Morphology and morphometry of the human obturator nerve in males and females.

Peripheral nerve injury and the nerves' subsequent repair and regeneration continues to be marked clinically by poor functional recovery. The analysis of nerve morphology is an aspect which may provide an impact on successful clinical outcomes through better prediction of donor and recipient matching. In this study, we evaluated the morphological aspects of the human obturator nerve for a better understanding of its potential in nerve transplantation. Morphological characteristics of donor obturator nerves were analysed, including nerve diameter and length, fascicle count and the ratio of neural to non-neural tissue present within the cross-sectional area of the nerve's epineurium, with respect to laterality and sex. Statistical significance (p < 0.10) was determined for male obturator nerves having an average diameter of 2.67 mm compared to female obturator nerves at 1.91 mm, as well as left obturator nerves having an average of 11.21 fascicles compared to the right having an average of 10.17 fascicles. Strong positive correlations were determined between cross-sectional nerve area and limb size index, as well as between percentage of non-neural tissue and area of non-neural tissue, among males. Separately, strong correlation between percentage of non-neural tissue and area of non-neural tissue among right obturator nerves in males and females was determined . These findings indicate that there are associations and predictions that can be made about nerve morphology and that these when combined with other patient characteristics may enhance patient functional recovery following a peripheral nerve's repair.

Pineal Gland from the Cell Culture to Animal Models: A Review.

This review demonstrates current literature on pineal gland physiology, pathology, and animal model experiments to concisely explore future needs in research development with respect to pineal gland function and neuro-regenerative properties. The pineal gland plays an integral role in sleep and recovery by promoting physiologic circadian rhythms via production and release of melatonin. Yet, the current literature shows that the pineal gland has neuroprotective effects that modulate both peripheral and central nerve injuries through several direct and indirect mechanisms, such as angiogenesis and induction of growth factors and anti-inflammatory mediators. Animal models have also shown correlations between pineal gland function and metabolic homeostasis. Studies have shown that a functional pineal gland is essential in preventing and slowing the progression of certain diseases such as diabetes, osteoporosis, vertebral osteoarthritis, and neurodegenerative processes. Lastly, the array of cell culturing methods and animal models that can be used to further develop the study of pineal gland function and nervous system injury were reviewed.

Typical and atypical properties of peripheral nerve allografts enable novel strategies to repair segmental-loss injuries.

We review data showing that peripheral nerve injuries (PNIs) that involve the loss of a nerve segment are the most common type of traumatic injury to nervous systems. Segmental-loss PNIs have a poor prognosis compared to other injuries, especially when one or more mixed motor/sensory nerves are involved and are typically the major source of disability associated with extremities that have sustained other injuries. Relatively little progress has been made, since the treatment of segmental loss PNIs with cable autografts that are currently the gold standard for repair has slow and incomplete (often non-existent) functional recovery. Viable peripheral nerve allografts (PNAs) to repair segmental-loss PNIs have not been experimentally or clinically useful due to their immunological rejection, Wallerian degeneration (WD) of anucleate donor graft and distal host axons, and slow regeneration of host axons, leading to delayed re-innervation and producing atrophy or degeneration of distal target tissues. However, two significant advances have recently been made using viable PNAs to repair segmental-loss PNIs: (1) hydrogel release of Treg cells that reduce the immunological response and (2) PEG-fusion of donor PNAs that reduce the immune response, reduce and/or suppress much WD, immediately restore axonal conduction across the donor graft and re-innervate many target tissues, and restore much voluntary behavioral functions within weeks, sometimes to levels approaching that of uninjured nerves. We review the rather sparse cellular/biochemical data for rejection of conventional PNAs and their acceptance following Treg hydrogel and PEG-fusion of PNAs, as well as cellular and systemic data for their acceptance and remarkable behavioral recovery in the absence of tissue matching or immune suppression. We also review typical and atypical characteristics of PNAs compared with other types of tissue or organ allografts, problems and potential solutions for PNA use and storage, clinical implications and commercial availability of PNAs, and future possibilities for PNAs to repair segmental-loss PNIs.

