Manufacturing challenges 制造挑戰Ensuring product quality 確保產品質量Biologics are susceptible to physical and chemical degradation. Even slight temperature fluctuations can lead to protein denaturation or aggregation, reducing efficacy. Freeze-thaw cycles of biologics in large-volume formats are often required for their storage and transport; however this process can compromise product integrity. To mitigate these risks, manufacturers must rely on validated processes and advanced monitoring systems that maintain consistent conditions throughout the freezing and thawing process.
生物制劑易受物理和化學因素的影響而降解。即使是輕微的溫度波動也可能導致蛋白質變性或聚集,從而降低療效。大體積生物制劑的儲存和運輸通常需要反復凍融;然而,這一過程可能會損害產品的完整性。為了降低這些風險,生產商必須依賴經過驗證的工藝和監控系統,以確保在整個凍融過程中保持條件的一致性。
Selecting primary packaging 選擇初級包裝Single-use containers, primarily bags or bottles, are the most common types of containers used to transport and store biologics, but each type of container has its own limitations. Bags offer flexibility and facilitate aseptically closed systems. However, they are prone to damage due to mechanical stress and can break if not adequately protected when in a frozen state. Rigid containers also tend to be bulky, which means they take a long time to freeze and thaw. This can compromise product quality. Bottles provide better structural integrity but can limit scalability and require specialized handling equipment. The choice of primary packaging used during freezing often determines the subsequent cold chain management technologies employed. This is because not all cold chain management solutions are compatible with all types of primary packaging.
一次性容器,主要是瓶子或袋子,是運輸和儲存生物制劑容器類型,但每種容器都有其自身的局限性。袋子容器具有靈活性,便于建立無菌封閉系統。然而,它們容易因機械應力而損壞,如果在冷凍狀態下保護不當,則可能破裂。硬質容器通常體積較大,這意味著它們需要較長的凍融時間。這可能會影響產品質量。瓶裝容器具有更好的結構完整性,但會限制其規模化生產,并且需要專門的操作設備。冷凍過程中使用的初級包裝的選擇通常決定了后續冷鏈管理技術的應用。這是因為并非所有冷鏈管理解決方案都與所有類型的初級包裝兼容。
Incompatible processes 不兼容的工藝The use of single-use bags can constrain process flexibility because of equipment incompatibilities and vendor lock-in. Therefore, scalable biopharmaceutical manufacturing solutions must support variable batch volumes while minimizing the need for substantial facility reconfiguration. Bag-independent and modular solutions are thus increasingly popular. Combining modular systems with automation can streamline workflows, reduce the need for manual intervention, and minimize contamination risks, as recommended in EU GMP Annex 1. Ultimately, an end-to-end process that is compatible with every step of cold chain management – from filling and freezing to storage and thawing – ensures a smooth transition, while also facilitating compliance with relevant quality control standards, such as EU GMP Annex 1.
由于設備不兼容和供應商鎖定,使用一次性袋子會限制工藝的靈活性。因此,可擴展的生物制藥生產解決方案必須支持不同批次量,同時減少對設施進行大規模重新配置的需求。因此,獨立于袋子的模塊化解決方案越來越受歡迎。將模塊化系統與自動化相結合可以簡化工作流程,減少人工干預,并降低污染風險,正如歐盟GMP附錄1所建議的那樣。最終,一個與冷鏈管理的每個步驟(從灌裝和冷凍到儲存和解凍)都兼容的端到端流程,可以確保平穩過渡,同時也有助于符合相關的質量控制標準,例如歐盟GMP附錄1。
Sustainable processes 可持續過程Cold chain operations are energy intensive, driven largely by the power requirements of freezers and temperature-controlled storage units. Optimizing freezing profiles and investing in energy-efficient equipment can help reduce the environmental impact of these operations. The use of fluorinated gases, also known as F-gases, is gradually being phased out, with the European Union setting a goal for a complete phase-out by 2050.
3 They are being replaced by natural gases and air-cooled technologies with much lower global warming potential (GWP) than F-gases.
