字體:小 中 大 |
|
|
|||||||||||||||||||||||||||||||||||||||||||||
| 2025/12/24 14:22:03瀏覽37|回應0|推薦0 | |||||||||||||||||||||||||||||||||||||||||||||
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, 胖老闆誠意肉粥好吃嗎? 走完這 10 家, 你可能會發現一件事士林夜市-吉彖皮蛋涼麵會不會太油? 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,富宏牛肉麵會踩雷嗎? 等你有一天,再回到這座城市。饌堂-黑金滷肉飯(雙連店)會不會太油? 如果你是第一次來臺北,胡記米粉湯好吃嗎? 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,御品元冰火湯圓女生會喜歡嗎? 也不用為了排行而奔波,御品元冰火湯圓早上吃適合嗎? 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,圓環邊蚵仔煎值得排隊嗎? 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,胖老闆誠意肉粥會不會太油? 然後在心裡對自己說一句:胡記米粉湯需要加料嗎? 「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,圓環邊蚵仔煎真的好吃嗎? 會一直在這些地方, 等你再回來。 Ducibella camanchacais a fast-swimming predator researchers named after “darkness.” At nearly 4 centimeters in length, this crustacean uses specialized raptorial appendages to capture and preyupon smaller amphipod species.The newly discovered crustacean is the first large, active predatory amphipod from the extreme depths of Atacama Trench. Credit: Johanna Weston, ©Woods Hole Oceanographic Institution Researchers have discovered a new predatory crustacean species, Dulcibella camanchaca, in the hadal zone of the Atacama Trench. This finding highlights the adaptive evolution necessary for survival in extreme deep-sea environments and underscores the importance of continued exploration and study of these remote ecosystems. Discovery of Dulcibella Camanchaca The ocean’s hadal zone, defined by crushing pressure and total darkness, might seem uninhabitable, but it’s home to a surprising array of unique creatures. Every new species discovered there helps scientists better understand how life adapts and even thrives in one of Earth’s harshest environments. A recent study published in the journal Systematics and Biodiversity introduces one such species: Dulcibella camanchaca, a newly identified deep-sea crustacean. It’s the first known large, active predatory amphipod from the hadal depths. Researchers from the Woods Hole Oceanographic Institution (WHOI) and the Instituto Milenio de Oceanografía (IMO) at the Universidad de Concepción, Chile, made the groundbreaking discovery. “Dulcibella camanchaca is a fast-swimming predator that we named after “darkness” in the languages of the peoples from the Andes region to signify the deep, dark ocean from where it predates,” explained Dr. Johanna Weston, the study’s co-lead author and a hadal ecologist at WHOI. Ducibella camanacha causes specialized raptorial appendages to capture and prey upon smaller amphipod species in the Atacama Trench’s food-limited realm. The trench stretches along the eastern South Pacific Ocean, plunging to depths exceeding 8,000 meters. Credit: Johanna Weston, ©Woods Hole Oceanographic Institution Adaptations and Habitat At nearly 4 centimeters in length, this crustacean uses specialized raptorial appendages to capture and prey upon smaller amphipod species in the Atacama (Peru-Chile) Trench’s food-limited realm. The trench stretches along the eastern South Pacific Ocean, plunging to depths exceeding 8,000 meters off the coast of northern Chile, and has long fascinated scientists. Located beneath nutrient-rich and productive surface waters and geographically remote from other hadal environments, the Atacama Trench hosts a distinctive community of native species. “Most excitingly, the DNA and morphology data pointed to this species being a new genus too, emphasizing the Atacama Trench as an endemic hotspot,” continued Weston. Schematic diagram of the Integrated Deep-Ocean Observing System (IDOOS), which is completed by an on-land seismic network. Credit: Felipe Gamonal Impact of the IDOOS Expedition This remarkable finding is part of the 2023 Integrated Deep-Ocean Observing System (IDOOS) Expedition aboard the R/V Abate Molina, led by scientists from IMO. Four Dulcibella camanchaca individuals were collected at a depth of 7,902 meters using a lander vehicle, which is an untethered platform used for carrying scientific equipment, including baited traps, to and from the ocean floor. Once safely back on the ship’s deck, recovered amphipods were frozen and then underwent detailed morphological and genetic analysis at the Universidad de Concepción. “This study’s collaborative effort and integrative approach confirmed Dulcibella camanchaca as a new species and highlights ongoing biodiversity discoveries in the Atacama Trench. This finding underlines the importance of continued deep-ocean exploration, particularly in Chile’s front yard,” said Dr. Carolina González, co-lead author from the IMO responsible for sample collection and DNA analysis. “More discoveries are expected as we continue to study the Atacama Trench.” The Future of Deep-Ocean Exploration As exploration technology advances, scientists anticipate uncovering more species, each offering insights into the