Functional and immunological peculiarities of peripheral nerve allografts.

This review addresses the accumulating evidence that live (not decellularized) allogeneic peripheral nerves are functionally and immunologically peculiar in comparison with many other transplanted allogeneic tissues. This is relevant because live peripheral nerve allografts are very effective at promoting recovery after segmental peripheral nerve injury via axonal regeneration and axon fusion. Understanding the immunological peculiarities of peripheral nerve allografts may also be of interest to the field of transplantation in general. Three topics are addressed: The first discusses peripheral nerve injury and the potential utility of peripheral nerve allografts for bridging segmental peripheral nerve defects via axon fusion and axon regeneration. The second reviews evidence that peripheral nerve allografts elicit a more gradual and less severe host immune response allowing for prolonged survival and function of allogeneic peripheral nerve cells and structures. Lastly, potential mechanisms that may account for the immunological differences of peripheral nerve allografts are discussed.

Protocol to Study the Role of Extracellular Vesicles During Induced Stem Cell Differentiation.

Extracellular vesicles (EVs) are vesicles released by cells, which due to their cargo and cell membrane proteins induce changes in the recipient cells. These vesicles can be a novel option to induce stem cell differentiation. Here we described a method to induce mesenchymal stem cell differentiation (MSC) into neuron-like cells using small EVs from neurons. First, we will describe a method based on neurons to induce adipocyte derived stem cells differentiation, a type of MSC, by coculturing both using inserts. Secondly, we will describe a follow-up method by using only isolated neuron-derived small EVs to directly induce ADSC differentiation in neuron-like cells. Importantly, in both methods it is possible to avoid the direct cell-to-cell contact, thus allowing for the study of soluble factors role during stem cell differentiation.

The Use of Bone Marrow-Derived Stem Cells in the Treatment of a Comminuted Tibiotarsal Fracture in a Juvenile Red-legged Seriema (Cariama cristata).

An adult red-legged seriema (Cariama cristata) presented with a comminuted fracture of the tibiotarsus and fibula. Surgery was performed, and a type II external fixator, with 2 distal and 2 proximal pins, was used to stabilize the fracture. After a 10-day stabilization period, the bird developed a second fracture on the same bone, proximal to the first fracture site. Another surgery was performed on the seriema similar to the first one. However, in this second surgical procedure a single pin, instead of 2 perpendicular pins, was placed proximally to the fracture site. After the second surgical procedure, bone marrow stem cells (BMSCs) from the seriema's left ulna were collected. Twenty-seven days after the second surgery, the BMSCs were transplanted, into the fracture sites. Twenty-four days after the stem cells were injected into the fractures (51 days after the second surgical procedure), radiographic images revealed healing bone calluses at the fracture sites. The fracture healing was relatively long for this case (a total of 75 days). The addition of bone marrow stem cell therapy to the use of external fixation may have contributed to the healing observed radiographically 24 days after administration; therefore, bone marrow stem cell therapy, in addition to traditional surgical fracture reduction and stabilization, may be a promising therapeutic approach for avian cases with similar injuries and bone anatomy. However, as this is a single case, this therapeutic modality deserves further application and study. Moreover, we suggest modifications in the bone marrow stem cell collection and therapy, which may be useful for future studies and application involving birds.

Long-term neural regeneration following injury to the peroneal branch of the sciatic nerve in sheep.