冷鏈操作是能源密集型的,這主要是由于冷凍機和溫控存儲單元的電力需求造成的。優化冷凍工藝流程并投資節能設備有助于減少這些作業對環境的影響。含氟氣體(也稱氟化氣體)的使用正在逐步淘汰,歐盟的目標是在2050年前淘汰。3取而代之的是天然氣和空氣冷卻技術,這些技術的變暖潛值(GWP)遠低于氟化氣體。
Figure 2: Reductions in product quality during cold chain management processes are a major concern for biopharmaceutical manufacturers
圖 2:冷鏈管理過程中產品質量下降是生物制藥生產商關注的主要問題。
The behavior of biologics during freezing生物制品在冷凍過程中的行為When biologics are frozen, several important changes occur that can influence their stability and efficacy. A thorough understanding of these behaviors is essential for preserving long-term product quality and efficacy.
生物制劑冷凍保存期間會發生一些重要變化,這些變化會影響其穩定性和療效。深入了解這些變化對于保持產品的長期質量和療效至關重要。
What happens when freezing biologics? 生物制劑冷凍后會發生什么?Proteins are thermally unstable molecules, and their native structure depends on a delicate balance of interactions within the protein itself and between the protein and surrounding components, such as solvents. When a protein solution is frozen, the temperature of the solution initially decreases steadily as the heat is removed. As the temperature continues to decrease, the solution can become super-cooled, which means that it drops below its normal freezing point without immediately forming ice. However, at a certain temperature, ice begins to form; this is known as
ice nucleation. Once ice starts to form, the temperature briefly stabilizes because energy is being used to change the liquid protein solution into solid ice, not to lower the temperature further. This stage is known as the
phase transition. After most of the liquid has turned to ice, the temperature begins to decrease again as more heat is removed, and the solution becomes completely solid.
蛋白質是熱穩定性較差的分子,其天然結構依賴于蛋白質內部以及蛋白質與周圍成分(例如溶劑)之間相互作用的微妙平衡。當蛋白質溶液被冷凍時,隨著熱量的移除,溶液的溫度最初會穩定下降。隨著溫度持續下降,溶液會變得過冷,這意味著它的溫度會降至正常冰點以下,但不會立即形成冰。然而,在達到一定溫度后,冰開始形成;這被稱為冰核形成。一旦冰開始形成,溫度會短暫穩定下來,因為能量被用于將液態蛋白質溶液轉化為固態冰,而不是用于進一步降低溫度。這個階段被稱為相變。當大部分液體轉化為冰后,隨著更多熱量的移除,溫度再次開始下降,溶液最終凝固。
Figure 3: The behavior of biologics during the freezing process 圖 3:生物制品在冷凍過程中的行為
Figure 4: Ice crystallization at each step in the freezing process
What physical changes impact protein stability during freezing?冷凍過程中哪些物理變化會影響蛋白質的穩定性?Freezing and thawing can alter how proteins interact with their environment, which in turn can reduce their stability. One of the most important effects is cryoconcentration.
4,5 When pharmaceutical products are frozen in large batches, ice forms as the temperature decreases; this removes water that normally hydrates and stabilizes proteins. As a result, proteins and other formulation components become concentrated in the remaining unfrozen solution. The loss of protective water and the increased concentration of other ingredients can destabilize proteins, leading to aggregation, partial unfolding, or unwanted interactions with formulation components or container surfaces.
凍融過程會改變蛋白質與其環境的相互作用方式,進而降低其穩定性。其中最重要的影響之一是冷凍濃縮。當藥品批量冷凍時,隨著溫度降低會形成冰;冰會帶走通常用于水合和穩定蛋白質的水分。因此,蛋白質和其他制劑成分會在剩余的未凍結溶液中濃縮。保護性水分的損失和其他成分濃度的增加會導致蛋白質不穩定,進而引起聚集、部分展開或與制劑成分或容器表面發生不必要的相互作用。
Cryoconcentration can introduce several additional destabilizing effects. As freezing progresses, the solution becomes more viscous, and the rates of freezing and thawing influence how long these altered conditions persist. Ice formation can also trap small air bubbles, which may further disrupt protein structure and reduce stability. Another key factor is the formation of ice-liquid interfaces.
5 Proteins that adsorb to these interfaces can undergo structural changes or denaturation; therefore, control of the cooling rate is critical. More rapid freezing generally produces smaller ice crystal s and results in a larger ice-liquid interface. This can help limit the unwanted crystallization of buffering components and support maintenance of solution pH.
