Lyophilization Process Design and Development: A Single-Step Drying Approach

High-throughput lyophilization process was designed and developed for protein formulations using a single-step drying approach at a shelf temperature (T_s) of ≥40°C. Model proteins were evaluated at different protein concentrations in amorphous-only and amorphous-crystalline formulations. Single-step drying resulted in product temperature (T_p) above the collapse temperature (T_c) and a significant reduction (of at least 40%) in process time compared to the control cycle (wherein T_p < T_c). For the amorphous-only formulation at a protein concentration of ≤25 mg/mL, single-step drying resulted in product shrinkage and partial collapse, whereas a 50 mg/mL concentration showed minor product shrinkage. The presence of a crystallizing bulking agent improved product appearance at ≤25 mg/mL protein concentration for single-step drying. No impact to other product quality attributes was observed for single-step drying. Vial type, fill height, and scale-up considerations (i.e., choked flow, condenser capacity, lyophilizer design and geometry) were the important factors identified for successful implementation of single-step drying. Although single-step drying showed significant reduction in the edge vial effect, the scale-up considerations need to be addressed critically. Finally, the single-step drying approach can indeed make the lyophilization process high throughput compared to traditional freeze-drying process (i.e., 2-step drying).     

Push-and-pull regulation of the fusion pore by synaptotagmin-7

In chromaffin cells, Ca(2+) binding to synaptotagmin-1 and -7 triggers exocytosis by promoting fusion pore opening and fusion pore expansion. Synaptotagmins contain two C2 domains that both bind Ca(2+) and contribute to exocytosis; however, it remains unknown whether the C2 domains act similarly or differentially to promote opening and expansion of fusion pores. Here, we use patch amperometry measurements in WT and synaptotagmin-7-mutant chromaffin cells to analyze the role of Ca(2+) binding to the two synaptotagmin-7 C2 domains in exocytosis. We show that, surprisingly, Ca(2+) binding to the C2A domain suffices to trigger fusion pore opening but that the resulting fusion pores are unstable and collapse, causing a dramatic increase in kiss-and-run fusion events. Thus, synaptotagmin-7 controls fusion pore dynamics during exocytosis via a push-and-pull mechanism in which Ca(2+) binding to both C2 domains promotes fusion pore opening, but the C2B domain is selectively essential for continuous expansion of an otherwise unstable fusion pore.     

