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跟著城市嚮導「老臺北胃」,用味道認識臺北很多朋友來臺北, 我怎麼選出這 10 大臺北小吃?在臺北, 一吃就知道:這就是臺灣味燒烤、火鍋很好吃, 不只是好吃,而是有「臺北日常感」臺北的小吃迷人,
吃完之後,你會記得臺北最後一個標準很簡單。 接下來的 10 樣臺北小吃, 第 1 家:饌堂-黑金滷肉飯(雙連店)|一碗就懂臺灣人的日常
如果只能用一道料理, 為什麼第一站,我會選饌堂? 不只是好吃,而是「現在的臺北感」 老臺北胃的帶路小提醒
這不是那種吃完會驚呼「哇!」的料理, 地址:103臺北市大同區雙連街55號1樓 電話:0225501379 第 2 家:富宏牛肉麵|臺北深夜也醒著的一碗熱湯
如果說滷肉飯代表的是臺灣人的日常, 為什麼老臺北胃會帶你來吃富宏? 不分時間,任何時候都適合的一碗麵 老臺北胃的帶路小提醒
這不是精緻料理, 地址:108臺北市萬華區洛陽街67號 電話:0223713028 菜單:https://www.facebook.com/pages/富宏牛肉麵-原建宏牛肉麵/ 第 3 家:士林夜市・吉彖皮蛋涼麵|臺北夏天最有記憶點的一口清爽
如果你在夏天來到臺北, 為什麼在夜市,我會帶你吃涼麵? 皮蛋,是靈魂,也是臺灣味的關鍵 老臺北胃的帶路小提醒
這不是華麗的小吃, 原來臺北的小吃,連氣候都一起考慮進去了。 地址:111臺北市士林區基河路114號 電話:0981014155 菜單:https://www.facebook.com/profile.php?id=100064238763064 第 4 家:胖老闆誠意肉粥|臺北人深夜最踏實的一碗粥
如果你問我, 為什麼這一碗粥,會被叫做「誠意」? 這不是觀光小吃,而是臺北人的生活片段
這些畫面, 老臺北胃的帶路小提醒
這不是為了拍照而存在的小吃, 地址:10491臺北市中山區長春路89-3號 電話:0913806139 第 5 家:圓環邊蚵仔煎|夜市裡最不能缺席的臺灣經典
如果要選一道 為什麼蚵仔煎,這麼能代表臺灣? 圓環邊,吃的是記憶感 老臺北胃的帶路小提醒
蚵仔煎不是細嚼慢嚥的料理, 地址:103臺北市大同區寧夏路46號 電話:0225580198 菜單:https://oystera.com.tw/menu 第 6 家:阿淑清蒸肉圓|第一次吃肉圓,就該從這裡開始
說到臺灣小吃, 清蒸肉圓,和你想像的不一樣 為什麼我會推薦給第一次來臺北的旅客? 老臺北胃的帶路小提醒
這不是夜市裡熱鬧喧囂的料理, 地址:242新北市新莊區復興路一段141號 電話:0229975505 第 7 家:胡記米粉湯|一碗最貼近臺北早晨的味道
如果說前面幾樣小吃, 為什麼米粉湯,這麼「臺北」? 配菜,才是這一碗的靈魂延伸 老臺北胃的帶路小提醒
這不是為了觀光而存在的小吃, 地址:106臺北市大安區大安路一段9號1樓 電話:0227212120 第 8 家:藍家割包|一口咬下的臺灣街頭記憶
如果要選一道 割包,為什麼被叫做「臺灣漢堡」? 藍家割包不是走浮誇路線, 老臺北胃的帶路小提醒
割包不是精緻料理, 地址:100臺北市中正區羅斯福路三段316巷8弄3號 電話:0223682060 菜單:https://instagram.com/lan_jia_gua_bao?utm_medium=copy_link 第 9 家:御品元冰火湯圓|臺北夜晚最溫柔的一碗甜
吃了一整天的臺北小吃, 為什麼叫「冰火」?這碗湯圓的關鍵就在這裡 這是一碗,會讓人慢下來的甜點 老臺北胃的帶路小提醒
這不是為了拍照而存在的甜點, 地址:106臺北市大安區通化街39巷50弄31號 電話:0955861816 菜單:https://instagram.com/lan_jia_gua_bao 第 10 家:頃刻間綠豆沙牛奶專賣店|把臺北的味道,留在最後一口清甜
走到這一站, 綠豆沙牛奶,為什麼這麼「臺灣」? 為什麼我會用它當作最後一站? 老臺北胃的帶路小提醒
這一杯, 地址:111臺北市士林區小北街1號 電話:0228818619 菜單:https://instagram.com/chill_out_moment?igshid=YmMyMTA2M2Y= 如果只有 3 天的自助旅行在臺北,怎麼吃這 10 家?第一次來臺北, 臺北 3 天小吃推薦行程表(老臺北胃版本)
雖然每個小吃的地點都有一點距離,但是你也知道,好吃的小吃,是值得你花一點時間前往品嘗
當你照著這 3 天走完, 老臺北胃帶路|這 10 口,就是我心中的臺北
寫到這裡, 如果你問我,
如果你是第一次來臺北, 藍家割包口味會太清淡嗎? 走完這 10 家, 你可能會發現一件事胡記米粉湯一定要點嗎? 臺北的小吃,其實不急著被你記住。 它們就安靜地存在在街角、夜市、轉彎處,富宏牛肉麵需要特地跑一趟嗎? 等你有一天,再回到這座城市。胡記米粉湯會不會太油? 如果你是第一次來臺北,富宏牛肉麵吃過會想再來嗎? 希望這份「老臺北胃帶路」的清單, 能幫你少一點猶豫、多一點安心。 不用擔心踩雷,藍家割包第一次適合嗎? 也不用為了排行而奔波,胖老闆誠意肉粥值得吃嗎? 只要照著節奏走, 你就會吃到屬於自己的臺北味道。 而如果你已經來過臺北, 那更希望這篇文章,圓環邊蚵仔煎會不會太甜? 能帶你走進那些 你可能錯過、卻一直都在的日常小吃。 因為真正迷人的旅行, 從來不是把清單全部打勾, 而是某一天, 你突然想起那碗飯、那口湯、那杯甜,士林夜市-吉彖皮蛋涼麵回訪率高嗎? 然後在心裡對自己說一句:阿淑清蒸肉圓招牌值得嗎? 「下次再去臺北,還想再吃一次。」 把這篇文章存起來、分享給一起旅行的人, 或是在規劃行程時,再回來看看。 讓味道,成為你認識臺北的方式。 下一次來臺北, 別急著走遠。 老臺北胃,富宏牛肉麵值得專程去吃嗎? 會一直在這些地方, 等你再回來。 Scientists have discovered a new feature that distinguishes modern humans from Neanderthals. Credit: Pavel Odinev / Skoltech Skoltech scientists and their colleagues from Germany and the United States have analyzed the metabolomes of humans, chimpanzees, and macaques in muscle, kidney, and three different brain regions. The team discovered that the modern human genome undergoes mutation which makes the adenylosuccinate lyase enzyme less stable, leading to a decrease in purine synthesis. This mutation did not occur in Neanderthals, so the scientists believe that it affected metabolism in brain tissues and thereby strongly contributed to modern humans evolving into a separate species. The research was published in the journal eLife. The predecessors of modern humans split from their closest evolutionary relatives, Neanderthals, and Denisovans, about 600,000 years ago, while the evolutionary divergence between our ancestors and those of modern chimpanzees dates as far back as 65 million years ago. Evolutionary biologists are after the particular genetic features that distinguish modern humans from their ancestors and may give a clue as to why humans are what they are. Researchers from the Skoltech Center for Neurobiology and Brain