冷凍濃縮還會引入其他幾種不穩定因素。隨著冷凍的進行,溶液粘度會增加,而凍融速率會影響這些改變狀態的持續時間。冰的形成還會捕獲微小的氣泡,這可能會進一步破壞蛋白質結構并降低其穩定性。另一個關鍵因素是冰-液界面的形成。吸附在這些界面上的蛋白質可能會發生結構變化或變性;因此,控制冷卻速率至關重要。快速冷凍通常會產生更小的冰晶,并形成更大的冰液界面。這有助于限制緩沖成分的非預期結晶,并有助于維持溶液的pH值。
What does this mean when freezing biologics during manufacturing?在生產過程中冷凍生物制劑意味著什么?Ultimately, freezing is not just a matter of lowering the temperature. For example, fast freezing is optimal for most proteins, such as monoclonal antibodies, whereas slower freezing rates are preferable for other proteins.
6歸根結底,冷凍不僅僅是降低溫度的問題。例如,快速冷凍對大多數蛋白質(如單克隆抗體)來說是好選擇,而較慢的冷凍速率則更適合其他蛋白質。
Precise control over process parameters is required to minimize destabilizing effects and preserve the integrity of biologics. Manufacturers must account for these physical changes and their impact on protein stability to ensure consistent product quality and reliable handling of bulk drug substances.
精確控制工藝參數對于減少不穩定因素并保持生物制劑的完整性至關重要。生產商必須考慮這些物理變化及其對蛋白質穩定性的影響,以確保產品質量的一致性和原料藥處理的可靠性。
Figure 5: RoSS® shel l is a protective secondary packaging for all two-dimensional single-use bags currently on the market
圖 5:RoSS® shell 是一種適用于目前市面上所有一次性2D袋子的保護性二級包裝。
Best practice: Controlled freezing of biologicsThe freezing process has profound implications for the stability of protein-based biologics. Cryoconcentration and the formation of ice-liquid interfaces can lead to the loss of protein structure and function if not properly controlled. The extent of these effects depends on a variety of factors, including:
冷凍過程對蛋白質生物制劑的穩定性有著深遠的影響。如果控制不當,冷凍濃縮和冰液界面的形成會導致蛋白質結構和功能的喪失。這些影響的程度取決于多種因素,包括:
Therefore, effective management of these physical changes requires controlled freezing strategies for different container types, such as single-use bags and bottles, and for a range of processing volumes.
因此,要有效管理這些物理變化,需要針對不同類型的容器(如一次性袋子和瓶子)以及不同的加工量制定受控的冷凍策略。
Freezing biologics in single-use bags 將生物制劑冷凍于一次性袋子中2D bioprocess containers that have a small water column can be frozen using plate-freezing technology, which enables more rapid, controlled freezing than traditional static freezing. When employing plate-freezing technology with single-use bags, the bags should be placed in specialized secondary packaging designed to ensure optimal heat transfer. Rapid, controlled freezing using plate freezers enables simultaneous freezing of the drug substance in single-use bags from both the top and the bottom. This helps prevent cryoconcentration of the drug substances and other formulation components in the center of the bag. Both conductive cooling, which provides direct contact with the cooling medium as in plate freezers, and convective cooling, which uses an airflow-based technology as in blast freezers, achieve faster and more homogeneous freezing than static freezers. Figure 6 illustrates the difference in freezing results between static freezers and plate freezers. The degree of cryoconcentration in a single-use bag compared to the initial liquid-state concentration when frozen in a static freezer is significantly higher than that observed when plate-freezing is used. A study conducted in collaboration with Zurich University of Applied Sciences measured cryoconcentration levels of up to +212 % after freezing in a static freezer, whereas cryoconcentration levels using plate freezers showed no major changes.