Peripheral nerves (PNs) are frequently injured as a result of trauma or disease. Development of therapies to regenerate PNs requires the use of animal models, typically beginning in rodents and progressing to larger species. There are several large animal models of PN regeneration that each has their benefits and drawbacks. Sheep have been used in PN studies due to their similarities in body weight to humans and the ease and lesser expense in their care and housing relative to other species. We have investigated the use of sheep for studies of PN regeneration and have developed and tested an injury model in the peroneal branch of the sciatic nerve. Three experimental groups were tested on mature sheep: a bisection; a 5-cm reverse autograft; and sham surgery. Protocols were developed for the post-operative care for animals with this injury, and regeneration was tracked for extended time points via compound muscle action potentials (CMAPs) and endpoint assessments of nerve morphometry, muscle mass and muscle fibrosis. Results indicate the practical viability of this PN injury model and show distinctions in the degree and rate of regeneration between bisection and reverse autograft that persisted 14 months. This long-term study shows bisections lead to significantly improved CMAPS and muscle mass and lesser muscle fibrosis as compared to reverse autograft. The persistence of these discernable changes between two relatively similar experimental groups out to extended time points is an indication of the sensitivity of this nerve section and its potential applicability for comparative studies.

Dynamics of male canine germ cell development.

Primordial germ cells (PGCs) are precursors of gametes that can generate new individuals throughout life in both males and females. Additionally, PGCs have been shown to differentiate into embryonic germ cells (EGCs) after in vitro culture. Most studies investigating germinative cells have been performed in rodents and humans but not dogs (Canis lupus familiaris). Here, we elucidated the dynamics of the expression of pluripotent (POU5F1 and NANOG), germline (DDX4, DAZL and DPPA3), and epigenetic (5mC, 5hmC, H3K27me3 and H3K9me2) markers that are important for the development of male canine germ cells during the early (22-30 days post-fertilization (dpf)), middle (35-40 dpf) and late (45-50 dpf) gestational periods. We performed sex genotype characterization, immunofluorescence, immunohistochemistry, and quantitative reverse transcriptase polymerase chain reaction (RT-qPCR) analyses. Furthermore, in a preliminary study, we evaluated the capacity of canine embryo PGCs (30 dpf) to differentiate into EGCs. To confirm the canine EGCs phenotype, we performed alkaline phosphatase detection, immunohistochemistry, electron and transmission scanning microscopy and RT-qPCR analyses. The PGCs were positive for POU5F1 and H3K27me3 during all assessed developmental periods, including all periods between the gonadal tissue stage and foetal testes development. The number of NANOG, DDX4, DAZL, DPPA3 and 5mC-positive cells increased along with the developing cords from 35-50 dpf. Moreover, our results demonstrate the feasibility of inducing canine PGCs into putative EGCs that present pluripotent markers, such as POU5F1 and the NANOG gene, and exhibit reduced expression of germinative genes and increased expression of H3K27me3. This study provides new insight into male germ cell development mechanisms in dogs.

Bone marrow stem cell applied in the canine veterinary clinics / Células tronco de medula óssea utilizadas na clínica veterinária canina

Cell therapy represents an old therapeutic practice initiated with the transfusion of whole blood in different clinical situations. There is now a breakthrough in the study of multipotent stem cell therapy because of its functionality in regeneration of tissues, which promotes attention of the scientific community. Bone marrow is one of the main sources of multipotent stem cells, composed by hematopoietic stem cells responsible for the renewal of the cellular components of the blood, and mesenchymal stem cells that aid in the regeneration of tissues. These cells have a strong potential for the treatment of several diseases, due their main characteristics such as high plasticity, capacity for self-renewal and immunomodulation. Although, there are many studies that show good results with the use of cell therapy as a form of treatment for several diseases, some studies still show inconclusive or unsatisfactory results. Therefore, the objective of this study was to review the application of bone marrow stem cells in the canine model since improvements on the knowledge of the technique are necessary to enable its applicability with safety and efficacy.(AU)