Intramolecular phenotypic capacitance in a modular RNA molecule

Phenotypic capacitance refers to the ability of a genome to accumulate mutations that are conditionally hidden and only reveal phenotype-altering effects after certain environmental or genetic changes. Capacitance has important implications for the evolution of novel forms and functions, but experimentally studied mechanisms behind capacitance are mostly limited to complex, multicomponent systems often involving several interacting protein molecules. Here we demonstrate phenotypic capacitance within a much simpler system, an individual RNA molecule with catalytic activity (ribozyme). This naturally occurring RNA molecule has a modular structure, where a scaffold module acts as an intramolecular chaperone that facilitates folding of a second catalytic module. Previous studies have shown that the scaffold module is not absolutely required for activity, but dramatically decreases the concentration of magnesium ions required for the formation of an active site. Here, we use an experimental perturbation of magnesium ion concentration that disrupts the folding of certain genetic variants of this ribozyme and use in vitro selection followed by deep sequencing to identify genotypes with altered phenotypes (catalytic activity). We identify multiple conditional mutations that alter the wild-type ribozyme phenotype under a stressful environmental condition of low magnesium ion concentration, but preserve the phenotype under more relaxed conditions. This conditional buffering is confined to the scaffold module, but controls the catalytic phenotype, demonstrating how modularity can enable phenotypic capacitance within a single macromolecule. RNA’s ancient role in life suggests that phenotypic capacitance may have influenced evolution since life’s origins.Phenotypic capacitance requires mutations that reversibly alternate between hidden and revealed states in response to environmental or genetic perturbations (1, 2). In the hidden or “cryptic” state the mutations can survive selection because they do not change the phenotype, and multiple such mutations can accumulate within individual genomes in a population. Perturbation after such accumulation can reveal the combined effects of multiple mutations. By exposing the phenotypic effects of mutations that may not have been beneficial individually, capacitance provides a mechanism of generating new phenotypes—from macromolecules to morphological traits—with novel functions (1–4). The term “phenotypic capacitance” is appropriate for situations where altered phenotypes with a genetic basis can be hidden and revealed, even when no adaptive potential of the revealed phenotypes is demonstrated (2). “Evolutionary capacitance,” on the other hand, is a term reserved for instances when an adaptive role is demonstrated. Phenotypic capacitance has been known in fruit flies since the 1950s (5), but demonstrations of adaptive potential (4, 6), and the various molecular mechanisms behind it (7–11) have been reported only relatively recently.A module in a biological system is a group of system parts that interact more with each other than with parts outside of the module (12). In RNA molecules, the parts are nucleotides, and modules are units of tertiary structure that fold independently, and often perform different functions, such as binding to different proteins, RNAs, or small molecules. Modularity has been described in the telomerase RNA component (13), ribosomal RNA (14), long noncoding RNA (e.g., Xist, Hotair) (15), riboswitches (16), and self-splicing introns (17, 18). A link between modularity and phenotypic capacitance could provide a mechanism for the evolution of novel functions involving modules of RNA structure, and especially for functional innovations that require multiple simultaneous mutations. It is not known how modularity might change the potential to hide and reveal the effects of mutations in RNA structures, which is a prerequisite for phenotypic capacitance.To investigate a possible link between modularity and phenotypic capacitance in RNA, we chose to study the Azoarcus group I RNA enzyme (ribozyme). Group I ribozymes such as this have two structural modules that are functionally distinct (Fig. 1). The first of them is a scaffold module (Fig. 1, yellow) that folds rapidly, and forms a nearly identical structure even when removed from the context of the rest of the ribozyme (19, 20). The scaffolding it provides facilitates the folding of the less thermodynamically stable catalytic module (Fig. 1, blue) (21). Biochemical studies have shown that the catalytic phenotype (protein-free splicing) resides in the catalytic module, which can maintain activity if the scaffold module is deleted, but only under conditions of very high magnesium (80 mM) and extended incubation times (16 h) (22). This instability caused by deleting the scaffold supports the idea that this module acts as an intramolecular chaperone.Open in a separate windowFig. 1.The modular structure of the Azoarcus group I ribozyme. (A) The scaffold module (yellow) and the catalytic module (blue) are shown in the context of the ribozyme secondary structure. The regions that show base pairing (P) are numbered sequentially from the 5′ to the 3′ end, according to group I intron standards. The substrate for the ribozyme is written in lowercase letters. The modules are also shown in the context of the 3D crystal structure (PDB ID: 1ZZN), from a “top view” (B) and “side view” (C), with respect to the scaffold module.The diversification of RNA functions has played an important role in the evolution of extant organisms, and may have been even more important at life’s beginnings when RNA enzymes (ribozymes) played a central role as catalysts in the RNA world scenario (23). In a previous publication using the Azoarcus ribozyme, we demonstrated an adaptive role for accumulated cryptic variation that was revealed when altered enzymatic activity was required (24). Here, we focus on how the functionally distinct modules of this structure might facilitate the occurrence of environmentally conditional mutations that enable phenotypic capacitance.We aimed to identify mutations that maintain the catalytic phenotype under normal conditions but alter this phenotype under stressful conditions. The ideal stressful condition for our RNA system is a low concentration of magnesium ions. The concentration of magnesium ions inside of cells is maintained at a higher concentration than any other divalent ion due to its role in many cellular functions. Importantly for our current experiments, it is known that magnesium ions are critical for stabilizing the native structure of RNA molecules (25). Low concentrations of magnesium only allow folding of the most stable RNA structures and can lead to misfolding of less stable structures. In addition, many ribozymes, including group I introns, use highly coordinated magnesium ions in their active site (26). Based on previous reports on the magnesium dependence of the Azoarcus ribozyme (19), we here studied a stressful environment with low (2 mM) MgCl₂, a relaxed environment with high (25 mM) MgCl₂, and an intermediate environment (10 mM MgCl₂). We note that magnesium availability is often limited in natural environments, a stressful condition that organisms have evolved adaptive responses to. For example, magnesium homeostasis in bacteria is maintained by the expression of ion transporters that are sometimes regulated by cis-acting RNA regulatory elements. These “magnesium riboswitch” elements control downstream mRNA expression by conformational changes induced by altered magnesium concentrations (27). This example and others (28) highlight the widespread importance of our chosen experimental stressor.     

Asymmetric capacitance response from the chemical characteristics of activated carbons in KOH electrolyte

The positive and negative capacitance behaviors of heat-treated activated carbons are separately studied in a three-electrode configuration using 6 M KOH and 1 M H₂SO₄ as electrolytes. Heat treatment of activated carbons at 400–800 °C causes slight changes in surface area accompanied by a significant removal of oxygen-containing functional groups. Consequently, the specific surface capacitance with a 25% reduction in the negative and an 8% reduction in the positive are monitored in KOH electrolyte. The unequal capacitance reductions as well as the asymmetric CV curves reveal that the negative pseudo-capacitances are much larger than the positive ones in KOH electrolyte. These results could be ascribed to the redox reactions preferring in the negative region. The insertion process of cation also plays a significant effect on the asymmetric capacitance behavior. Compared with the identical electrochemical response in H₂SO₄ electrolyte, huge difference in the capacitance values of both electrodes in KOH electrolyte will give a less contribution to the cell capacitance. To optimize the cell performance, a suitably increasing the weigh of active materials in the positive, especially for activated carbon with high level of oxygen-containing functional groups, is recommended.     

