ライフサイエンスコーパス: manufacturing

1 tive, user-friendly, rapid, and scalable for manufacturing.

2 compaction procedure is adaptive to additive manufacturing.

3 s of these damages originating from chemical manufacturing.

4 that control solidification during additive manufacturing.

5 ngineered biomaterials to control human cell manufacturing.

6 leness, and low-cost production for scalable manufacturing.

7 ion during their discovery, development, and manufacturing.

8 e route for rationally designed, sustainable manufacturing.

9 limited by the high cost of development and manufacturing.

10 per batch, with the potential for continuous manufacturing.

11 etching process easily compatible with batch manufacturing.

12 ides an alternate route for thin-film device manufacturing.

13 e research and development of metal additive manufacturing.

14 s, coatings, and byproducts of semiconductor manufacturing.

15 processing window is favored for industrial manufacturing.

16 the field and discusses challenges in vector manufacturing.

17 linical diagnostics assays, and cell therapy manufacturing.

18 ver, from issues of solubility, which impede manufacturing.

19 dow into fiber technology through low-energy manufacturing.

20 nt roles in chemical synthesis and molecular manufacturing.

21 owed substantial simplifying the transistors manufacturing.

22 tates both rapid development and small-scale manufacturing.

23 sed in chemical, pharmaceutical, and polymer manufacturing.

24 due to the sample constraints of small scale manufacturing.

25 from a sample collection based on worldwide manufacturing.

26 wed by silver production (24%) and chemicals manufacturing (12%).

27 The key step of manufacturing a bioelectrode is the effective enzyme imm

28 ucing complicated tissues is demonstrated by manufacturing a complex hard/soft tissue interface and d

29 These data demonstrate that manufacturing a defined-composition CD19 CAR T cell iden

30 alization of the unit of mass is possible by manufacturing a perfect one-kilogram sphere from a (28)S

31 ose a new precision additive freeform optics manufacturing (AFOM) method using an pulsed infrared (IR

32 Digital manufacturing, all-ceramics, and adhesive dentistry are

33 Additive manufacturing, also referred to as three-dimensional (3D

34 Although manufacturing alterations (n = 834 of 2813; 30%) were th

35 Additive manufacturing (AM) alias 3D printing translates computer

36 recent growth in interest for metal additive manufacturing (AM) in the biomedical and aerospace indus

37 roplet motion associated with metal additive manufacturing (AM) processes are presented.

38 Computer-controlled additive manufacturing (AM) processes, also known as three-dimens

39 The additive-manufacturing (AM) technique, known as three-dimensional

40 Additive manufacturing (AM) technologies offer an attractive path

41 is fully compatible with existing industrial manufacturing and can lead to cost-effective production

42 e and omelettete, was determined after their manufacturing and during in vitro digestion.

43 o stretchable electronics; however, both the manufacturing and fundamental mechanics are largely elus

44 Drug Applications (ANDA) data that included manufacturing and healthy individual pharmacokinetic dat

45 ptimal performance, which adds extra cost to manufacturing and limits long-term device stability.

46 ger DNA origami structures are possible, but manufacturing and manipulating an increasingly long scaf

47 ngs for leveraging advances in both additive manufacturing and patient-specific computational modelin

48 ising candidate for future roll-to-roll mass manufacturing and practical application of highly effici

49 ith the recent renewed interests in chemical manufacturing and process intensification, simple, inexp

50 Radiochronometers are used to constrain the manufacturing and processing history of actinide materia

51 To address this deficiency, a variety of manufacturing and processing techniques are being adapte

52 nal applications in the fields of industrial manufacturing and prototyping to increasingly find roles

53 ughput yields, thereby offering simultaneous manufacturing and purification of nanoparticles with tai

54 solid cancers will require major technical, manufacturing and regulatory innovations centered around

55 a massively parallel approach for designing, manufacturing and screening mini-protein binders, integr

56 Additive manufacturing and self-assembly techniques enable lattic

57 ive environmental impact of their continuous manufacturing and trashing.

58 auxiliary power source, location of chemical manufacturing, and binding air emissions limits in nonco

59 GS-5734 is amenable to large-scale manufacturing, and clinical studies investigating the dr

60 ated approach combining simulation, additive manufacturing, and drop tower testing, the function of h

61 d of refrigerated storage (immediately after manufacturing, and during ripening and storage).

62 lished methodology in research, development, manufacturing, and production for screening, optimizatio

63 overing novel quality attributes, optimizing manufacturing, and screening drugs/biomaterials.

64 The ultra-fast manufacturing approach can be applied to a wide range of

65 Here, a low-cost manufacturing approach for bioresorbable conductors on b

66 using a scalable, single-step, weaving-based manufacturing approach.

67 t development in instrumentation, optics and manufacturing approaches has facilitated the design and

68 While many aspects of electronics manufacturing are controlled with great precision, the n

69 timal T cells, genetic engineering, and cell manufacturing are poised to broaden T-cell-based therapi

70 use during component, particularly battery, manufacturing are the largest contributors to overall PV

71 emental mercury (Hg(0)) wastes in mining and manufacturing areas has caused serious soil and groundwa

72 roundwater plumes associated with industrial manufacturing areas.

