Questões de Vestibular EBMSP 2018 para Prosef - 2019.1 - Medicina - 1ª Fase
Foram encontradas 50 questões
Ano: 2018
Banca:
EBMSP
Órgão:
EBMSP
Prova:
EBMSP - 2018 - EBMSP - Prosef - 2019.1 - Medicina - 1ª Fase |
Q1334852
Inglês
Texto associado
Questão
A new study published in Current Biology is
investigating why you get poor sleep in unfamiliar
places. It suggests that when people sleep in an
unfamiliar place, one hemisphere of the brain stays
more awake as a way to keep watch for potential
danger possibly a remnant of the days when Homo
sapiens had to guard their territory every night.
This phenomenon is known as unihemispheric slow-wave sleep, and it’s seen in marine animals and some birds. This is the first study to suggest that the human brain may also be hard-wired to function in a similar way, although on a smaller scale. Humans, unlike sparrows, don’t usually sleep with one eye open. However, when in new surroundings, one hemisphere of the brain may stay at least a little bit awake – great for waking quickly if an intruder shows up, but with a resulting groggy feeling the next morning.
The group of researchers recruited sleep study participants, and conducted neuroimaging along with polysomnography, a standard test used in sleep labs to monitor brain waves, oxygen level in blood, heart rate, breathing, and eye and leg movements. They discovered that only the brain’s right hemisphere was consistently engaged in slow-wave, or deep, sleep. The left hemisphere – the side responsible for logical thinking and reasoning – had what the researchers called “enhanced vigilance”, which also made the entire brain more responsive to sound.
The researchers tried a test where they targeted sounds to the left and right ear. They found that on the first night, 80 percent of the arousals from deep sleep occurred when sound was made to target the right ear (the brain’s left hemisphere). On day two, that number dropped to about 50 percent.
This phenomenon is known as unihemispheric slow-wave sleep, and it’s seen in marine animals and some birds. This is the first study to suggest that the human brain may also be hard-wired to function in a similar way, although on a smaller scale. Humans, unlike sparrows, don’t usually sleep with one eye open. However, when in new surroundings, one hemisphere of the brain may stay at least a little bit awake – great for waking quickly if an intruder shows up, but with a resulting groggy feeling the next morning.
The group of researchers recruited sleep study participants, and conducted neuroimaging along with polysomnography, a standard test used in sleep labs to monitor brain waves, oxygen level in blood, heart rate, breathing, and eye and leg movements. They discovered that only the brain’s right hemisphere was consistently engaged in slow-wave, or deep, sleep. The left hemisphere – the side responsible for logical thinking and reasoning – had what the researchers called “enhanced vigilance”, which also made the entire brain more responsive to sound.
The researchers tried a test where they targeted sounds to the left and right ear. They found that on the first night, 80 percent of the arousals from deep sleep occurred when sound was made to target the right ear (the brain’s left hemisphere). On day two, that number dropped to about 50 percent.
FIRGER, Jessica. Disponível em: <http://www.newsweek.com/authors/ jessica-figer>. Acesso em: set. 2018. Adaptado.
In order to monitor the participants’ brains, the researchers
Ano: 2018
Banca:
EBMSP
Órgão:
EBMSP
Prova:
EBMSP - 2018 - EBMSP - Prosef - 2019.1 - Medicina - 1ª Fase |
Q1334853
Inglês
Texto associado
Questão
A new study published in Current Biology is
investigating why you get poor sleep in unfamiliar
places. It suggests that when people sleep in an
unfamiliar place, one hemisphere of the brain stays
more awake as a way to keep watch for potential
danger possibly a remnant of the days when Homo
sapiens had to guard their territory every night.
This phenomenon is known as unihemispheric slow-wave sleep, and it’s seen in marine animals and some birds. This is the first study to suggest that the human brain may also be hard-wired to function in a similar way, although on a smaller scale. Humans, unlike sparrows, don’t usually sleep with one eye open. However, when in new surroundings, one hemisphere of the brain may stay at least a little bit awake – great for waking quickly if an intruder shows up, but with a resulting groggy feeling the next morning.
The group of researchers recruited sleep study participants, and conducted neuroimaging along with polysomnography, a standard test used in sleep labs to monitor brain waves, oxygen level in blood, heart rate, breathing, and eye and leg movements. They discovered that only the brain’s right hemisphere was consistently engaged in slow-wave, or deep, sleep. The left hemisphere – the side responsible for logical thinking and reasoning – had what the researchers called “enhanced vigilance”, which also made the entire brain more responsive to sound.
The researchers tried a test where they targeted sounds to the left and right ear. They found that on the first night, 80 percent of the arousals from deep sleep occurred when sound was made to target the right ear (the brain’s left hemisphere). On day two, that number dropped to about 50 percent.
This phenomenon is known as unihemispheric slow-wave sleep, and it’s seen in marine animals and some birds. This is the first study to suggest that the human brain may also be hard-wired to function in a similar way, although on a smaller scale. Humans, unlike sparrows, don’t usually sleep with one eye open. However, when in new surroundings, one hemisphere of the brain may stay at least a little bit awake – great for waking quickly if an intruder shows up, but with a resulting groggy feeling the next morning.
The group of researchers recruited sleep study participants, and conducted neuroimaging along with polysomnography, a standard test used in sleep labs to monitor brain waves, oxygen level in blood, heart rate, breathing, and eye and leg movements. They discovered that only the brain’s right hemisphere was consistently engaged in slow-wave, or deep, sleep. The left hemisphere – the side responsible for logical thinking and reasoning – had what the researchers called “enhanced vigilance”, which also made the entire brain more responsive to sound.
