Pág. 4 – Opinión: SOS UGR
Pág. 18: El Pantanto de Cubillas estrena el Club Náutico universitario
Pág. 21: Formador contra los malos tratos (pistas para hoy)
Premios a las mejores notas
Pág. 22: Vivir en Granada
– ‘Behind’y el arte joven
Pág. 47: La verdad del flamenco y su hondura espiritual
Pág. 48: Detrás del nuevo arte
Pág. 49: Kodama: «Borges era terrible, sentía todo lo que yo sentía»
Descarga por URL: http://sl.ugr.es/02eT
Pág. 4 – Opinión: SOS UGR
Pág. 18: El Pantanto de Cubillas estrena el Club Náutico universitario
Pág. 21: Formador contra los malos tratos (pistas para hoy)
Premios a las mejores notas
Pág. 22: Vivir en Granada
– ‘Behind’y el arte joven
Pág. 47: La verdad del flamenco y su hondura espiritual
Pág. 48: Detrás del nuevo arte
Pág. 49: Kodama: «Borges era terrible, sentía todo lo que yo sentía»
Descarga por URL: http://sl.ugr.es/02eT
A study conducted at the University of Granada has demonstrated that ibuprofen -a non-steroidal anti-inflammatory drug (NSAID)- has beneficial effects on bone repair after a fracture or following bone surgery.
In vitro tests demonstrated that -unlike other NSAIDs- when a therapeutic dose of ibuprofen is administered, it has no negative effects on the proliferation and synthesis of obsteoblast osteocalcin, a cell which is directly involved in the formation and regeneration of bones.
Osteoblast cells are bone cells that synthesize the bone matrix. Consequently, osteoblasts play a major role in bone development, growth, maintenance and repair.
Positive Results
In an article recently published in the prestigious Journal of bone and mineral metabolism, the University of Granada researchers report the positive effects of ibuprofen on bone repair. The researchers are members of the research group BIO277, which studies the effects of different pharmacological and non-pharmacological therapies on obsteoblast cells.
The primary author of this article, Concepción Ruiz Rodríguez, a professor at the University of Granada Nursing Department states that «up to date, we had little information on the effects of ibuprofen on osteoblast cells». The University of Granada study demonstrates that a therapeutic dose of ibuprofen (5-25 µm.) does not inhibit the proliferation and synthesis of osteocalcin in the MG-63 cell line. However, when higher doses are administered (>25 µm.) they may activate other cells, which might explain the expression of membrane markers and the decrease in the phagocytic capacity.
Source: http://canal.ugr.es/health-science-and-technology/item/58505
A study conducted at the University of Granada has demonstrated that ibuprofen -a non-steroidal anti-inflammatory drug (NSAID)- has beneficial effects on bone repair after a fracture or following bone surgery.
In vitro tests demonstrated that -unlike other NSAIDs- when a therapeutic dose of ibuprofen is administered, it has no negative effects on the proliferation and synthesis of obsteoblast osteocalcin, a cell which is directly involved in the formation and regeneration of bones.
Osteoblast cells are bone cells that synthesize the bone matrix. Consequently, osteoblasts play a major role in bone development, growth, maintenance and repair.
Positive Results
In an article recently published in the prestigious Journal of bone and mineral metabolism, the University of Granada researchers report the positive effects of ibuprofen on bone repair. The researchers are members of the research group BIO277, which studies the effects of different pharmacological and non-pharmacological therapies on obsteoblast cells.
The primary author of this article, Concepción Ruiz Rodríguez, a professor at the University of Granada Nursing Department states that «up to date, we had little information on the effects of ibuprofen on osteoblast cells». The University of Granada study demonstrates that a therapeutic dose of ibuprofen (5-25 µm.) does not inhibit the proliferation and synthesis of osteocalcin in the MG-63 cell line. However, when higher doses are administered (>25 µm.) they may activate other cells, which might explain the expression of membrane markers and the decrease in the phagocytic capacity.
Source: http://canal.ugr.es/health-science-and-technology/item/58505
A study conducted at the University of Granada has demonstrated that ibuprofen –a non-steroidal anti-inflammatory drug (NSAID)– has beneficial effects on bone repair after a fracture or following bone surgery.
In vitro tests demonstrated that –unlike other NSAIDs– when a therapeutic dose of ibuprofen is administered, it has no negative effects on the proliferation and synthesis of obsteoblast osteocalcin, a cell which is directly involved in the formation and regeneration of bones.
