EIKEN肺炎鏈球菌檢測試劑盒（免疫捕獲法）

廣州健侖生物科技有限公司

主要用途：用于檢測尿標本中的肺炎鏈球菌抗原，以支持肺炎鏈球菌感染的診斷。

產品規(guī)格：20T/盒

存儲條件：2-30℃

EIKEN肺炎鏈球菌檢測試劑盒（免疫捕獲法）

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【產品介紹】

EIKEN

二維碼掃一掃

【公司名稱】 廣州健侖生物科技有限公司
【】    楊永漢 
【】 
【騰訊 】 2042552662
【公司地址】 廣州清華科技園創(chuàng)新基地番禺石樓鎮(zhèn)創(chuàng)啟路63號二期2幢101-3室
【企業(yè)文化】

細胞中蛋白折疊多數發(fā)生在內質網(ER)，但是如果這個過程出現差錯，未折疊蛋白累積，對ER產生應激。這可觸發(fā)UPR，關閉翻譯，降低未折疊蛋白，增加蛋白質折疊機制的產生。然而，如果ER應激沒有解決，UPR也能誘導凋亡。
兩個主要因素控制UPR-IRE1a和PERK。IRE1a通過激活轉錄因子XBP1促進細胞存活，驅動細胞存活基因的表達。另一方面，PERK激活一種轉錄因子稱為CHOP，它反過來驅動促凋亡因子DR5的表達。
舊金山加州大學Peter Walter及其同事現已證實CHOP激活DR5，表明它是一種細胞自主過程。但是他們也發(fā)現IRE1a抑制DR5，直接降解它的mRNA通過一種稱為調節(jié)IRE1a依賴的降解(RIDD)過程。人類癌細胞系出于ER應激中的IRE1a抑制即可以防護DR5 mRNA降解又可以增加細胞凋亡。
每種生物都有一個共同的目標：生存。它的所有體細胞都在協同工作，以保持它活著。它們是通過微調的溝通手段而達成目的的。聯合柏林和劍橋大學，盧森堡大學的盧森堡系統生物醫(yī)學中心(LCSB)的科學家*揭示細胞信號從周圍環(huán)境轉換為內部信號的規(guī)律。就像一支管弦樂隊的一個孤立的音符，細胞的一個孤立信號處于次要性的地位。
“重要的是，該信號從細胞膜傳遞到細胞的強度和頻率的相對變化，”這項研究的*、LCSB的Alexander Skupin博士說，這項研究發(fā)表于《science Signaling》雜志上。
通過使空氣振動，一支管弦樂隊的樂器從而產生信號——音符。在細胞內，鈣離子負責攜帶信號。當來自于環(huán)境的一片信息——比如一個生物信使——與細胞的外膜相遇，細胞內的鈣離子被釋放。在那里，鈣離子控制各種適應過程。“乍一看，并沒有簡單的離子沖動模式，” Skupin解釋;“但它們在細胞內仍然以一種有意義的反應達到高潮，就像一個特定基因的激活。”
為了確定這一現象的潛在規(guī)律，研究人員結合成像技術和數學方法，研究人類腎細胞和大鼠肝細胞。他們發(fā)現，鈣沖動的強度和頻率經歷了的變化——都發(fā)生在細胞-內部和細胞-細胞之間。因此，它們所傳達的信息不能被孤立的信號單獨分析進行解釋。“這就像在一個樂團，在那里自己學習孤立的音符不容許有任何旋律的結果，”Skupin延續(xù)了音樂的比喻。 “你必須聽聽所有儀器的頻率和音量如何變化，以及產生旋律。然后你獲得了音樂作品的印象。”

現在，研究人員*成功地通過傾聽細胞的交流而獲得這樣一整個印象。他們發(fā)現，鈣沖動的過多變化導致彼此相對于一個特定的關系中：外部的刺激不會導致鈣沖動的增長，恰恰相反的是它們發(fā)生時的頻率有了變化——音樂廳中，交響曲中的儀器的音符會上升和下降。“這種模式是導致細胞反應的實際信號，” Skupin說。“我們的分析已經對此提供了解釋。”
“這些結果對于分析疾病很重要，” LCSB的主任魯迪·巴林教授說。“我們知道，在帕金森病中，神經細胞中的鈣平衡被破壞，并懷疑細胞之間的錯誤通信可能在神經退行性疾病的發(fā)病中發(fā)揮作用。隨著這些通信的基本規(guī)律的發(fā)現，如Alexander Skupin，他的團隊和我們的合作伙伴現在已經實現了，我們在帕金森病的分析中邁進了重要的一步。”
加州大學圣地亞哥分校醫(yī)學院的研究人員說，調節(jié)細胞周期進程(細胞分裂和復制的過程)中*的一種蛋白質，實際上激活一個關鍵的抑癌基因，而不是像以前認為的那樣使它失活。
“這項發(fā)現是我的實驗室20年來的研究結果，” 加州大學圣地亞哥分校醫(yī)學院細胞和分子系的教授史蒂文·f·道迪博士說。“它*抗原抗體了一個傳統的認知，即一個稱為p16-細胞周期蛋白D通路(癌癥中zui常見的遺傳通路突變)促進所有腫瘤細胞的細胞周期進程的一個基本方面。”這項研究結果發(fā)表于《eLife》雜志上。
細胞周期蛋白D是在細胞復制的*階段期間合成的，被認為有助于促進復雜的，多階段的過程，其中包括與視網膜母細胞瘤(Rb)蛋白的相互作用，Rb蛋白的功能是通過抑制細胞周期進程防止細胞過度生長，直到細胞準備分裂。RB是一個抑癌基因。