The researchers tried a test where they targeted sounds to the left and right ear. They found that on the first night, 80 percent of the arousals from deep sleep occurred when sound was made to target the right ear (the brain’s left hemisphere). On day two, that number dropped to about 50 percent.
FIRGER, Jessica. Disponível em: <http://www.newsweek.com/authors/ jessica-figer>. Acesso em: set. 2018. Adaptado.
The scientists found out that
Ano: 2018
Banca:
EBMSP
Órgão:
EBMSP
Prova:
EBMSP - 2018 - EBMSP - Prosef - 2019.1 - Medicina - 1ª Fase |
Q1334854
Inglês
Texto associado
Questão
A new study published in Current Biology is
investigating why you get poor sleep in unfamiliar
places. It suggests that when people sleep in an
unfamiliar place, one hemisphere of the brain stays
more awake as a way to keep watch for potential
danger possibly a remnant of the days when Homo
sapiens had to guard their territory every night.
This phenomenon is known as unihemispheric slow-wave sleep, and it’s seen in marine animals and some birds. This is the first study to suggest that the human brain may also be hard-wired to function in a similar way, although on a smaller scale. Humans, unlike sparrows, don’t usually sleep with one eye open. However, when in new surroundings, one hemisphere of the brain may stay at least a little bit awake – great for waking quickly if an intruder shows up, but with a resulting groggy feeling the next morning.
The group of researchers recruited sleep study participants, and conducted neuroimaging along with polysomnography, a standard test used in sleep labs to monitor brain waves, oxygen level in blood, heart rate, breathing, and eye and leg movements. They discovered that only the brain’s right hemisphere was consistently engaged in slow-wave, or deep, sleep. The left hemisphere – the side responsible for logical thinking and reasoning – had what the researchers called “enhanced vigilance”, which also made the entire brain more responsive to sound.
The researchers tried a test where they targeted sounds to the left and right ear. They found that on the first night, 80 percent of the arousals from deep sleep occurred when sound was made to target the right ear (the brain’s left hemisphere). On day two, that number dropped to about 50 percent.
This phenomenon is known as unihemispheric slow-wave sleep, and it’s seen in marine animals and some birds. This is the first study to suggest that the human brain may also be hard-wired to function in a similar way, although on a smaller scale. Humans, unlike sparrows, don’t usually sleep with one eye open. However, when in new surroundings, one hemisphere of the brain may stay at least a little bit awake – great for waking quickly if an intruder shows up, but with a resulting groggy feeling the next morning.
The group of researchers recruited sleep study participants, and conducted neuroimaging along with polysomnography, a standard test used in sleep labs to monitor brain waves, oxygen level in blood, heart rate, breathing, and eye and leg movements. They discovered that only the brain’s right hemisphere was consistently engaged in slow-wave, or deep, sleep. The left hemisphere – the side responsible for logical thinking and reasoning – had what the researchers called “enhanced vigilance”, which also made the entire brain more responsive to sound.
The researchers tried a test where they targeted sounds to the left and right ear. They found that on the first night, 80 percent of the arousals from deep sleep occurred when sound was made to target the right ear (the brain’s left hemisphere). On day two, that number dropped to about 50 percent.
FIRGER, Jessica. Disponível em: <http://www.newsweek.com/authors/ jessica-figer>. Acesso em: set. 2018. Adaptado.
The word or expression from the text has not been correctly
defined in
Ano: 2018
Banca:
EBMSP
Órgão:
EBMSP
Prova:
EBMSP - 2018 - EBMSP - Prosef - 2019.1 - Medicina - 1ª Fase |
Q1334855
Biologia
No trabalho iniciado, silenciosamente, nos
anos de 1960 e que só deu frutos dez anos depois,
Carl Woese selecionou uma única estrutura para
comparar espécies. Obviamente, a estrutura tinha
de estar presente em todas as espécies. E mais,
tinha de servir ao mesmo propósito. Esse propósito
tinha de ser fundamental e tão importante para a
célula que até leves mudanças na sua função seriam
penalizadas pela seleção natural. Isto é necessário
se quisermos comparar as diferenças que se
acumulam entre espécies ao longo de, literalmente,
bilhões de anos, para construírem uma grande
árvore da vida, desde o início. Essa foi a escala da
ambição de Woese ao propor uma classificação com
base em Domínios.
LANE, Nick. Questão Vital: porque a vida é como é? e.1. Rio de Janeiro: Rocco, 2017, p.17.
O texto menciona uma estrutura selecionada pelo pesquisador Carl Woese, durante a montagem de sua classificação dos seres vivos por Domínios. Esta estrutura apresenta uma função ou propósito essencial para a manutenção da vida. Desta forma, pode-se afirmar que a função biológica citada está associada diretamente à
LANE, Nick. Questão Vital: porque a vida é como é? e.1. Rio de Janeiro: Rocco, 2017, p.17.
O texto menciona uma estrutura selecionada pelo pesquisador Carl Woese, durante a montagem de sua classificação dos seres vivos por Domínios. Esta estrutura apresenta uma função ou propósito essencial para a manutenção da vida. Desta forma, pode-se afirmar que a função biológica citada está associada diretamente à
Ano: 2018
Banca:
EBMSP
Órgão:
EBMSP
Prova:
EBMSP - 2018 - EBMSP - Prosef - 2019.1 - Medicina - 1ª Fase |
Q1334856
Biologia
A radiação ultravioleta foi a primeira fonte
de mutação do DNA a ser estudada e, devido ao
seu poder germicida, vem sendo amplamente
empregada para causar danos letais em
micro-organismos em condições laboratoriais. Ela
é usada para matar bactérias e fungos, tornando o
espaço de manipulação do material genético mais
puro e esterilizado.
Considerando-se as vantagens mencionadas na utilização da radiação ultravioleta em ambientes de pesquisa, pode-se afirmar: