Figure 3J, *p < 0.01), respectively. No significant difference was observed in dogs belonging to the SD group. Figure 4 shows the mean time spent in barking by dogs belonging to the SD and ND groups before (T0) and after the evaluation period (T1). A significant decrease from a T0 value of 180.21 ± 15.35 to a T1 value of 76.02 ± 7.22 was observed in the ND group after 10 days. No significant difference was observed in the SD group. The data were analyzed using graphing and statistical software. All data are presented as ± the standard error of the mean and were first checked for normality using the D'Agostino-Pearson normality test. Differences in activity, rest and barking time as well as symptoms during the evaluation period were analyzed using a two-way ANOVA test followed by Tukey's multiple comparisons test. p < 0.05 was considered significant. It is worth noting that, at the beginning of the study, each dog was automatically assigned by the mobile app software to achieve a desired daily activity according to weight, age, and breed. After treatment, all dogs belonging to the ND group showed a significant decrease in the mean daily activity (p < 0.05) with respect to SD group, which was even lower than expected, and a consequent significant increase in daily mean rest time (p < 0.01). These results were also well correlated with consequent clinical symptoms and signs (Figures 2 – 3), demonstrating significant improvement as well as a significant reduction in barking time (Figure 4, p < 0.001). Taken together, all these considerations strengthened the efficacy of the ND in improving the results of common behavioral therapies for generalized anxiety. These results are also in agreement with our recent paper, which described the efficacy of a similar diet in relieving some of the clinical symptoms, such as dandruff, itchiness, flush, diarrhea, and flatulence, that have all been taken into account in this study26. It is also worth noting that clinical symptoms might also be the manifestation of an overall inflammation status, with a consequent oxidative stress imbalance. Inflammation is also known to contribute to the etiology of anxiety disorders, depression27, and neurotransmitter activity28. In this sense, we recently identified a specific compound, oxytetracycline, as a possible agent able to trigger an inflammatory condition both in vitro29,30and in vivo31,32. Oxytetracycline belongs to the class of tetracyclines, which are the most widely and legally used antibiotics in intensive farming (e.g., poultry30, livestock33, and aquaculture34) due to their low cost and high efficacy35. Unfortunately, oxytetracycline also has a high affinity for calcium-rich tissues, such as bone and teeth36, and can remain fixed in treated animals for extended periods, even respecting withdrawal time30. Moreover, pet food production relies on meat (mainly poultry) by-products, which are mechanically separated37. This kind of separation generates a bone-based meal bearing oxytetracycline residues that are present in commercially available diets (canned, semi-moist, and dry) at 20 – 30% and can accumulate within a pet's body. Concerning the ND group, it is reasonable to hypothesize that the mean score intensity reduction of all clinical symptoms was thus a consequence of the anti-inflammatory and antioxidant effect of the nutraceutical substances Punica granatum38, Valeriana officinalis39, Rosmarinus officinalis40, Tilia spp41, tea extract42, and polyunsaturated fatty acids (PUFA) present within the diet. For instance, PUFA have been show to modulate behavioral symptoms in attention-deficit hyperactivity disorder (ADHD) patients and in aggressive dogs43. These dogs had lower docosahexaenoic acid (DHA) levels than normal, as well as a higher omega-6:omega-3 ratio44,45. Figure 1. ND Reduces Activity Time and Increases Rest Time in Dogs. Schematic representation of the daily mean activity (A) and rest time (B) of dogs before (T0) and 10 days after (T1) SD and ND supplementation (**p < 0.01). The error bars are ± the standard error of mean. Please click here to view a larger version of this figure. Figure 2. ND Improves the Behavioral Disturbances in Affected Dogs. Schematic representations of the mean score intensities of behavioral symptoms in dogs before (T0) and 10 days after (T1) SD and ND supplementation. (A) Marking. (B) Anxiety (***p < 0.001). (C) Diffidence (*p < 0.05). (D) Irregular biorhythm (**p < 0.01). (E) Reactivity (**p < 0.01). (F) Activation (*p < 0.05). (G) Irritability (**p < 0.01). (H) Alertness (*p < 0.05). (I) Environmental exploration (**p < 0.01). (J) Attention requirement (**p < 0.01). The error bars are ± the standard error of mean. Please click here to view a larger version of this figure. Figure 3. ND Improves the Clinical Signs in Affected Dogs. Schematic representation of the mean score intensities of clinical symptoms in dogs before (T0) and 10 days after (T1) SD and ND supplementation (A) Dandruff (***p < 0.001). (B) Itch (*p < 0.05). (C) Flush (*p < 0.05). (D) Seborrhea (*p < 0.05). (E) Fur opacity (*p < 0.05). (F) Vomiting (***p < 0.001). (G) Diarrhea (**p < 0.01). (H) Flatulence (*p < 0.05). (I) Lachrymation (*p < 0.05). (J) Anal sac repletion (**p < 0.01). The error bars are ± the standard error of mean. Please click here to view a larger version of this figure. Figure 4. ND Reduces the Bark Time in Supplemented Dogs. Schematic representation of the mean time spent barking in dogs before (T0) and 10 days after (T1) SD and ND supplementation (***p < 0.001). The error bars are ± the standard error of mean. Please click here to view a larger version of this figure. Daily Ratio Weight (kg) Amount (g) 1 – 10 30 – 180 11 -20 190 – 300 21 – 35 310 – 455 36 – 50 465 – 595 Table 1. Daily Amount of Food Provided to the Dogs.