频域寄生电容法变频电机Hertz轴承电流密度计算

提出应用频域寄生电容法计算Hertz轴承电流密度。该种方法以电机系统内的寄生电容为研究对象,通过解析法确定其频域特性,结合电机内耦合电容拓扑结构计算轴承电流。本文以一台3kW变频电机为研究对象,通过解析法确定其各部分寄生电容的频域特性,并通过阻抗分析仪对计算结果进行校验。根据变频器电机系统耦合电容模型列写轴承电流线性微分方程,通过一般线性扩展法对其进行求解,求得轴承放电电流。搭建轴承电流测量平台,对轴承电流进行测量,与计算结果基本吻合。最后应用接触力学中的经典Hertz理论求得轴承接触面积,进而计算轴承电流密度。该种轴承电流密度计算方法为定量评估轴承电损伤提供了理论依据。     

不同掺杂酸对纤维聚苯胺电化学性能的影响

采用界面聚合法通过不同质子酸掺杂分别制备了平均直径约为50,62,95 nm的纤维聚苯胺。通过傅里叶变换红外光谱(FT-IR)、扫描电子显微镜(SEM)、透射电镜(TEM)对其化学组成和微观形貌进行了表征,采用循环伏安、恒流充放电和交流阻抗研究了不同质子酸掺杂纤维聚苯胺的超级电容器电容行为,并利用X射线衍射(XRD)、氮气吸脱附及X射线光电子能谱(XPS)等方法对纤维聚苯胺的微观结构进行了深入研究。结果表明：高氯酸(HClO4)掺杂制备的聚苯胺在0.5 A/g电流密度下的比容量可以达到397 F/g,高于盐酸(HCl, 334 F/g)和樟脑磺酸(HCSA, 383 F/g)掺杂聚苯胺的测试结果,纤维的电化学性能主要受其规整度、孔隙率及掺杂度的影响。     

Effects of arginine-vasopression on regional blood volume distribution in supine humans

Summary In healthy humans, the increase in arterial blood pressure seen in patients with autonomic dysfunction in response to exogenous vasopressin (AVP) is abolished. We tested the hypothesis that redistribution of blood from the intra- to the extrathoracic vascular compartment might contribute to this buffer response. Regional distribution of^99mTc labeled autologous red cells was assessed in healthy supine volunteers (n=7) during arginine-vasopressin administration (1 ng·kg^–1 bolus i.v. followed by a 14-min infusion of 3 ng·kg^–1·min^–1), along with arterial and central venous pressures, and heart rate. Exogenous vasopressin increased plasma vasopressin concentration from 4.0±1.4 SEM to 91 pg·ml^–1±12. Thoracic counts increased slightly but significantly by 2.2%±0.9, while global abdominal counts remained unchanged. Most surprisingly, counts in the liver markedly increased (+8.1%±1.8, p=0.02), but significantly decreased in the spleen (–3.1%±1.4). Intestinal (–2.5%±2.4) and limb counts did not change significantly. Consistent with the increase in thoracic counts centralvenous pressure increased from 3.6 mm Hg±1 to 4.7±1 (p=0.02), while arterial pressure and heart rate did not change. All changes reversed towards baseline when vasopressin administration ceased. Thus, in humans with an intact autonomic system, vasopressin, at concentrations observed during hypotension, increases liver and, albeit to a small extent, also thoracic blood volume, but decreases splenic blood content. These results 1) are incompatible with the hypothesis that AVP induces a shift of blood from intra- to extrathoracic capacitance vessels, and 2) show that AVP increases rather than decreases central blood volume.     

Mapping the human face: biophysical properties

Background: Facial skin exhibits unique biophysical properties that are distinct from skin belonging to other areas of the body. Small to large regional differences in biophysical properties between facial sites are observed. Technological advances in dermatological research allow a quantitative study of the biophysical qualities of the face and its relation to skin elsewhere. However, comprehensive studies examining inter‐regional variations using each of the six standard biophysical parameters have been few. We summarize findings on the biophysical parameters used to explore the human face as well as regional differences in skin reactivity to chemical irritants. Methods: We performed a literature search using Pubmed, Embase, Science Citations Index, and the UCSF's dermatological library on biophysical parameters and skin physiology pertaining to the human face. Results: Distinct regional differences in transepidermal water loss (TEWL), capacitance, blood flow, sebum, pH, and temperature were demonstrated in facial skin. However, studies cannot be compared with each other because each uses different anatomical sites, skin conditions, and measurement techniques. Intraregional differences in TEWL, sebum, and temperatures were observed on the cheeks and appeared to follow characteristic distribution patterns. Higher blood flow levels and skin temperatures were generally observed in areas with dense networks of blood vessels such as the nose and perioral region. Areas such as the forehead, nose, and chin consistently showed higher sebum casual levels, but variability in sebum levels between sites was also observed. The susceptibility of the face to hexyl nicotinate, sodium lauryl sulfate, and benzoic acid differed depending on location and age. Conclusion: Establishing a standardized biophysical profile of the human face will help to improve therapeutics, and further our understanding of differences in chemical reactivity and disease distribution. Future research necessitates standardization of the anatomical sites studied, sample size, and experimental protocols.