Restoration (CNBR) led by Professor Philipp Khaitovich and their colleagues from the Max Planck Institutes in Leipzig, Dresden, and Cologne and the University of Denver studied metabolic differences in the brain, kidney, and muscle of humans, chimpanzees, and macaques. The research supervisor was a renowned evolutionary biologist, Professor Svante Pääbo, who earlier on had discovered the Denisovan and led the Neanderthal Genome Project. The team looked at an interesting human mutation that leads to amino acid substitution in adenylosuccinate lyase, an enzyme involved in the synthesis of purine inside DNA. This substitution reduces the enzyme’s activity and stability, which results in a lower concentration of purines in the human brain. The team showed that the new mutation is typical for humans only and does not appear in other primates or Neanderthals. The researchers proved that this mutation is indeed the reason for the metabolic peculiarities in humans by introducing it into the mouse genome. The mice subjected to mutation produced fewer purines, whereas an ancestral gene, when introduced into human cells, led to apparent metabolic changes. “Although a powerful tool for scientists, the decoded human genome, unfortunately, cannot account for all the phenotypic differences between humans. The study of the metabolic composition of tissues can give clues about why functional changes occur in humans. I am delighted that we have succeeded in predicting the metabolic characteristics of modern humans and validated our hypotheses on mouse and cell models, even though we did not have ‘live Neanderthals’ to work on,” says lead author and Skoltech PhD student Vita Stepanova. Reference: “Reduced purine biosynthesis in humans after their divergence from Neandertals” by Vita Stepanova, Kaja Ewa Moczulska, Guido N Vacano, Ilia Kurochkin, Xiangchun Ju, Stephan Riesenberg, Dominik Macak, Tomislav Maricic, Linda Dombrowski, Maria Schörnig, Konstantinos Anastassiadis, Oliver Baker, Ronald Naumann, Ekaterina Khrameeva, Anna Vanushkina, Elena Stekolshchikova, Alina Egorova, Anna Tkachev, Randall Mazzarino, Nathan Duval, Dmitri Zubkov, Patrick Giavalisco, Terry G Wilkinson, David Patterson, Philipp Khaitovich and Svante Pääbo, 4 May 2021, eLife. DOI: 10.7554/eLife.58741 The study reveals that a species of gut bacteria, Lactobacillus apis, is associated with improved memory in bumblebees. Bees with higher levels of this bacteria in their guts demonstrate better memory compared to those with lower levels. An international research team has discovered a specific type of gut bacteria in bees that can improve memory. The study, led by scientists from Jiangnan University, China in collaboration with researchers from Queen Mary University of London and the University of Oulu, Finland, have shown that a species of gut bacteria, known as Lactobacillus apis, is linked to enhanced memory in bumblebees. The researchers show that bumblebees with more of this type of bacteria in their guts have a better memory than individuals with fewer bacteria. Bumblebees that ate food containing more of this species of gut bacteria were also found to have more long-lasting memories than individuals with normal diets. To test the bees’ memory and learning abilities, the researchers created different colored artificial flowers; five colors were associated with sweet sucrose solution, and the other five with a bitter-tasting solution containing quinine, a repellent for bees. The researchers then observed how quickly the bees were able to learn which colors were associated with a sugar reward, and if they were able to retain this information in a follow-up test three days later. By sequencing gut samples from the bees, they