Osteoblast cells are bone cells that synthesize the bone matrix. Consequently, osteoblasts play a major role in bone development, growth, maintenance and repair.
Positive Results
In an article recently published in the prestigious Journal of bone and mineral metabolism, the University of Granada researchers report the positive effects of ibuprofen on bone repair. The researchers are members of the research group BIO277, which studies the effects of different pharmacological and non-pharmacological therapies on obsteoblast cells.
The primary author of this article, Concepción Ruiz Rodríguez, a professor at the University of Granada Nursing Department states that «up to date, we had little information on the effects of ibuprofen on osteoblast cells». The University of Granada study demonstrates that a therapeutic dose of ibuprofen (5-25 µm.) does not inhibit the proliferation and synthesis of osteocalcin in the MG-63 cell line. However, when higher doses are administered (>25 µm.) they may activate other cells, which might explain the expression of membrane markers and the decrease in the phagocytic capacity.
http://canal.ugr.es/health-science-and-technology/item/58505
Full bibliographic informationDíaz-Rodríguez L, García-Martínez O, De Luna-Bertos E, Ramos-Torrecillas J, Ruiz C, Effect of ibuprofen on proliferation, differentiation, antigenic expression, and phagocytic capacity of osteoblasts, J Bone Miner Metab. 2012 Apr 28. [Epub ahead of print], http://www.ncbi.nlm.nih.gov/pubmed/22543821
A study conducted at the University of Granada has demonstrated that ibuprofen –a non-steroidal anti-inflammatory drug (NSAID)– has beneficial effects on bone repair after a fracture or following bone surgery.
In vitro tests demonstrated that –unlike other NSAIDs– when a therapeutic dose of ibuprofen is administered, it has no negative effects on the proliferation and synthesis of obsteoblast osteocalcin, a cell which is directly involved in the formation and regeneration of bones.
Osteoblast cells are bone cells that synthesize the bone matrix. Consequently, osteoblasts play a major role in bone development, growth, maintenance and repair.
Positive Results
In an article recently published in the prestigious Journal of bone and mineral metabolism, the University of Granada researchers report the positive effects of ibuprofen on bone repair. The researchers are members of the research group BIO277, which studies the effects of different pharmacological and non-pharmacological therapies on obsteoblast cells.
The primary author of this article, Concepción Ruiz Rodríguez, a professor at the University of Granada Nursing Department states that «up to date, we had little information on the effects of ibuprofen on osteoblast cells». The University of Granada study demonstrates that a therapeutic dose of ibuprofen (5-25 µm.) does not inhibit the proliferation and synthesis of osteocalcin in the MG-63 cell line. However, when higher doses are administered (>25 µm.) they may activate other cells, which might explain the expression of membrane markers and the decrease in the phagocytic capacity.
http://canal.ugr.es/health-science-and-technology/item/58505
Full bibliographic informationDíaz-Rodríguez L, García-Martínez O, De Luna-Bertos E, Ramos-Torrecillas J, Ruiz C, Effect of ibuprofen on proliferation, differentiation, antigenic expression, and phagocytic capacity of osteoblasts, J Bone Miner Metab. 2012 Apr 28. [Epub ahead of print], http://www.ncbi.nlm.nih.gov/pubmed/22543821
“Lo infantil en el diván. La cura del pequeño neurótico”, es el título del libro de Patrick Monribot, que, con el número seis de la colección de conferencias sobre psicoanálisis, ha sido coeditada por la Editorial Universidad de Granada (eug) y el Instituto del Campo Freudiano de Granada, traducido del francés por Francisco Hernández Díaz, con revisión, epígrafe y notas de Mónica Francés.
Se trata de un texto de Patrick Monribot sobre el universo de la infancia al que Freud accedió a través de la cura de adultos, “y al que la cura de niños nos permite conocer de primera mano”, dice Ynma Nieto Ferre en la presentación de este librito de 66 páginas.
Este pequeño volumen que acaba de publicar la eug recoge la conferencia impartida por Patrick Monribot en el Salón de Grados de la Facultad de Ciencias Políticas y Sociología de la UGR, el 14 de diciembre de 2010, con ocasión del ciclo “Paradojas de la salud mental. Lacan y la Psiquiatría”, organizado por el Instituto del Campo Freudiano de Granada, y presentado por José Luis Chacón.
Patrick Monribot demuestra en estas páginas cómo un niño puede salir adelante de manera perenne “sin ser desacondicionado por alguna ortopedia del espíritu”.
