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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, 圓環邊蚵仔煎當正餐適合嗎? 走完這 10 家, 你可能會發現一件事胡記米粉湯觀光客推薦嗎? 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,頃刻間綠豆沙牛奶專賣店辣的推薦嗎? 等你有一天,再回到這座城市。饌堂-黑金滷肉飯(雙連店)外國人能接受嗎? 如果你是第一次來臺北,胡記米粉湯價格合理嗎? 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,頃刻間綠豆沙牛奶專賣店值得專程去嗎? 也不用為了排行而奔波,饌堂-黑金滷肉飯(雙連店)推薦點什麼? 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,藍家割包當點心適合嗎? 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,胖老闆誠意肉粥吃起來順口嗎? 然後在心裡對自己說一句:胡記米粉湯男生會吃得飽嗎? 「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,頃刻間綠豆沙牛奶專賣店當正餐適合嗎? 會一直在這些地方, 等你再回來。 Scientists have discovered that AP2A1 controls cellular aging, making it a promising target for anti-aging therapies. Suppressing AP2A1 reverses aging in cells, while increasing it accelerates senescence. Researchers from Osaka University have discovered that the protein subunit AP2A1 may play a role in the unique structural organization of senescent cells. There are countless products on the market that claim to restore a youthful appearance by reducing wrinkles or tightening the jawline. But what if aging could be reversed at the cellular level? Researchers in Japan may have uncovered a way to do just that. A recent study published in Cellular Signaling by scientists at Osaka University identifies a key protein that regulates the transition between “young” and “old” cell states. As the body ages, senescent cells—older, less active cells—accumulate in various organs. These cells are significantly larger than younger ones and display structural changes, including altered organization of stress fibers, which are essential for movement and interaction with their environment. “We still don’t understand how these senescent cells can maintain their huge size,” says lead author of the study Pirawan Chantachotikul. “One intriguing clue is that stress fibers are much thicker in senescent cells than in young cells, suggesting that proteins within these fibers help support their size.” Graphical abstract. Credit: Chantachotikul et al., Osaka University The Role of AP2A1 in Cellular Senescence To explore this possibility, the researchers examined AP2A1 (Adaptor Protein Complex 2, Alpha 1 Subunit). AP2A1 is a protein that is upregulated in the stress fibers of senescent cells, including fibroblasts, which create and maintain the skin’s structural and mechanical characteristics, and epithelial cells. The researchers eliminated AP2A1 expression in older cells and overexpressed AP2A1 in young cells to determine the effect on senescence-like behaviors. “The results were very intriguing,” explains Shinji Deguchi, senior author. “Suppressing AP2A1 in older cells reversed senescence and promoted cellular rejuvenation, while AP2A1 overexpression in young cells advanced senescence.” Furthermore, the researchers found that AP2A1 is often closely associated with integrin β1, a protein that helps cells latch onto the scaffolding-like collagen matrix that surrounds them, and that both AP2A1 and integrin β1 move along stress fibers within cells. In addition, integrin β1 strengthened cell–substrate adhesions in fibroblasts; this might explain the cause of the raised or thickened structures characteristic of senescent cells. “Our findings suggest that senescent cells maintain their large size through improved adhesion to the extracellular matrix via AP2A1 and integrin β1 movement along enlarged stress fibers,” concludes Chantachotikul. Given that AP2A1 expression is so closely linked to signs of aging in senescent cells, it could potentially be used as a marker for cellular aging. The research team’s work may also provide a new treatment target for diseases that are associated with old age. Reference: “AP2A1 modulates cell states between senescence and rejuvenation” by Pirawan Chantachotikul, Shiyou Liu, Kana Furukawa and Shinji Deguchi, 21 January 2025, Cellular Signalling. DOI: 10.1016/j.cellsig.2025.111616 Researchers found microplastics in coral mucus, tissue, and skeleton, suggesting coral may absorb microplastics and act as a “sink” for ocean plastic. These findings help address the “missing plastic problem” and require further research to understand their global implications. Researchers have discovered microplastics in all components of coral, including its skeleton. Researchers from Japan and