73 struction, allowing for potential changes in manufacturing as a mitigation measure to reduce microfib

74 cations throughout synthetic biology and bio-manufacturing as they are able to sense a wide range of

75 ance and product recovery in industrial food manufacturing as well as their use as sprayable carriers

76 k carbon between 1880 and 2015 within the US Manufacturing Belt, a region historically reliant on coa

77 llenges and future directions with regard to manufacturing bio-inspired hybrid materials are provided

78 ntial breakthrough applications in advancing manufacturing, biology, and chemistry research at the mi

79 con nitride film, suitable for semiconductor manufacturing but previously thought to result in wavegu

80 rocesses, such as laser welding and additive manufacturing, but also on other applications such as ph

81 sensitivity analysis with scalable, low-cost manufacturing, but they tend to measure only a single bi

82 m computer-aided design (CAD)/computer-aided manufacturing (CAM)-fabricated high-strength ceramics-na

83 due to its revolutionary and near limitless manufacturing capabilities.

84 fety data and WHO-standardized international manufacturing capability available in both high and low

85 could help overcome unresolved cell therapy manufacturing challenges and complement frameworks to de

86 rapidly to develop solutions to some of the manufacturing challenges identified in early clinical st

87 a more detailed evaluation of the effects of manufacturing changes on the subset contribution to in v

88 lly relevant differences in IIRMIs following manufacturing changes or between products with the same

89 hnology offers a new sustainable approach to manufacturing chemicals, enabling the replacement of pet

90 Our findings show that advanced textile manufacturing combined with scaffold-mediated gene deliv

91 02 volunteers from 4 machinery and equipment manufacturing companies in Taichung, Taiwan, was followe

92 Manufacturing companies routinely use copper fibers for

93 This study opens perspectives for manufacturing complex fiber network materials.

94 off between fine structural manipulation and manufacturing complex shapes in practical sizes and time

95 MSC lines derived from different donors and manufacturing conditions.

96 ter use for biomass feedstock irrigation and manufacturing/construction of solar power facilities cou

97 The manufacturing cost of the prototype was kept below 300 U

98 its portability, easy availability, cheaper manufacturing cost, and transportability.

99 Critical issues like manufacturing costs have to be addressed before mass pro

100 sign (QbD) of the final product and reducing manufacturing costs.

101 h were previously incompatible with additive manufacturing, could be processed successfully using sel

102 A manufacturing database of PROSE patients from 2002 to 20

103 onomic challenges associated with energy and manufacturing demands.

104 , such as funding, research and development, manufacturing, determination of safety and efficacy, reg

105 Here, we overcome the manufacturing difficulties and report a class of mechani

106 iscellaneous objects or powders), industrial manufacturing (e.g., for quality control of parts), or r

107 The current model for industrial chemical manufacturing employs large-scale megafacilities that be

108 uticals due to their complexity, which makes manufacturing errors more likely, and fragility, which m

109 CO2 for utilization purposes (e.g., polymer manufacturing, etc.).

110 Despite improved manufacturing facilities and implementation of effective

111 Eight manufacturing facilities participating in the National I

112 faster and to reduce the investment to build manufacturing facilities, in addition to allowing for th

113 ked increase in concentrations downstream of manufacturing facilities, with the most abundant compoun

114 1,1-difluoroethene, which is registered to a manufacturing facility in the area.

115 layer by layer increases design freedom and manufacturing flexibility, thereby enabling complex geom

116 s structures is compatible with roll-to-roll manufacturing for the fabrication of flexible devices.

117 re of gas-adsorbed graphene and guidance for manufacturing graphene-based electromechanical devices.

118 Unemployed Japanese men and those in manufacturing had an 8-11-fold increased risk of lung, g

119 s in three-dimensional printing and additive manufacturing, has many practical applications in the fi

120 res created by microfabrication and additive manufacturing have demonstrated value across a number of

121 iques in computational modeling and additive manufacturing have matured concurrently, and results fro

122 as micro- and nanotechnologies and additive manufacturing, have been integral for advancing the fiel

123 tant chemical building block that is used in manufacturing high-value products, such as latex and sup

124 s a key process in semiconductor high volume manufacturing (HVM), high resolution lithography is cruc

125 view how exploiting biological processes for manufacturing (i.e., industrial biomanufacturing) addres

126 nal quality assurance approach, derived from manufacturing in the mid-1900s.

127 just-in-time production strategies from the manufacturing industry.

128 ction of coal generation or a large chemical manufacturing industry.

129 he results here show the first step toward a manufacturing infrastructure for traditional crystalline

130 orporation is of great scientific and device manufacturing interest.

131 Our approach to metal-based additive manufacturing is applicable to a wide range of alloys an

132 Metallic powder bed additive manufacturing is capable of producing complex, functiona

133 tures, and their scale up to industrial-size manufacturing is emphasized here.

134 he field of therapeutic viral vector/vaccine manufacturing is maximizing production.