Discussion

Both SD and ND were two commercially available diets that completely fulfill the recommendations for protein, carbohydrate, and fat content according to the nutritional guidelines for complete and complementary pet food. However, in the ND, nutraceutical substances, such as Punica granatum (0.0457%), Valeriana officinalis (0.026%), Rosmarinus officinalis (0.000044%), Tilia spp (0.0635%), tea extract (0.031%), and L-tryptophan (0.0329%), were added. It is noteworthy that this clinical evaluation was inspired by a previous trivial evaluation where 2 dogs with evident behavioral symptoms mainly ascribed to generalized anxiety showed significant improvements after 3 days of ND supplementation. Here, we successfully used the same ND with 24 dogs presenting behavioral symptoms mainly ascribed to generalized anxiety.

The only critical step that occurred in the protocol was related to the Wi-Fi connection. In some boxes, the sensor signal did not reach the Wi-Fi station and therefore did not provide any data on the activity of the dogs. Thus, a Wi-Fi range extender was used to completely cover the distance between those boxes and the Wi-Fi station. Many studies have been performed to validate the usefulness of small, lightweight, motion-sensing accelerometers for pets44 and humans46-54. The sensor used in this clinical evaluation presents some limitations with respect to the gold-standard method of using a video camera55,56, such as a lack of specificity in distinguishing rest activity from sleep and general motion from an anxiety-related one. On the other hand, the sensor allows for the easy and fast detection of movement, as well as the ability to monitor daily improvements by means of a mobile phone app. Moreover, with respect to the other commercially available devices, this new sensor has a lower weight and price, can be worn by a dog of any weight, and has a long-lasting (~ 14 days) battery life. Moreover, because of the Wi-Fi station, it does not require the owner to be close to the dog while it is registering the improvements57-59. In fact, after registration with the website of the product company, the station can gather and store information that can be seen either on a computer or on a mobile device, even at a long distance (i.e., beyond the Bluetooth and Wi-Fi range). Possible further applications of this sensor will be the monitoring of excessive movement in dogs affected by separation anxiety47-54, abnormal repetitive behaviors60, or narcolepsy61once left alone at home.

Our results pave the way for a different short-term approach to manage dogs with behavioral symptoms mainly ascribed to generalized anxiety disorders, allowing the owner to re-establish a mutual attachment relationship with the dog. In conclusion, a better understanding of dog behavior, both by pet owners and by behavioral experts able to recognize behavioral and clinical symptoms related to generalized anxiety, might be coupled with a specific diet in order to ensure a better quality of life for the animals.

Disclosures

The authors have nothing to disclose.

Acknowledgements

This review was not supported by grants. We thank Sanypet Forza 10 USA Corp. Orlando, FL, USA for kindly providing the ND used in this study.

Materials

FitBark Activity monitor FitBark Inc. Sensor
 FitBark Wi-Fi Base Station FitBark Inc. 7002 Wi-Fi Base Station
FORZA10 Behavioral Diet 6lbs Forza10 USA Corp E0030922007 Nutraceutical diet
M5, 3G Mobile Wi-Fi  TP-LINK M5250 Router
SmartBox Laika 215,278 sq ft Dog box
Recorder Olympus WS-831 Voice recorder
DOWNLOAD MATERIALS LIST