A terapia celular representa uma antiga prática terapêutica iniciada com a transfusão de sangue total em diferentes situações clínicas. Atualmente há um avanço no estudo da terapia com células-tronco mesenquimais por conta de sua funcionalidade na regeneração de tecidos, o que promove uma crescente atenção do meio científico. A medula óssea é uma das principais fontes de células-tronco multipotentes, no qual se encontram as células-tronco hematopoiéticas, responsável pela renovação dos componentes celulares do sangue, e as células-tronco mesenquimais que auxiliam na regeneração de tecidos. Essas células têm um forte potencial para o tratamento de diversas enfermidades, uma vez que possuem como principais características alta plasticidade, capacidade de auto renovação e imunomodulação. Apesar de haver muitos trabalhos que apresentam bons resultados com a utilização da terapia celular como forma de tratamento para diversas enfermidades, alguns estudos ainda demonstram resultados inconclusivos ou não satisfatórios, por isso, objetivou-se com este trabalho revisar a aplicação das células-tronco derivadas da medula óssea no modelo canino uma vez que é necessário melhorias sobre o conhecimento da técnica para que possibilite a sua aplicabilidade com segurança e eficácia.(AU)

Bioimpressão e produção de mini-órgãos com células tronco / Bioprinting with stem cells and production of mini-organs

A bioimpressão é considerada uma fonte promissora no desenvolvimento celular, e na produção de mini-órgãos, válulas, cartilagens que futuramente poderão ser utilizados na terapia para transplantes em animais e humanos. Assim, essa técnica poderá ser utilizada como uma terapia eletiva, no tratamento de injúrias e principalmente no tratamento de doenças crônico-degenerativas. Em humanos essa terapia está sendo pesquisada a fim de auxiliar a medicina no tratamento e regeneração de tecidos impressos a partir de arcabouços de células desenvolvidas a partir de células-tronco, biomateriais e impressões em 3D. O uso dessa tecnologia é também um auxiliar nas pesquisas oncológicas com o intuito de projetar e avaliar a proliferação celular de tumores, bem como a ação de novos medicamentos quimioterápicos. No entanto, a maior limitação para o uso da terapia utilizando-se a impressora de células, órgãos e tecidos em 3D é a falta de protocolos unificados com metodologias reprodutíveis e detalhadas; com o objetivo de viabilizar a utilização da impressora e a impressão de células, órgãos e tecidos em 3D. Dessa forma, esta revisão busca reunir as publicações mais atuais na área, as quais destacam os avanços no uso de bioimpressão com células-tronco, a fim de descrever as principais técnicas e os potenciais de utilização como alternativa terapêutica na medicina humana e veterinária.(AU)

The bioprinting is considered a promising source in cell development, and production of mini-organs, valves, cartilage that may eventually be used in therapy for transplantation in animals and humans. It can also be used as an elective therapy in the treatment of injuries and treatment of chronic degenerative diseases. In humans, this therapy is been studied mainly in the treatment and regeneration of tissues printed from scaffold cells developed from stem cells, biomaterials and impressions in 3D. This technology is also an aid for the study of the formation of tumors, in order to design and evaluate the cellular proliferation of the tumors and the action of new chemotherapy drugs. However, the main drawback to this therapy is the lack of standardized protocols with reproducible and detailed methodologies with the aim of enabling the use of bioprinting and printing cells, tissues and organs in 3D. Thus, this review seeks to bring together the most current publications of the bioprinting area in order to describe the technique and its potential use as a therapeutic alternative.(AU)

Células-tronco derivadas do epitélio olfatório: perspectivas terapêuticas na medicina veterinária / Stem cells derived from olfactory epithelium: therapeutic perspectives in veterinary medicine

O epitélio olfatório (EO) é uma fonte promissora de células-tronco (CTEO) para o uso terapêutico na medicina veterinária e humana, especialmente em doenças correlacionadas com o sistema nervoso periférico (medula espinhal) e central (cérebro e tronco encefálico) , pois as CTEO possuem a capacidade de se diferenciar em células do sistema nervoso, tais como: neurônios, oligodendrócitos e astrócitos. Em humanos estas células são utilizadas em ensaios terapêuticos de doenças degenerativas como o Alzheimer e Parkinson. Em animais a casuística relativa das doenças neurodegenerativas crônicas ou agudas é baixa, devido à dificuldade de diagnóstico definitivo, desta forma o enfoque das pesquisas com terapia celular são em sua grande maioria em lesões mecânicas na medula espinhal. Devido à falta de padronização e seleção das melhores metodologias que permitam confrontação de estudos, esta revisão busca reunir as mais recentes publicações, descrevendo o potencial uso das células-tronco do epitélio olfatório em terapias celulares, discutindo os principais desafios e perspectivas futuras com enfoque na medicina veterinária.(AU)