7對于含有少量水柱的二維生物工藝容器,可采用平板冷凍技術進行冷凍,該技術比傳統的靜態冷凍技術能夠實現更快速、更可控的冷凍。當使用平板冷凍技術處理一次性袋子時,應將袋子置于專門設計的二級包裝中,以確保最佳的熱傳遞。平板冷凍機能夠從頂部和底部同時冷凍一次性袋子中的藥物,從而實現快速、可控的冷凍。這有助于防止藥物和其他制劑成分在袋子中心發生冷凍濃縮。無論是傳導冷卻(如平板冷凍機中與冷卻介質直接接觸)還是對流冷卻(如速凍機中利用氣流技術),都能比靜態冷凍機實現更快、更均勻的冷凍。圖 6 展示了靜態冷凍機和平板冷凍機冷凍結果的差異。與靜態冷凍機相比,使用平板冷凍技術冷凍的一次性袋子中的冷凍濃縮程度明顯更高。與蘇黎世應用科學大學合作進行的一項研究測量了靜態冷凍機冷凍后的冷凍濃縮水平高達 +212 %,而使用平板冷凍機的冷凍濃縮水平則沒有出現重大變化。
Figure 6: Visualized cryoconcentration of uncontrolled conventional freezing (top) vs controlled plate-freezing (bottom)
圖 6:非受控常規冷凍(上圖)與受控平板冷凍(下圖)的冷凍濃縮可視化圖
Dark blue spots indicate greater cryoconcentration. Rapid and controlled freezing with a plate freezer enables more homogeneous freezing than conventional freezing.
深藍色斑點表示冷凍濃縮程度更高。與傳統冷凍方法相比,使用平板冷凍機進行快速可控冷凍能夠實現更均勻的冷凍效果。
As noted earlier, small air bubbles can occur during the cooling process, which can further affect proteins and reduce their stability. Stress at the liquid-ice interface during the formation of ice can also destabilize proteins.8 So how can these effects be prevented to achieve a homogeneous freezing result? Single Use Support has performed computed tomography (CT) scans to visualize when these phenomena occur to identify ways in which they can be avoided. In Figure 7, an uneven freezing result following static freezing is clearly visible. Bubbles and cracks at the final point of solidification are visible, indicating cryoconcentration.
如前所述,冷卻過程中可能會產生微小氣泡,這會進一步影響蛋白質并降低其穩定性。冰形成過程中液態-冰界面處的應力也會破壞蛋白質的穩定性。8 那么,如何避免這些影響以獲得均勻的冷凍效果呢?Single Use Support 公司進行了計算機斷層掃描 (CT),以觀察這些現象發生的時間,并找出避免它們的方法。圖 7 清晰地顯示了靜態冷凍后冷凍效果不均勻的情況。在最終凝固點處可以看到氣泡和裂紋,表明存在低溫濃縮現象。
Figure 7: CT scan cross-sectional views (horizontal and vertical) of a single-use bag frozen in a static freezer show uneven freezing, with bubbles and cracks concentrated at the final point of solidification
圖 7:在靜態冰箱中冷凍的一次性袋子的 CT 掃描橫截面視圖(水平和垂直)顯示冷凍不均勻,氣泡和裂紋集中在最終凝固點。
Figure 8: CT scan cross-sectional views (horizontal and vertical) of a single-use bag frozen using a plate freezer show homogeneous ice fronts with no bubbles or cracks
圖 8:使用平板冷凍機冷凍的一次性袋子的 CT 掃描橫截面視圖(水平和垂直)顯示均勻的冰層前沿,沒有氣泡或裂紋。
In contrast, Figure 8 shows homogeneous freezing, achieved by following freezing protocols to obtain optimal freezing rates and gradients, using Single Use Support’s plate freezer, RoSS. pFTU. This fully automated, protocol-driven approach not only aligns with US Food and Drug Administration 21 CFR Part 11 standards for electronic records and delivers consistent results across a variety of scales but also maximizes product integrity. The controlled-rate plate freezer RoSS.pFTU, used in combination with Single Use Support’s protective secondary packaging RoSS
® shell, can achieve maximum product quality during the freezing of biologics.
相比之下,圖8展示了使用Single Use Support公司的 RoSS.pFTU平板冷凍機,通過遵循冷凍方案獲得冷凍速率和梯度,從而實現均勻冷凍。這種全自動、配方驅動的方法不僅符合 (FDA) 21 CFR Part 11 的電子記錄標準,并且在各種規模下都能提供一致的結果,而且還能保證產品的完整性。RoSS.pFTU 可控速率平板冷凍機與 Single Use Support 公司的 RoSS
® 保護性二級包裝外殼配合使用,可在生物制品冷凍過程中實現產品質量。
The RoSS® shell offers robust, reliable, and secure protection for single-use bioprocess containers of any size and vendor during freezing, transportation, storage, and thawing.