References

  1. Ibáñez Talegón, M., Anzola Delgado, B., Kalinin, P. r. o. f. .. . V. l. a. d. i. m. i. r. . , (2011).
  2. Houpt, K. A., Honig, S. U., Reisner, I. R. Breaking the human-companion animal bond. J Am Vet Med Assoc. 208, 1653-1659 (1996).
  3. Overall, K. L. . Clinical behavioral medicine for small animals. , 544 (1997).
  4. Brousset Hernández-Jáuregui, D. M., Galindo Maldonado, F., Valdez Pérez, R., Romano Pardo, M., Schuneman de Aluja, A. Cortisol en saliva, orina y heces: evaluación no invasiva en mamíferos silvestres. Vet Méx. 36, 325-337 (2005).
  5. Flannigan, G., Dodman, N. H. Risk factors and behaviors associated with separation anxiety in dogs. J Am Vet Med Assoc. 219, 460-466 (2001).
  6. Pageat, P. . Patología del comportamiento del perro. , (2000).
  7. Serpell, J. . The Domestic Dog: Its Evolution, Behaviour and Interactions with People. , (1995).
  8. Overall, K. L. Pharmacologic treatments for behavior problems. Vet Clin North Am Small Anim Pract. 27, 637-665 (1997).
  9. Riaz, A., Khan, R. A. Effect of Punica Granatum on behavior in rats. Afr J Pharm Pharmacol. 8, 1118-1126 (2014).
  10. Das, S., Sarma, P. A study on the anticonvulsant and anti anxiety activity of ethanolic extract of Punica granatum Linn. Int. J. Pharm. Scie. 6, 389-392 (2014).
  11. Sudati, J. H., et al. In vitro Antioxidant Activity of Valeriana officinalis Against Different Neurotoxic Agents. Neurochem Res. 34, 1372-1379 (2009).
  12. Hattesohl, M., Feistel, B., Sievers, H., Lehnfeld, R., Hegger, M., Winterhoff, H. Extracts of Valeriana officinalis L. s.l. show anxiolytic and antidepressant effects but neither sedative nor myorelaxant properties. Phytomedicine. 15, 2-15 (2008).
  13. Wang, J., et al. Chemical Analysis and Biological Activity of the Essential Oils of Two Valerianaceous Species from China: Nardostachys chinensis and Valeriana officinalis. Molecules. 15, 6411-6422 (2010).
  14. Carlini, E. A. Plants and the central nervous system. Pharmacol Biochem Behav. 75, 501-512 (2003).
  15. Ulbricht, C., et al. An Evidence-Based Systematic Review of Rosemary (Rosmarinus officinalis) by the Natural Standard Research Collaboration. J Diet Suppl. 7, (2010).
  16. Machado, D. G., et al. Antidepressant-like effect of the extract of Rosmarinus officinalis in mice: Involvement of the monoaminergic system. Prog Neuropsychopharmacol Biol Psychiatry. 33, 642-650 (2009).
  17. Viola, H., et al. Isolation of pharmacologically active benzodiazepine receptor ligands from Tilia tomentosa (Tiliaceae). J Ethnopharmacol. 44, 47-53 (1994).
  18. Coleta, M., Campos, M. G., Cotrim, M. D., Proencada Cunha, A. Comparative evaluation of Melissa officinalis L., Tilia europaea L., Passiflora edulis Sims. and Hypericum perforatum L. in the elevated plus maze anxiety test. Pharmacopsychiatry. 34, S20-S21 (2001).
  19. Juneja, L. R., Chu, D. -. C., Okubo, T., Nagato, Y., Yokogoshi, Y. L-theanine-a unique amino acid of green tea and its relaxation effect in humans. Trends Food Sci Technol. 10, 199-204 (1999).
  20. Miodownik, C., et al. Serum Levels of Brain-Derived Neurotrophic Factor and Cortisol to Sulfate of Dehydroepiandrosterone Molar Ratio Associated With Clinical Response to L-Theanine as Augmentation of Antipsychotic Therapy in Schizophrenia and Schizoaffective Disorder Patients. Clin Neuropharmacol. 34, 155-160 (2011).
  21. Delgado, P. L., et al. Tryptophan-depletion challenge in depressed patients treated with desipramine or fluoxetine: implications for the role of serotonin in the mechanism of antidepressant action. Biol Psychiatry. 46, 212-220 (1999).
  22. Delgado, P. L., Charney, D. S., Price, L. H., Aghajanian, G. K., Landis, H., Heninger, G. R. Serotonin function and the mechanism of antidepressant action. Reversal of antidepressant-induced remission by rapid depletion of plasma tryptophan. Arch Gen Psychiatry. 47, 411-418 (1990).