The olfactory epithelium (OE) is a promising source of stem cells (OESC) for therapeutic use in veterinary and human medicine, especially in diseases correlated with the peripheral (spinal cord) and central (brain and brainstem) nervous system (CNS), because of its ability to differentiate into neurons, astrocytes and oligodendrocytes cells. In humans, OESC has been used primarily in therapeutic trials for degenerative diseases such as Alzheimer and Parkinson. In animals, the frequency of corresponding cases of chronic or acute neurodegenerative diseases is very low, because of the difficulty of a definitive diagnosis; thus, the focus of cell therapy research are mostly mechanical spinal cord injuries. Due to the lack of normalization and selection of the best methodologies for comparative studies, this review aims to analyze recent reports on the potential use of stem cells from the olfactory epithelium in cell therapies and to discuss the main challenges and future prospects in veterinary medicine.(AU)

Regulation of neural stem cells by choroid plexus cells population.

The choroid plexus is a tissue on the central nervous system responsible for producing cerebrospinal fluid, maintaining homeostasis and neural stem cells support; though, all of its functions still unclear. This study aimed to demonstrate the niches of choroid plexus cells for a better understanding of the cell types and functions, using the porcine as the animal model. The collected material was analyzed by histology, immunohistochemistry, and cell culture. The cell culture was characterizated by immunocytochemistry and flow cytometry. Our results showed OCT-4, TUBIII, Nestin, CD45, CD73, CD90 positive expression and GFAP, CD105 negative expression, also methylene blue histological staining confirmed the presence of telocytes cells. We realized that the choroid plexus is a unique and incomparable tissue with different niches of cells as pluripotent, hematopoietic, neuronal progenitors and telocyte cells, which provide its complexity, differentiated functionality and responsibility on brain balance and neural stem cells regulation.

Estudo microscópico e macroscópico, com enfoque radiográfico e de alizarina, no desenvolvimento embrionário e fetal de gatos domésticos (Felis catus) em diferentes idades gestacionais / Microscopic and macroscopic study focusing ray and alizarin on embryonic and fetal development in cats (Felis catus) in different gestational ages

The domestic cat was named Felis catus by Carolus Linnaeus in his book Systema Na turae, in 1798. The family Felidae has many morphological similarities with wild felines. The study of the embryology of the domestic cat is of great value considering its importance as an experimental model for the wild cats endangered from extinction, especially in the research related to reproductive biology. The objective of this study is the descriptive embryology of the domestic cat at different stages of pregnancy, through macroscopic description of photographic records, radiographic and alizarin technique, and microscopic description of photographic records by light microscopy. In embryos with an estimated gestational age of 17 days we observed macroscopically an expansion corresponding to the rostral forebrain, the placoid site of lens, cervical flexure, the four pharyngeal arches with grooves dividing the cardiac prominence, a sign of the limb bud, and the presence of somites. In the caudal region of the embryo, we saw the cranio-caudal bend, allowing the same position in format of a "C". In embryos with an estimated age of 22 days, we noticed macroscopically the forebrain, optic vesicle pigmentation of the retina, the optic vesicle, fourth ventricle, liver, fore and hind limbs with a slight distinction between the digits and superficial vascularization. In embryos with an estimated age of 25 days we noticed presence of the forebrain and midbrain, the pronounced cervical curvature of the optic vesicle with strong pigmentation of the retina, the optic vesicle, limbs and chest well developed, distinguishing the digits and pronounced the liver Fetuses with estimated age of 52 days have internal and external structures easily identified in adult animals. With respect to the bone structure we noted that they did not have any radial bone formed, only bone shafts. Microscopically, the embryo of the domestic cat with CR of 0.9cm and estimated age of 19 days revealed the presence of beak, oral cavity with upper and lower nasal cavity, eye and opening of the 4th ventricle of the brain, esophagus, heart with atrium and ventricle, lung, liver, mesonephric ridge, primitive gonad, stomach, forelimb bud, spine and spinal cord in development. This paper is of great importance for study of the internal and external morphology of domestic cats for better understanding of the embryonic development of the species.