Asegura Monribot en su discurso: “Aislar el objeto pulsional, ofrecerle otro destino, según la palabra de Freud con respecto a la pulsión, es una manera de reorganizar la defensa del sujeto frente a la castración y ante lo real. A ese precio, el niño puede soltar su obsesión. A ese precio, la nueva relación del sujeto a la pulsión le permitirá, tal vez, otro tipo de arreglo sintomático para poder sostenerlo en la existencia, un arreglo menos perjudicial que el precedente”.
Patrick Monribot es psicoanalista. Nació en Burdeos (Francia), es analista de la Escuela de la Causa Freudiana de París y de la New Lacanian School y miembro de la Asociación Mundial de Psicoanálisis (AMP).
Adquiera este libro en el sitio web de la EUG: http://sl.ugr.es/02eQ
Gabinete de Comunicación – Secretaría General
UNIVERSIDAD DE GRANADA
Acera de San Ildefonso, s/n. 18071. Granada (España)
Tel. 958 243063 – 958 244278
Correo e. gabcomunicacion@ugr.es
Web: http://canal.ugr.es
“Lo infantil en el diván. La cura del pequeño neurótico”, es el título del libro de Patrick Monribot, que, con el número seis de la colección de conferencias sobre psicoanálisis, ha sido coeditada por la Editorial Universidad de Granada (eug) y el Instituto del Campo Freudiano de Granada, traducido del francés por Francisco Hernández Díaz, con revisión, epígrafe y notas de Mónica Francés.
Se trata de un texto de Patrick Monribot sobre el universo de la infancia al que Freud accedió a través de la cura de adultos, “y al que la cura de niños nos permite conocer de primera mano”, dice Ynma Nieto Ferre en la presentación de este librito de 66 páginas.
Este pequeño volumen que acaba de publicar la eug recoge la conferencia impartida por Patrick Monribot en el Salón de Grados de la Facultad de Ciencias Políticas y Sociología de la UGR, el 14 de diciembre de 2010, con ocasión del ciclo “Paradojas de la salud mental. Lacan y la Psiquiatría”, organizado por el Instituto del Campo Freudiano de Granada, y presentado por José Luis Chacón.
Patrick Monribot demuestra en estas páginas cómo un niño puede salir adelante de manera perenne “sin ser desacondicionado por alguna ortopedia del espíritu”.
Asegura Monribot en su discurso: “Aislar el objeto pulsional, ofrecerle otro destino, según la palabra de Freud con respecto a la pulsión, es una manera de reorganizar la defensa del sujeto frente a la castración y ante lo real. A ese precio, el niño puede soltar su obsesión. A ese precio, la nueva relación del sujeto a la pulsión le permitirá, tal vez, otro tipo de arreglo sintomático para poder sostenerlo en la existencia, un arreglo menos perjudicial que el precedente”.
Patrick Monribot es psicoanalista. Nació en Burdeos (Francia), es analista de la Escuela de la Causa Freudiana de París y de la New Lacanian School y miembro de la Asociación Mundial de Psicoanálisis (AMP).
Adquiera este libro en el sitio web de la EUG: http://sl.ugr.es/02eQ
Gabinete de Comunicación – Secretaría General
UNIVERSIDAD DE GRANADA
Acera de San Ildefonso, s/n. 18071. Granada (España)
Tel. 958 243063 – 958 244278
Correo e. gabcomunicacion@ugr.es
Web: http://canal.ugr.es
University of Granada researchers have developed an artificial cerebellum (a biologically-inspired adaptive microcircuit) that controls a robotic arm with human-like precision.
The cerebellum is the part of the human brain that controls the locomotor system and coordinates body movements.
To date, although robot designers have achieved very precise movements, such movements are performed at very high speed, require strong forces and are power consuming. This approach cannot be applied to robots that interact with humans, as a malfunction might be potentially dangerous.
To solve this challenge, University of Granada researchers have implemented a new cerebellar spiking model that adapts to corrections and stores their sensorial effects; in addition, it records motor commands to predict the action or movement to be performed by the robotic arm. This cerebellar model allows the user to articulate a state-of-the-art robotic arm with extraordinary mobility.
Automatic Learning
The developers of the new cerebellar model have obtained a robot that performs automatic learning by extracting the input layer functionalities of the brain cortex. Furthermore, they have developed two control systems that enable accurate and robust control of the robotic arm during object handling.