Thailand have discovered microplastics in all three parts of coral anatomy—surface mucus, tissue, and skeleton. This breakthrough was achieved using a newly developed microplastic detection method, which the team applied to coral for the first time. These findings may also explain the ‘missing plastic problem’ that has puzzled scientists, where about 70% of the plastic litter that has entered the oceans cannot be found. The team hypothesizes that coral may be acting as a ‘sink’ for microplastics by absorbing it from the oceans. Their findings were published in the journal Science of the Total Environment. Humanity’s dependence on plastics has brought unprecedented convenience to our lives but has caused untold damage to our ecosystem in ways researchers are still beginning to understand. In the oceans alone, it is estimated that 4.8–12.7 million tons of plastics flow into the marine environment annually. A variety of microplastics extracted from corals off the coast of Si Chang Island in the Gulf of Thailand. As seen by the color, shape, and size, coral will consume a wide range of microplastics, with many of them thinner than a strand of human hair. Credit: Kyushu University/Isobe lab “In Southeast Asia, plastic pollution has become a significant issue. Collectively, nearly 10 million tons of plastic waste are dumped annually, equivalent to 1/3 of the world’s total,” explains Assistant Professor Suppakarn Jandang from Kyushu University’s Research Institute for Applied Mechanics (RIAM) and first author of the study. “Some of this plastic is discharged into the ocean, where it degrades into microplastics.” To study the plastic pollution problem in Southeast Asia, RIAM partnered with Thailand’s Chulalongkorn University in 2022 to establish the Center for Ocean Plastic Studies. The international institute is led by Professor Atsuhiko Isobe, who also led the research team behind these latest findings. The team wanted to examine the impact of microplastics on local coral reefs, so they focused their fieldwork on the coast of Si Chang Island in the Gulf of Thailand. The area is known for its small reef flats as well as being a common area for anthropological studies. Extracting Microplastics from Coral “Coral has three main anatomical parts: the surface mucus, the outside of the coral body; the tissue, which is the inner parts of the coral; and the skeleton, the hard deposits of calcium carbonate they produce. Our first step was to develop a way to extract and identify microplastics from our coral samples,” continues Jandang. “We put our samples through a series of simple chemical washes designed to break apart each anatomical layer. After each subsequent layer was dissolved, we would filter out the content and then work on the next layer.” Assistant Professor Suppakarn Jandang (right) and team are preparing to collect coral samples for microplastic analysis. Credit: Kyushu University/Isobe Lab In total, they collected and studied 27 coral samples across four species. 174 microplastic particles were found in their samples, mostly ranging from 101–200 μm in size, close to the width of a human hair. Of the detected microplastics 38% were distributed on the surface mucus, 25% in the tissue, and 37% were found in the skeleton. As for types of microplastics, the team found that nylon, polyacetylene, and polyethylene terephthalate (PET) were the three most prevalent, accounting for 20.11%, 14.37%, and 9.77%, respectively, of the identified samples. Corals as a “Sink” for Microplastics These new findings also indicate that coral may act as a marine plastic ‘sink’, sequestering plastic waste from the ocean, like how trees sequester CO2 from the air. “The ‘missing plastic problem’ has been troubling scientists who track marine plastic waste, but this evidence suggests that corals could account for that missing plastic,” says Jandang. “Since coral skeletons remain intact after they die, these deposited microplastics can potentially be preserved for hundreds of years. Similar to mosquitos in amber.” Further study is still necessary to understand the full impact of these findings on coral reefs and the global ecosystem. “The corals that we studied this time are distributed all around the world. To get a more accurate picture of the situation we must conduct extensive studies globally across an array of coral species,” concludes