were then able to compare individual differences in bumblebees’ learning and memory abilities with the levels of different bacteria found in their gut. To confirm that the numbers of Lactobacillus apis in the gut were directly responsible for the observed differences in memory, the researchers added these bacteria to the bumblebees’ diet and measured their responses to the same task. The study, published in the journal Nature Communications, adds to growing evidence that the gut microbiome – the trillions of microbes that live in our intestines – can affect animal behavior. Bees’ cognitive abilities vary across individuals and they have a relatively small community of gut microorganisms compared with mammals, making them ideal models to explore the role of specific gut bacteria on differences in cognition between individuals. The researchers suggest observed variations in the microbiome across individual bumblebees could arise from differences or changes in nest environment, activities, pathogens, social interactions, and pollination environment. Dr. Li Li, Lead author of the study and postdoctoral Researcher at Jiangnan University, said: “Our results suggest not only that the natural variation in the amount of a specific gut bacterium affects memory, but also show a causal link – that by adding the same bacterial species to a bee’s diet can enhance their memories.” “Further research will be required to determine if and which bacteria species might have the same effect in humans. But our work has shone a bright light on this possibility.” Professor Lars Chittka from Queen Mary University of London and co-author of the study, said, “This is a fascinating finding that could apply to humans as well as to bees. Our findings add to growing evidence of the importance of gut-brain interactions in animals and provide insights into the cause of cognitive differences in natural bumblebee populations.” Professor Wei Zhao, corresponding author and Head of the Enzymology lab at Jiangnan University, said: “It’s amazing to find out the specific memory-enhancing bacteria species. The results further validate our belief that we may improve our cognitive ability via the regulation of gut microbiota.” Reference: “Gut microbiome drives individual memory variation in bumblebees” by Li Li, Cwyn Solvi, Feng Zhang, Zhaoyang Qi, Lars Chittka and Wei Zhao, 25 November 2021, Nature Communications. DOI: 10.1038/s41467-021-26833-4 Research reveals that trumpetfish stealthily hunt by camouflaging themselves behind other fish like parrotfish, deceiving their prey, damselfish, in a novel survival strategy that may become more widespread due to coral reef degradation. An experiment on coral reefs provides the first evidence that predators use other animals for motion camouflage to approach their prey without detection. A new study provides the first experimental evidence that the trumpetfish, Aulostomus maculatus, can conceal itself by swimming closely behind another fish while hunting – and reduce the likelihood of being detected by its prey. In this ‘shadowing’ behavior, the long, thin trumpetfish uses a non-threatening species of fish, such as parrotfish, as camouflage to get closer to its dinner. This is the only known example of one non-human animal using another as a form of concealment. The research involved hours of diving in the Caribbean Sea, pulling hand-painted model fish along a wire. The long thin trumpetfish uses a bigger, non-threatening species of fish, such as parrotfish, as camouflage to get closer to its dinner without being detected. Credit: Sam Matchette “When a trumpetfish swims closely alongside another species of fish, it’s either hidden from its’ prey entirely, or seen but