RoSS® 外殼為任何尺寸和供應商的一次性生物工藝容器在冷凍、運輸、儲存和解凍過程中提供強大、可靠和安全的保護。
With its innovative design, the RoSS
® shell is a tamper-evident system that minimizes contamination risk and ensures all single-use bags are efficiently cooled using plate freezing technology while providing protection during storage and shipping. This:
憑借其創新設計,RoSS® 外殼是一個防篡改系統,可降低污染風險,并確保所有一次性袋子均能使用平板冷凍技術進行高效冷卻,同時在儲存和運輸過程中提供保護。
Minimizes product losses attributable to bag breakages
減少因袋子破損造成的產品損失
Maximizes product quality by providing optimal freezing and thawing conditions
通過提供冷凍和解凍條件,提高產品質量
Is compatible with all types of two-dimensional (2D) single-use bags
兼容所有類型的二維(2D)一次性袋子
Single-use bags secured within the robust RoSS
® shell can be placed into the
RoSS.pFTU plate-based freezer, which:
一次性袋子固定在堅固的 RoSS® 外殼內,可放入 RoSS.pFTU 平板式冷凍機中,該冷凍機:
Enables controlled freezing down to -80 °C with the highest possible speed and accuracy
能夠以高速度和精度實現低至-80°C的受控冷凍
Offers a capacity of up to 400 L, depending on bag type
容量高達400升,具體取決于袋子類型
Is fully compatible with 2D single-use bags of any size and from any vendor
兼容任何尺寸、任何供應商的二維一次性袋子
Can achieve optimal product stability results for bulk drug substances, including monoclonal antibodies
可實現原料藥(包括單克隆抗體)的產品穩定性
Is fully automated and ready for cGMP use
全自動運行,符合cGMP要求
Figure 9: Fully loaded RoSS.pFTU Large Scale
圖 9:滿載的 RoSS.pFTU 大規模
Freezing biologics in bottles 將生物制劑冷凍于瓶中Unlike single-use bags, bottles present unique challenges when used to freeze biologics; this is due to their bulk and their requirement for vertical placement during freezing. It is therefore recommended to freeze bottles using static or blast freezing methods.
與一次性袋子不同,瓶子在冷凍生物制劑時面臨著獨特的挑戰;這是由于瓶子體積較大,且冷凍過程中需要垂直放置。因此,建議采用靜態冷凍或速凍方法冷凍瓶子。
However, uncontrolled freezing in bottles often leads to uneven temperature gradients and cryoconcentration, compromising product quality. Blast freezing, particularly with forced air flow, is superior to static freezing methods but still requires careful control.
然而,瓶內冷凍若不受控制,往往會導致溫度梯度不均勻和濃縮,從而影響產品質量。速凍,特別是采用強制氣流的速凍,優于靜態冷凍方法,但仍需嚴格控制。
Studies have shown that uncontrolled freezing can result in considerable differences in solute concentration between the top and bottom of a bottle, indicating heterogeneous freezing and reduced reproducibility, with cryoconcentration levels increasing by more than 300 %.
9研究表明,冷凍若不受控制,會導致瓶內頂部和底部溶質濃度出現顯著差異,表明冷凍不均勻,重復性降低,濃縮程度增加超過300%。
As a bottle is subjected to the freezing process, pressure on the side walls from the growing ice fronts pushes liquid toward the center, forming a cone at the top. This phenomenon is known as the “volcano effect", illustrated in Figure 10.