Isobe. “We also do not know the health effects of microplastics on coral and the larger reef community. There is still much to be done to accurately evaluate the impact of microplastics on our ecosystem.” Reference: “Possible sink of missing ocean plastic: Accumulation patterns in reef-building corals in the Gulf of Thailand” by Suppakarn Jandang, María Belén Alfonso, Haruka Nakano, Nopphawit Phinchan, Udomsak Darumas, Voranop Viyakarn, Suchana Chavanich and Atsuhiko Isobe, 14 September 2024, Science of The Total Environment. DOI: 10.1016/j.scitotenv.2024.176210 Funding: Science and Technology Research Partnership for Sustainable Development, Japan Science and Technology Agency, Japan International Cooperation Agency, Kyushu University, Japan Society for the Promotion of Science The pathogen Pseudomonas aeruginosa forms a protective biofilm. Credit: Nano Imaging Lab SNI/Biozentrum, University of Basel Bacteria detect cell wall fragments as danger signals and form protective biofilms, a survival strategy seen across species and relevant for fighting infections. University of Basel researchers have discovered that bacteria can sense threats in advance through a general danger signal. Bacteria detect when nearby cells are dying and proactively form a protective biofilm. Understanding how bacteria communicate and respond to threats is crucial for combating infections. Bacteria are constantly engaged in a struggle for survival, facing threats from immune cells, antibiotics, or phages— viruses that only infect bacteria. Over the course of evolution, bacteria have developed numerous strategies to protect themselves from such dangers. But how do bacteria sense potential threats in their environment and initiate protective measures? Danger signal: Cell wall fragments In their recent study, researchers led by Prof. Knut Drescher at the Biozentrum, University of Basel, have discovered that fragments of the bacterial cell wall, so-called peptidoglycans, serve as an alarm signal indicating danger in the environment. “These molecules act as a general danger signal recognized not only by conspecifics but also by bacteria of different species,” says Drescher “Peptidoglycans are released when bacteria are killed by phages or antibiotics.” Protective mechanism: Biofilm formation Bacteria respond to this danger signal by producing a small signaling molecule known as c-di-GMP, which triggers biofilm formation. Biofilms are complex, three-dimensional structures of living bacteria embedded in a slimy matrix. “In Vibrio cholerae, the cholera-causing pathogen, even a brief exposure to cell wall fragments triggers biofilm formation,” explains Sanika Vaidya, first author of the study. Within the biofilm, bacteria are protected from attacks by phages, immune cells, and antibiotics. Survival strategy: Cross-species warning The researchers observed this behavior not only in the cholera pathogen but also in other dangerous, often multi-drug resistant pathogens such as Pseudomonas aeruginosa, Acinetobacter baumannii, Staphylococcus aureus, and Enterococcus faecalis. The fact that bacteria across species respond to the same danger signal suggests a universal survival strategy. “Interestingly, human immune cells also recognize peptidoglycan fragments as an infection signal,” emphasizes Drescher. “This highlights surprising parallels between bacterial and human defense mechanisms.” Clinical relevance: Preventing biofilms This universal survival strategy may explain why biofilms play such an important role in various environments — from natural ecosystems to human infections. However, the study raises new questions: Do the cell wall fragments activate additional protective mechanisms beyond biofilm formation? And how can these novel insights be applied to more effectively combat biofilm-forming pathogens? Reference: “Bacteria use exogenous peptidoglycan as a danger signal to trigger biofilm formation” by Sanika Vaidya, Dibya Saha, Daniel K. H. Rode, Gabriel Torrens, Mads F. Hansen, Praveen K. Singh, Eric Jelli, Kazuki Nosho, Hannah Jeckel, Stephan Göttig, Felipe Cava and Knut Drescher, 3 January 2025, Nature Microbiology. DOI: 10.1038/s41564-024-01886-5 RE98915RGPOIOKJ 胡記米粉湯長輩會喜歡嗎? 》台北夜市美食人氣美食完整評比|10家一次破解圓環邊蚵仔煎值得吃嗎? 》台北夜市美食Top10|選店困難症救星士林夜市-吉彖皮蛋涼麵吃起來順口嗎? 》台北小吃美食愛店推薦|台中10間美食評比 |
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