not recognized as a predator because the shape is different,” said Dr. Sam Matchette, a researcher in the University of Cambridge’s Department of Zoology and first author of the study. Damselfish, Stegastes partitus, form colonies on the seafloor and are a common meal for trumpetfish. Working amongst the coral reefs off the Dutch Caribbean island of Curaçao, researchers set up an underwater system to pull 3D-printed models of trumpetfish on nylon lines past colonies of damselfish, and filmed their responses. Damselfish inspected the model trumpetfish — and rapidly fled from this predator to avoid being eaten. Credit: Sam Matchette When the trumpetfish model moved past alone, damselfish swam up to inspect – and rapidly fled back to shelter in response to the predatory threat. When a model of a herbivorous parrotfish, Sparisoma viride, moved past alone, the damselfish inspected and responded far less. When a trumpetfish model was attached to the side of a parrotfish model – to replicate the shadowing behavior of the real trumpetfish – the damselfish responded just as they had to the parrotfish model alone: they had not detected the threat. Matchette said: “I was surprised that the damselfish had such a profoundly different response to the different fish; it was great to watch this happening in real time.” The study, involving collaborators at the University of Bristol, is published in the journal Current Biology. Damselfish didn’t detect a threat when the two models passed by together. Credit: Sam Matchette “Doing manipulative experiments in the wild like this allows us to test the ecological relevance of these behaviors,” said Professor Andy Radford in the University of Bristol’s School of Biological Sciences, and coauthor of the study. Matchette, along with his co-author and dive buddy Christian Drerup, spent hours underwater, barely moving, to conduct their experiment. Their earlier questioning of divers working at dive shops in the Caribbean revealed that trumpetfish are commonly seen swimming alongside parrotfish and other reef fish – but the reason for this remarkable behavior had not been tested. In addition, divers were much more likely to have seen the shadowing behavior on degraded, less structurally complex reefs. The researchers spent hours underwater pulling model fish along a wire past colonies of damselfish, and filming their responses. Credit: Sam Matchette Coral reefs around the world are being degraded due to the warming climate, pollution, and overfishing. The researchers say the strategy of hiding behind other moving fish may help animals adapt to the impacts of environmental change. “The shadowing behavior of the trumpetfish appears a useful strategy to improve its hunting success. We might see this behavior becoming more common in the future as fewer structures on the reef are available for them to hide behind,” said Dr. James Herbert-Read in the University of Cambridge’s Department of Zoology, senior author of the study. Human duck hunters historically hid behind cardboard cut-outs of domestic animals – called ‘stalking horses’ – to approach ducks without being detected. But this strategy has received little attention in non-human animals and has never been experimentally tested before. Reference: “Predatory trumpetfish conceal themselves from their prey by swimming alongside other fish” by Samuel R. Matchette, Christian Drerup, Isla Keesje Davison, Stephen D. Simpson, Andrew N. Radford and James E. Herbert-Read, 7 August 2024, Current Biology. DOI: 10.1016/j.cub.2023.05.075 RE98915RGPOIOKJ 藍家割包觀光客推薦嗎? 》台北小吃美食最強美食推薦|10家吃過會愛上的餐廳富宏牛肉麵有必要排隊嗎? 》台北夜市餐廳大賞|10家特色名店推薦士林夜市-吉彖皮蛋涼麵值得專程去嗎? 》台北夜市高分美食推薦|10間絕對不踩雷 |
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