The synergy between the cerebellum and the automatic control system enables robot’s adaptability to changing conditions i.e. the robot can interact with humans. The biologically-inspired architectures used in this model combine the error training approach with predictive adaptive control.
The designers of this model are Silvia Tolu, Jesús Garrido and Eduardo Ros Vidal, at the University of Granada Department of Computer Architecture and Technology, and the University of Almería researcher Richard Carrillo.
University of Granada researchers have developed an artificial cerebellum (a biologically-inspired adaptive microcircuit) that controls a robotic arm with human-like precision.
The cerebellum is the part of the human brain that controls the locomotor system and coordinates body movements.
To date, although robot designers have achieved very precise movements, such movements are performed at very high speed, require strong forces and are power consuming. This approach cannot be applied to robots that interact with humans, as a malfunction might be potentially dangerous.
To solve this challenge, University of Granada researchers have implemented a new cerebellar spiking model that adapts to corrections and stores their sensorial effects; in addition, it records motor commands to predict the action or movement to be performed by the robotic arm. This cerebellar model allows the user to articulate a state-of-the-art robotic arm with extraordinary mobility.
Automatic Learning
The developers of the new cerebellar model have obtained a robot that performs automatic learning by extracting the input layer functionalities of the brain cortex. Furthermore, they have developed two control systems that enable accurate and robust control of the robotic arm during object handling.
The synergy between the cerebellum and the automatic control system enables robot’s adaptability to changing conditions i.e. the robot can interact with humans. The biologically-inspired architectures used in this model combine the error training approach with predictive adaptive control.
The designers of this model are Silvia Tolu, Jesús Garrido and Eduardo Ros Vidal, at the University of Granada Department of Computer Architecture and Technology, and the University of Almería researcher Richard Carrillo.
ScienceDaily (July 3, 2012) — University of Granada researchers have developed an artificial cerebellum (a biologically-inspired adaptive microcircuit) that controls a robotic arm with human-like precision. The cerebellum is the part of the human brain that controls the locomotor system and coordinates body movements
To date, although robot designers have achieved very precise movements, such movements are performed at very high speed, require strong forces and are power consuming. This approach cannot be applied to robots that interact with humans, as a malfunction might be potentially dangerous.
To solve this challenge, University of Granada researchers have implemented a new cerebellar spiking model that adapts to corrections and stores their sensorial effects; in addition, it records motor commands to predict the action or movement to be performed by the robotic arm. This cerebellar model allows the user to articulate a state-of-the-art robotic arm with extraordinary mobility.
Automatic Learning
The developers of the new cerebellar model have obtained a robot that performs automatic learning by extracting the input layer functionalities of the brain cortex. Furthermore, they have developed two control systems that enable accurate and robust control of the robotic arm during object handling.
The synergy between the cerebellum and the automatic control system enables robot’s adaptability to changing conditions i.e. the robot can interact with humans. The biologically-inspired architectures used in this model combine the error training approach with predictive adaptive control.
The designers of this model are Silvia Tolu, Jesús Garrido and Eduardo Ros Vidal, at the University of Granada Department of Computer Architecture and Technology, and the University of Almería researcher Richard Carrillo.
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ScienceDaily (July 3, 2012) — University of Granada researchers have developed an artificial cerebellum (a biologically-inspired adaptive microcircuit) that controls a robotic arm with human-like precision. The cerebellum is the part of the human brain that controls the locomotor system and coordinates body movements
To date, although robot designers have achieved very precise movements, such movements are performed at very high speed, require strong forces and are power consuming. This approach cannot be applied to robots that interact with humans, as a malfunction might be potentially dangerous.
To solve this challenge, University of Granada researchers have implemented a new cerebellar spiking model that adapts to corrections and stores their sensorial effects; in addition, it records motor commands to predict the action or movement to be performed by the robotic arm. This cerebellar model allows the user to articulate a state-of-the-art robotic arm with extraordinary mobility.
Automatic Learning
The developers of the new cerebellar model have obtained a robot that performs automatic learning by extracting the input layer functionalities of the brain cortex. Furthermore, they have developed two control systems that enable accurate and robust control of the robotic arm during object handling.
The synergy between the cerebellum and the automatic control system enables robot’s adaptability to changing conditions i.e. the robot can interact with humans. The biologically-inspired architectures used in this model combine the error training approach with predictive adaptive control.
The designers of this model are Silvia Tolu, Jesús Garrido and Eduardo Ros Vidal, at the University of Granada Department of Computer Architecture and Technology, and the University of Almería researcher Richard Carrillo.
Descargar