當瓶子處于冷凍過程中時,不斷增長的冰鋒對瓶壁施加壓力,將液體推向中心,在頂部形成錐形。這種現象被稱為“火山效應",如圖10所示。
Figure 10: Visualized cryoconcentration in bottles under uncontrolled freezing conditions showing the “volcano effect" (left) compared with controlled blast freezing (right)
圖 10:在不受控制的冷凍條件下,瓶中低溫濃縮的可視化結果,顯示了“火山效應"(左圖),并與受控的速凍(右圖)進行了比較。
To address these issues, Single Use Support has developed controlled-rate freezing protocols for bottles. For large bottles, freezing rates of approximately -0.1 °C to -0.5 °C/min are essential for maintaining protein stability.4,10 Controlled air distribution with advanced air flow systems optimizes the freezing behavior of drug substances to ensure bottle-to-bottle reproducibility and homogeneous freezing results. Visualization of heat transfer and airflow patterns demonstrates that high-performance forced air distribution enables consistent temperature control and uniform freezing. Single Use Support’s
RoSS.BLST is a blast freezer that controls the rate of cooling by employing smart air distribution, as shown in Figure 11. It is a modular, controlled-rate blast freezer that incorporates forced-air technology. Its best-in-class chamber size-to-foot-print ratio enables manufacturers to efficiently freeze bulk-packaged biologics. It can accommodate bottles, bulky single-use bag setups, and other single-use containers. For example, it can accommodate up to 192 2 L bottles and can freeze drug substances according to optimal freezing protocols to achieve maximum product stability. It also contributes to efficient and sustainable freezing by providing great process flexibility:
為了解決這些問題,Single Use Support 開發了適用于瓶裝產品的控溫速凍方案。對于大瓶裝產品,約 -0.1℃ 至 -0.5 °C/min 的速凍速率對于維持蛋白質穩定性至關重要
4,10。采用氣流系統的可控空氣分配能夠優化藥物的冷凍行為,確保瓶與瓶之間冷凍效果的可重復性和均勻性。熱傳遞和氣流模式的可視化結果表明,高性能強制空氣分配能夠實現穩定的溫度控制和均勻的冷凍效果。如圖 11 所示,Single Use Support 的 RoSS.BLST 是一款采用智能空氣分配控制冷卻速率的速凍機。它是一款模塊化、控溫速凍機,并采用了強制空氣技術。其腔室尺寸與占地面積比使生產商能夠高效地冷凍散裝生物制劑。它可以容納瓶裝產品、體積較大的一次性袋子以及其他一次性容器。例如,它最多可容納 192 瓶 2 升裝藥品,并可根據冷凍方案冷凍藥品,以實現產品穩定性。此外,它還具有高的工藝靈活性,有助于實現高效且可持續的冷凍:
Modular shelving for bottle sizes ranging from 30 mL to 10 L
模塊化貨架,適用于30毫升至10升的瓶裝飲料
Sustainable design with natural refrigerants and a low refrigerant load
采用可持續設計,使用天然制冷劑,制冷劑負荷低
Complies with EN 378 and ISO 5149 standards
符合EN 378和ISO 5149標準
Includes thawing functionality with integrated shaking
內置搖晃功能,可解凍飲料
Figure 11: Visualization of heat transfer and airflow patterns when using RoSS.BLST for temperature control , showing the high-performance forced air distribution when used with single-use bottles (top) and bags (bottom)
圖 11:使用 RoSS.BLST 進行溫度控制時的熱傳遞和氣流模式可視化,顯示了與一次性瓶子(上圖)和袋子(下圖)一起使用時的高性能強制空氣分配。
Bottle RoSS protects bottle caps with attached tubing assemblies. It provides tamper-evident integrity and reduces product losses during cold chain storage and shipping. Therefore, Bottle RoSS ensures the safe, efficient, and scalable management of biologics in bottles, regardless of bottle manufacturer or type.