evolutionary pressures and adaptations unique to the deep ocean. The results of this study will contribute to broader efforts to understand deep-ocean ecosystems and protect them from emerging threats, such as pollution and climate change. Reference: “A new large predator (Amphipoda, Eusiridae) hidden at hadal depths of the Atacama Trench” by Johanna N. J. Weston, Carolina E. González, Rubén Escribano and Osvaldo Ulloa, 27 November 2024, Systematics and Biodiversity. DOI: 10.1080/14772000.2024.2416430 A Swedish study shows that providing food for small birds during winter results in healthier birds with better immune response. As birds face new pathogens due to climate change and human activity, understanding factors like winter feeding is important for their survival. Seeds and fat balls do more than just fill small birds’ stomachs. New research from Lund University in Sweden shows that feeding during the wintertime causes birds to be healthier, since they do not have to expend as much energy fighting infections. A small change in body temperature can be fatal for humans. Small birds, meanwhile, lower their body temperature at night by several degrees during the winter. Just like us, the birds attempt to save energy when it is cold. If they are exposed to infection, the body’s first reaction is to raise its temperature, which clashes with the bird’s simultaneous need to save energy by lowering body temperature. “We investigated how access to food during winter affected the balancing act between maintaining a low body temperature in order to save energy, and the possibility of raising body temperature in order to fight infection,” says Hannah Watson, a biologist at Lund University. The study shows that birds who were fed during the winter did not need to lower their body temperature as much at night as birds who did not have access to feeding tables. They had gathered enough energy to survive a winter night in spite of a having higher body temperature. When the birds were exposed to a simulated infection, all the birds had essentially the same temperature during a fever. Instead of conserving energy to survive the winter, the birds without access to extra food were forced to use more energy in order to raise their body temperature high enough to battle infection. Unexpected Findings on Immune Response “We had expected to find that the birds that had access to birdfeeders would have more energy to fight an infection, and that as a result they would exhibit a stronger fever response. Our results, however, show the opposite – birds that did not have access to a reliable source of food had the strongest reaction to infection. This enabled them to reach the same fever temperature as the birds with extra food,” says Hannah Watson. Climate change and human activity are having an ever-increasing impact on animals. Wild animals come into contact with new pathogens that they have never encountered before. Bird feeding, then, can have positive and negative effects. Birds that visit feeding tables are exposed to more infection because of the spread of pathogens, but this could make their immune defenses more tolerant to a new infection. It is therefore important, the researchers argue, to understand the factors that affect animals’ capacity to put up an effective immune response – access to food during winter being one such example. “A lot of people like to feed the birds. Our study shows that this can have a positive effect on the capacity of our small birds to fight an infection,” concludes Hannah Watson. Reference: “Thermoregulatory costs of the innate immune response are modulated by winter food availability in a small passerine” by Hannah Watson, Jan-Åke Nilsson and Johan F. Nilsson, 9 April 2023, Journal of Animal Ecology. DOI: 10.1111/1365-2656.13914 An apoptotic, or dying cell, characterized by its wavy membrane, lies within a cultured sheet of epithelial cells. Credit: Yuma Cho and Junichi Ikenouchi, Kyushu University Researchers at Kyushu University have discovered a vital role for calcium in getting rid of dead cells in our body’s protective tissues. This finding is crucial for understanding how our bodies keep the outer and inner surfaces clean and safe from infection. The study, using advanced techniques, shows that when cells in these protective layers die, calcium helps the neighboring cells quickly remove them, maintaining a healthy barrier. Discovery of a New Cellular Mechanism Researchers at Kyushu University in Japan have uncovered a calcium-driven process crucial for removing dead cells, enhancing our understanding of how our bodies maintain health and prevent disease. Published recently in the journal Current Biology, their findings show that calcium ion levels are vital for effectively clearing dying cells, known as apoptotic cells, from epithelial tissues—these are the cells that form protective