O gato doméstico (Felis catus) foi nomeado por Carolus Linnaeus em seu livro Systema Naturae, em 1798. A família Felidea apresenta muita semelhança morfológica com os felinos selvagens. O estudo da embriologia do gato doméstico é de grande valia, uma vez que, é considerado um importante modelo animal quando comparado aos gatos selvagem em extinção, especialmente relacionado às pesquisas sobre biologia reprodutiva. Este trabalho objetivou análisar e comparar as fases embrionárias de quatro embriões e um feto de felinos domésticos. Nos embriões com idade gestacional estimada em 17 dias (0,5cm CR) podemos observar pela análise macroscópica a presença de dilatação rostral correspondente ao prosencéfalo, o local placóide do cristalino, a flexura cervical, os quatro arcos faríngeos com os sulcos que o dividem, a proeminência cardíaca, o indício do brotamento do membro pélvico, além da presença de somitos. Na região caudal do embrião, visualizamos a curvatura cranio-caudal, permitindo ao mesmo uma posição em formato de "C". Nos embriões com idade gestacional estimada em 22 dias (1,2cm CR), na análise macroscópica foi visualizado o prosencéfalo, vesícula óptica com pigmentação da retina, vesícula ótica, quarto ventrículo, fígado, membros torácicos e pélvicos com discreta distinção dos dígitos e vascularização superficial. Nos embriões com idade gestacional estimada em 25 dias (1,5cm CR) notamos a presença do prosencéfalo e mesencéfalo, a curvatura cervical pronunciada, vesícula óptica com forte pigmentação da retina, vesícula ótica, membros pélvicos e torácicos bem desenvolvidos, com distinção dos dígitos e fígado bem pronunciado. Os fetos com idade gestacional estimada em 52 dias (10cm CR) possuem estruturas internas e externas facilmente identificadas em animais adultos. Com relação às estruturas ósseas notamos que as mesmas não apresentam nenhuma epífise óssea formada, sendo visíveis somente as diáfises ósseas. Na análise microscópica, o embrião de idade gestacional de 19 dias (0,9cm CR) revelou a presença do rostro, cavidade oral com lábio superior e inferior, cavidade nasal, olho e a abertura do 4º ventrículo encefálico, esôfago, coração com átrio e ventrículo, pulmão, fígado, crista mesonéfrica, gônada primitiva, estômago, broto do membro torácico, coluna vertebral e a medula espinhal em formação. Esse trabalho é de grande importância para o estudo da morfologia externa e interna de gatos domésticos, principalmente no que diz respeito ao desenvolvimento ósseo e articular, considerando as alterações que podem ou não ser promovidas pelo uso de terapias medicamentosas ou celulares durante o desenvolvimento embrionário e fetal.

The use of animal models for stroke research: a review.

Stroke has been identified as the second leading cause of death worldwide. Stroke is a focal neurologic deficit caused by a change in cerebral circulation. The use of animal models in recent years has improved our understanding of the physiopathology of this disease. Rats and mice are the most commonly used stroke models, but the demand for larger models, such as rabbits and even nonhuman primates, is increasing so as to better understand the disease and its treatment. Although the basic mechanisms of stroke are nearly identical among mammals, we here discuss the differences between the human encephalon and various animals. In addition, we compare common surgical techniques used to induce animal models of stroke. A more complete anatomic knowledge of the cerebral vessels of various model species is needed to develop more reliable models for objective results that improve knowledge of the pathology of stroke in both human and veterinary medicine.