The majority of protein folding in cells occurs in the endoplasmic reticulum (ER), but if there is a mistake in this process, unfolded protein accumulates, stressing the ER. This triggers UPR, turning off translation, reducing unfolded proteins, and increasing the production of protein folding mechanisms. However, UPR also induces apoptosis if ER stress is not resolved.
Two major factors control UPR-IRE1a and PERK. IRE1a promotes cell survival by activating the transcription factor XBP1, driving the expression of cell-survival genes. On the other hand, PERK activates a transcription factor called CHOP, which in turn drives the expression of pro-apoptotic factor DR5.
Peter Walter and colleagues at the University of California, San Francisco, have now shown that CHOP activates DR5, indicating that it is a cell-autonomous process. However, they also found that IRE1a inhibits DR5 by directly degrading its mRNA through a process called regulation of IRE1a-dependent degradation (RIDD). Human cancer cell lines protect DR5 mRNA from degradation and increase apoptosis as well, due to IRE1a inhibition in ER stress.
Each creature has a common goal: to survive. All its somatic cells are working together to keep it alive. They do this by fine-tuning the means of communication. For the first time, scientists at the Luxembourg Systemic Biomedicine Center (LCSB) in Berlin and the University of Cambridge, University of Luxembourg, have uncovered the law that cellular signals are converted from the surrounding environment to internal signals. Like an isolated note of an orchestra, an isolated signal of the cell is secondary.
"Importantly, the relative change in the intensity and frequency of the signal delivered from the cell membrane to the cell," said Alexander Skupin, MD, Ph.D., a study lead author of the study in the journal Science Signaling.
By vibrating the air, an orchestra's instrument produces a signal-note. Within the cell, calcium is responsible for carrying the signal. When a piece of information from the environment - such as a bio-messenger - meets the outer membrane of a cell, intracellular calcium is released. There, calcium ions control various adaptation processes. "At first glance, there is no simple model of ion impulses," Skupin explains; "but they still culminate in a meaningful reaction in the cell, much like the activation of a particular gene."
To determine the underlying law of this phenomenon, researchers used both imaging techniques and mathematical methods to study human kidney cells and rat hepatocytes. They found that the intensity and frequency of calcium impulses underwent extreme changes-both in the cell-interior and cell-cell. Therefore, the information they convey can not be interpreted individually by isolated signals. "It's like in an orchestra where studying isolated or isolated notes does not allow any melody to result," Skupin continues the metaphor of music. "You have to hear how the frequency and volume of all the instruments change, and the melodies." Then you get the impression of a piece of music. "

Now, for the first time, researchers have been able to get such an impression by listening to the exchange of cells. They found that too many changes in calcium impulses lead to one another relative to a particular relationship: external stimuli do not lead to an absolute increase in calcium impulses, but instead the frequency at which they occur has changed - in concert halls, symphonic The notes in the instrument will rise and fall. "This pattern is the actual signal that leads to cellular responses," Skupin said. "Our analysis has provided an explanation for this."
"These results are important for disease analysis," said Rudy Bahrain, director of LCSB. "We know that in Parkinson's disease the balance of calcium in nerve cells is broken and it is suspected that miscommunication between cells may play a role in the pathogenesis of neurodegenerative diseases.With the discovery of the basics of these communications, Alexander Skupin, his team and our partners have now come true and we are taking an important step in the analysis of Parkinson's disease. "
Researchers at the University of California San Diego School of Medicine say a protein essential for the process of regulating the cell cycle (the process of cell division and replication) actually activates a key tumor suppressor rather than, as previously thought, It is inactivated.
"This finding is the result of two decades of my laboratory's research," said Dr. Steven F. Dodi, a professor of cellular and molecular medicine at the University of California San Diego School of Medicine. "It's a compley traditional understanding of antigen-antibody, a fundamental aspect of what is known as the p16-cyclin D pathway, the most common genetic pathway mutation in cancer, that promotes the cell cycle progression of all tumor cells." The study Results published in the "eLife" magazine.
Cyclin D, which is synthesized during the first phase of cell replication, is thought to contribute to the promotion of a complex, multi-stage process including the interaction with retinoblastoma (Rb) proteins whose function is Prevent cell overgrowth by inhibiting cell cycle progression until the cell is ready for division. RB is a tumor suppressor gene.