linings on body surfaces. The study utilized genetically modified epithelial tissue cultures, along with molecular markers and sophisticated imaging techniques to observe this process. Vital Barriers and Cellular Defense Epithelial cells cover the outer and inner surfaces of our bodies, including the skin and internal organs, serving as essential protective barriers. When these cells become damaged and die, a process known as apoptosis, adjacent cells quickly collaborate to eject the dead cells and close any openings. This action helps prevent the entry of harmful substances that could lead to infections or inflammation. While this process is critical for maintaining the integrity of epithelial barriers, the detailed mechanisms involved were not fully understood until this recent discovery. The study, led by Professor Junichi Ikenouchi and his colleagues, Dr. Kenji Matsuzawa and Mr. Yuma Cho, the first author, from Kyushu University, also included contributions from collaborators from the University of Tokyo and Health Sciences University of Hokkaido in Japan. In this image, the cell marked with an asterisk was damaged using a focused laser, triggering apoptosis. After an initial increase in general calcium levels around the dying cell (calcium wave), a sustained increase in calcium levels was observed at the interface between the apoptotic cell and the surrounding cells (marked B and D). This new mechanism is essential for expelling the apoptotic cell and preserving the integrity of the epithelium. Credit: Junichi Ikenouchi, originally published in https://doi.org/10.1016/j.cub.2024.08.057 Introduction to CaRE: A Calcium Response Mechanism To begin with, the team induced apoptosis in individual epithelial cells using a focused laser and observed the response in the surrounding cells. They then observed how nearby cells reacted by modifying them to express special calcium ion probes called GCaMP6, which allowed them to visualize real-time calcium changes. Interestingly, they found that the neighbors of the apoptotic cell showed a significant spike in calcium levels, particularly near the membrane regions interfacing with the dying cell. The researchers named this intriguing phenomenon the “calcium response in effectors of apical extrusion (CaRE).” Role of IP3 Receptors and Desmosomes in Cell Removal Delving deeper into this newly discovered mechanism, the team next examined the role of IP3 receptors, proteins present inside cells that help regulate calcium ion levels. They found that inhibiting the activity of IP3 receptors or removing their associated genes completely prevented the expulsion of apoptotic cells. Further analysis using advanced electron microscopy revealed that a specific subset of IP3 receptors, particularly those located near desmosomes, plays a key role in CaRE. Desmosomes are cell adhesion structures that form strong connections between cells, acting like buttons that hold them together. They are especially important in tissues like skin and organ linings, helping to keep everything intact and functioning properly. By ensuring neighboring cells adhere tightly, desmosomes play a key role in maintaining the structure and stability of our body’s tissues. The team found that the activation of IP3 receptors near desmosomes is necessary for triggering the contraction of a group of proteins known as actomyosin complex, which helps cells change shape and move, facilitating the removal of apoptotic cells. “Our study sheds light on a newfound role of IP3 receptors in desmosomes, the latter of which were previously thought to be involved only in mechanical connections between epithelial cells,” highlights Ikenouchi. As this study was conducted on cultured cells, the team notes that further analysis of the CaRE mechanism is needed to determine whether the mechanism also functions in living organisms, if it varies between different organ tissues, and whether other factors also play a role. Overall, this study advances our understanding of how our bodies maintain a healthy epithelium—something many of us take for granted. “Our findings provide valuable insights into understanding diseases caused by epithelial barrier disruption, such as atopic dermatitis and inflammatory bowel disease, and may contribute to the development of new preventive measures and treatments for chronic inflammation,” concludes Ikenouchi. Reference: “A sustained calcium response mediated by IP3 receptor anchoring to the desmosome is essential for apoptotic cell elimination” by Yuma Cho, Ikuko Koyama-Honda, Akihiko Tanimura, Kenji Matsuzawa and Junichi Ikenouchi, 23 September 2024, Current Biology. DOI: 10.1016/j.cub.2024.08.057 RE98915RGPOIOKJ 胡記米粉湯不加辣好吃嗎? 》台北小吃食記攻略|10家餐廳評分&推薦阿淑清蒸肉圓女生會喜歡嗎? 》台北小吃美食街攻略|10家熱門餐廳全紀錄富宏牛肉麵名過其實嗎? 》台北夜市聚餐推薦|10大類型餐廳評比 |
|||||||||||||||||||||||||||||||||||||||||||||
| ( 時事評論|家庭親子 ) |