  23. Valvassori, S. S., et al. Sodium butyrate has an antimanic effect and protects the brain against oxidative stress in an animal model of mania induced by ouabain. Psychiatry Res. 235, 154-159 (2015).
  24. Stoll, A. L., et al. Omega 3 Fatty Acids in Bipolar Disorder: A Preliminary Double-blind Placebo-Controlled Trial FREE. Arch Gen Psychiatry. 56, 407-412 (1999).
  25. Owen, C., Rees, A. M., Parker, G. The role of fatty acids in the development and treatment of mood disorders. Curr Opin Psychiatry. 21, 19-24 (2008).
  26. Kilkenny, C., Browne, W. J., Cuthi, I., Emerson, M., Altman, D. G. Improving bioscience research reporting: the ARRIVE guidelines for reporting animal research. Vet Clin Pathol. 41, 27-31 (2012).
  27. Di Cerbo, A., Palmieri, B., Chiavolelli, F., Guidetti, G., Canello, S. Functional foods in pets and humans. Intern J Appl Res Vet Med. 12, 192-199 (2014).
  28. Hovatta, I., Juhila, J., Donner, J. Oxidative stress in anxiety and comorbid disorders. Neurosci Res. 68, 261-275 (2010).
  29. Di Cerbo, A., et al. Toxicological Implications and Inflammatory Response in Human Lymphocytes Challenged with Oxytetracycline. J Biochem Mol Toxicol. 30, 170-177 (2016).
  30. Odore, R., et al. Cytotoxic effects of oxytetracycline residues in the bones of broiler chickens following therapeutic oral administration of a water formulation. Poult Sci. 94, 1979-1985 (2015).
  31. Di Cerbo, A., et al. Clinical evaluation of an antiinflammatory and antioxidant diet effect in 30 dogs affected by chronic otitis externa: preliminary results. Vet Res Commun. 40, 29-38 (2016).
  32. Di Cerbo, A., Canello, S., Guidetti, G., Laurino, C., Palmieri, B. Unusual antibiotic presence in gym trained subjects with food intolerance; a case report. Nutr Hosp. 30, 395-398 (2014).
  33. Kimera, Z. I., et al. Determination of oxytetracycline residues in cattle meat marketed in the Kilosa district, Tanzania. Onderstepoort J Vet Res. 82, 911 (2015).
  34. Chuah, L. O., Effarizah, M. E., Goni, A. M., Rusul, G. Antibiotic Application and Emergence of Multiple Antibiotic Resistance (MAR) in Global Catfish Aquaculture. Curr Environ Health Rep. 3, 118-127 (2016).
  35. Chopra, I., Roberts, M. Tetracycline antibiotics: mode of action, applications, molecular biology, and epidemiology of bacterial resistance. Microbiol Mol Biol Rev. 65, 232-260 (2001).
  36. Milch, R. A., Rall, D. P., Tobie, J. E. Bone localization of the tetracyclines. J Natl Cancer Inst. 19, 87-93 (1957).
  37. Rivera, J. A., Sebranek, J. G., Rust, R. E. Functional properties of meat by-products and mechanically separated chicken (MSC) in a high-moisture model petfood system. Meat Sci. 55, 61-66 (2000).
  38. Felger, J. C., Lotrich, F. E. Inflammatory cytokines in depression: neurobiological mechanisms and therapeutic implications. Neuroscience. 246, 199-229 (2013).
  39. Lee, C. -. J., Chen, L. -. G., Liang, W. -. L., Wang, C. -. C. Anti-inflammatory effects of Punica granatum Linne invitro and in vivo. Food Chem. 118, 315-332 (2010).
  40. Wojdyło, A., Oszmiański, J., Czemerys, R. Antioxidant activity and phenolic compounds in 32 selected herbs. Food Chem. 105, 940-949 (2007).
  41. Erkan, N., Ayranci, G., Ayranci, E. Antioxidant activities of rosemary (Rosmarinus Officinalis L.) extract, blackseed (Nigella sativa L.) essential oil, carnosic acid, rosmarinic acid and sesamol. Food Chem. 110, 76-82 (2008).
  42. Speisky, H., Rocco, C., Carrasco, C., Lissi, E. A., Lopez-Alarcon, C. Antioxidant screening of medicinal herbal teas. Phytother Res. 20, 462-467 (2006).
  43. Katiyar, S. K., Elmets, C. A. Green tea polyphenolic antioxidants and skin photoprotection (Review). Int J Oncol. 18, 1307-1313 (2001).
  44. Re, S., Zanoletti, M., Emanuele, E. Aggressive dogs are characterized by low omega-3 polyunsaturated fatty acid status. Vet Res Commun. 32, 225-230 (2008).