Bottle RoSS 通過連接的管路組件保護瓶蓋。它提供防篡改保護,并減少冷鏈儲存和運輸過程中的產品損失。因此,無論瓶子制造商或類型如何,Bottle RoSS 都能確保對瓶裝生物制劑進行安全、高效且可擴展的管理。
Figure 12: A RoSS.BLST fully loaded with 2 L bottles 圖 12:裝滿 2 升瓶子的 RoSS.BLST
Figure 13: Bottle RoSS for protection of single-use assemblies on bottles during cold chain handling
圖 13:瓶身 RoSS,用于在冷鏈搬運過程中保護瓶子上的一次性組件。
Maintaining cold chain for storage and transport維持冷鏈以進行儲存和運輸The efficient and safe freezing of biologics in single-use bags and bottles requires a fully closed, Annex 1-aligned, and aseptic system during the entire fluid and cold chain management process. The process begins with automated filling and filtration, continues through freezing, cold storage and shipping, and concludes with controlled thawing at the drug product site, until the drug substance is removed from the singleuse containers for fill/finish. The integration of closed systems at every stage minimizes contamination risks, streamlines workflows, and ensures product integrity. This end-toend strategy fosters compatibility between single-use technologies, regardless of the type or size of primary packaging used by the manufacturer. Furthermore, closed systems fulfill GMP-relevant standards, and can be seamlessly integrated into customer networks for process control. An automated and compatible cold chain improves operational efficiency, making it the gold standard for the management of single-use containers used in biopharmaceutical manufacturing, such as single-use bags and bottles.
生物制劑在一次性袋子和瓶中的高效安全冷凍,需要在整個液體和冷鏈管理過程中采用封閉、符合附件1要求且無菌的系統。該流程始于自動化灌裝和過濾,貫穿冷凍、冷藏和運輸,最終在藥品生產現場進行受控解凍,直至將原料藥從一次性容器中取出進行灌裝/包裝。在每個階段集成封閉系統可限度地降低污染風險,簡化工作流程,并確保產品完整性。這種端到端策略促進了各種一次性技術之間的兼容性,無論制造商使用何種類型或尺寸的初級包裝。此外,封閉系統符合GMP相關標準,并且可以無縫集成到客戶網絡中進行過程控制。自動化且兼容的冷鏈提高了運營效率,使其成為生物制藥生產中一次性容器(例如一次性袋子和瓶)管理的黃金標準。
Cold storage of biologics 生物制劑的冷藏For ultra-low temperature storage, the
RoSS.ULTF platform provides secure, scalable cold storage down to -80 °C. The modul ar interior can accommodate either single-use bags protected in RoSS® shells or single-use bottles and their assemblies protected with Bottle RoSS, as well as other bulk-packaged drug substances of various sizes and batch volumes. This design ensures compatibility with all container types and safety for high-value drug substances. Automated monitoring and GMP-compatible documentation support regulatory requirements and batch traceability.
RoSS.ULTF平臺專為超低溫儲存而設計,可提供安全、可擴展的冷藏環境,溫度可達-80°C。其模塊化內部結構可容納RoSS®外殼保護的一次性袋子、RoSS®瓶裝保護的一次性藥瓶及其組件,以及其他各種規格和批次的散裝藥品。該設計確保與所有容器類型兼容,并保障高價值藥品的安全性。自動化監控和符合GMP規范的文檔記錄功能可滿足監管要求和批次追溯性。
Cold chain shipping container 冷鏈運輸集裝箱Maintaining cold chain is critical when transporting bulk drug substances. The
RoSS.SHIP solution enables safe, temperature-controlled shipping of bottles and bags. This container is specifically designed to maintain cold chain, ensuring that bulk drug substances remain at temperatures below -60°C for several days during transport. Integrated track and trace technology enables real-time monitoring of temperature and location, providing full visibility and compliance throughout transit. RoSS.SHIP’s robust packaging minimizes the risk of breakage, contamination, and product loss, ensuring that biologics arrive at their destination in optimal condition.
在運輸原料藥時,維持冷鏈至關重要。RoSS.SHIP解決方案可實現瓶裝和袋裝原料藥的安全溫控運輸。該容器專為維持冷鏈而設計,確保原料藥在運輸過程中數日內保持在-60°C以下的溫度。集成的追蹤溯源技術可實時監控溫度和位置,從而在整個運輸過程中提供全面的可視性和合規性。RoSS.SHIP堅固的包裝限度地降低了破損、污染和產品損失的風險,確保生物制劑以好狀態抵達目的地。
Figure 14: Ultra-cold storage of biologics with RoSS.ULTF
圖 14:采用 RoSS.ULTF 進行生物制劑的超低溫儲存
Figure 15: The cold chain shipping container RoSS.SHIP
圖 15:冷鏈運輸集裝箱 RoSS.SHIP
Thawing biologics at the drug product site 在藥品生產現場解凍生物制劑 
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