  45. Colter, A. L., Cutler, C., Meckling, K. A. Fatty acid status and behavioural symptoms of attention deficit hyperactivity disorder in adolescents: a case-control study. Nutr J. 7, 8 (2008).
  46. Lascelles, B. D., Hansen, B. D., Thomson, A., Pierce, C. C., Boland, E., Smith, E. S. Evaluation of a digitally integrated accelerometer-based activity monitor for the measurement of activity in cats. Vet Anaesth Analg. 35, 173-183 (2008).
  47. Brown, D. C., Boston, R. C., Farrar, J. T. Use of an activity monitor to detect response to treatment in dogs with osteoarthritis. J Am Vet Med Assoc. 237, 66-70 (2010).
  48. Yam, P. S., et al. Validity, practical utility and reliability of Actigraph accelerometry for the measurement of habitual physical activity in dogs. J Small Anim Pract. 52, 86-91 (2011).
  49. Michel, K. E., Brown, D. C. Determination and application of cut points for accelerometer-based activity counts of activities with differing intensity in pet dogs. Am J Vet Res. 72, 866-870 (2011).
  50. Hansen, B. D., Lascelles, B. D., Keene, B. W., Adams, A. K., Thomson, A. E. Evaluation of an accelerometer for at-home monitoring of spontaneous activity in dogs. Am J Vet Res. 68, 468-475 (2007).
  51. Moreau, M., Siebert, S., Buerkert, A., Schlecht, E. Use of a tri-axial accelerometer for automated recording and classification of goats’ grazing behaviour. Appl Anim Behav Sci. 119, 158-170 (2009).
  52. Yamada, M., Tokuriki, M. Spontaneous activities measured continuously by an accelerometer in beagle dogs housed in a cage. J Vet Med Sci. 62, 443-447 (2000).
  53. Preston, T., Baltzer, W., Trost, S. Accelerometer validity and placement for detection of changes in physical activity in dogs under controlled conditions on a treadmill. Res Vet Sci. 93, 412-416 (2012).
  54. Yashari, J. M., Duncan, C. G., Duerr, F. M. Evaluation of a novel canine activity monitor for at-home physical activity analysis. BMC Vet Res. 11, 146 (2015).
  55. Troiano, R. P., Berrigan, D., Dodd, K. W., Mâsse, L. C., Tilert, T., McDowell, M. Physical activity in the United States measured by accelerometer. Med Sci Sports Exerc. 40, 181-188 (2008).
  56. Stratford, P. W., Kennedy, D. M. Performance measures were necessary to obtain a complete picture of osteoarthritic patients. J Clin Epidemiol. 59, 160-167 (2006).
  57. Parthasarathy, V., Crowell-Davis, S. L. Relationship between attachment to owners and separation anxiety in pet dogs (Canis lupus familiaris). J Vet Behav Clin Appl Res. 1, 109-120 (2006).
  58. Palestrini, C., Minero, M., Cannas, S., Rossi, E., Frank, D. Video analysis of dogs with separation-related behaviors. Appl Anim Behav Sci. 124, 61-67 (2010).
  59. Mills, D. S., Ramos, D., Estelles, M. G., Hargrave, C. A triple blind placebo-controlled investigation into the assessment of the effect of Dog Appeasing Pheromone (DAP) on anxiety related behaviour of problem dogs in the veterinary clinic. Appl Anim Behav Sci. 98, 114-126 (2006).
  60. Irimajiri, M., Crowell-Davis, S. L. Animal behavior case of the month. Separation anxiety. J Am Vet Med Assoc. 245, 1007-1009 (2014).
  61. Tynes, V. V., Sinn, L. Abnormal repetitive behaviors in dogs and cats: a guide for practitioners. Vet Clin North Am Small Anim Pract. 44, 543-564 (2014).

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Behavioral DisturbancesNutraceutical DietAnimal BehaviorAnxietyActivity MonitoringAccelerometerGPSWireless Data TransmissionSensorWi-Fi RouterSmart Phone ApplicationDog TrackingBreed Information

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Di Cerbo, A., Sechi, S., Canello, S., Guidetti, G., Fiore, F., Cocco, R. Behavioral Disturbances: An Innovative Approach to Monitor the Modulatory Effects of a Nutraceutical Diet. J. Vis. Exp. (119), e54878, doi:10.3791/54878 (2017).
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