135 n of Triticum aestivum (common wheat) during manufacturing is not allowed and, without adequate label

136 Perhaps most notably, the device manufacturing is significantly less expensive, time-cons

137 and process compatibility with semiconductor manufacturing.Kerr frequency comb generation from micror

138 ure size, accuracy, and suitability for mass manufacturing; laminar flow was studied to assess their

139 Environmental Protection Agency for chemical-manufacturing LCI.

140 savings could be seen from changing battery manufacturing location and ensuring end of life recyclin

141 ting as well as its potential as a method of manufacturing low-cost, large-area, efficient perovskite

142 ing technology has emerged as an alternative manufacturing method for low-cost production of electrod

143 hemistry of the future" as a clean and green manufacturing methodology has yet to be realized.

144 rationalized design guidelines and scalable manufacturing methods has hindered their applications.

145 es, and in designing simple and large-scaled manufacturing methods that can be widely utilized are co

146 s, but little is known about the spectrum of manufacturing methods used and their effects on BMSC cha

147 ples experimentally, using advanced additive manufacturing methods, and inform our designs using fini

148 g the design of BMGMCs and developing viable manufacturing methods.

149 g material, but no two centers used the same manufacturing methods.

150 chanical work, we have developed a method of manufacturing modular skeletal muscle actuators that can

151 ary data show that this approach could allow manufacturing multifunctional multimodal LSPR chips for

152 MHPs ideal for cost-efficient, large-volume manufacturing of a plethora of optoelectronic devices th

153 al platform for investigations aiming at the manufacturing of a regenerative medicine-inspired bioart

154 low-cost, high-throughput, and reproducible manufacturing of advanced nano-optical devices.

155 nanometres) and can be used for reproducible manufacturing of aligned van der Waals heterostructures.

156 review of recent progress on the nano/micro-manufacturing of bio-inspired hybrid materials is then p

157 ll many problems to solve, on the way to the manufacturing of biomedical devices, including the lack

158 on on a roll-to-roll platform for economical manufacturing of bioresorbable electronics.

159 thrombocytopenia before lymphodepletion, and manufacturing of CAR T cells without selection of CD8(+)

160 Additive manufacturing of cellular structures has numerous applic

161 d availability, long-time knowledge and easy manufacturing of cellulose.

162 ch, it opens the possibility for large-scale manufacturing of crack-based or crack-derived assemblies

163 cells, so our methods will likely facilitate manufacturing of cytoreagents.Current widely used viral

164 This principle is employed for the manufacturing of devices ranging from high-performance t

165 s for early-stage drug discovery, continuous manufacturing of drug delivery vehicles, and ultra-preci

166 the selection of polymeric materials for the manufacturing of dynamic nanodevices using protein molec

167 Large-area flakes allow manufacturing of large-area mono-layer transition metal

168 However, manufacturing of nanoparticle-coated membranes requires

169 tive laser melting, and will enable additive manufacturing of other alloy systems, such as non-weldab

170 s can be an effective means for the scalable manufacturing of patterned-functional nanostructures.

171 sed on the use of this technology for direct manufacturing of production parts; however, it remains g

172 tive patterns, potentially applicable to the manufacturing of simple electronic circuits.

173 trolyte is a cost-effective approach for the manufacturing of solar cells.

174 Additive manufacturing of such materials is of interest for propu

175 tein folding and is potentially relevant for manufacturing of synthetic peptides and recombinant prot

176 During manufacturing of the dry fermented sausages, actin was h

177 Additive manufacturing of the industrially relevant alloy Ti-6Al-

178 ted high-throughput, economical roll-to-roll manufacturing of the metamaterial, which is vital for pr

179 he mining of the rare earth oxide ceria, the manufacturing of the solar concentration infrastructure,

180 at provides the means for on-site, on-demand manufacturing of therapeutics and biomolecules.

181 here is no process for 3D printing (additive manufacturing) of nt-metals.

182 The design, and manufacturing, of T cell therapies is not standardized a

183 complexity or cost to existing protocols for manufacturing oligonucleotide drugs.

184 ) are used as lubricants and coolants in the manufacturing operations.

185 Metal-based additive manufacturing, or three-dimensional (3D) printing, is a

186 Manufacturing organizations' environmental impacts are o

187 nological applications ranging from additive manufacturing over machining of micro- and nanostructure

188 n Pennsylvania, which shows steel and cement manufacturing paired to suitable sinks as having the low

189 ABSTARCT: With the advent of intelligent manufacturing, phase measuring deflectometry (PMD) has b

190 y tool for dialog on clinical development or manufacturing plans.

191 cture that captures complexity on a scalable manufacturing platform.

192 nic components within an integrated additive manufacturing platform.

193 cal ingredients in a compact, reconfigurable manufacturing platform.

194 Using these markers, we developed a good manufacturing practice (GMP) differentiation protocol fo

195 ned with efficient cryopreservation and good manufacturing practice (GMP)-compatible culture, make th

196 Single-step production from a Good Manufacturing Practice cold kit may enable rapid adoptio

197 lications such as cell therapies, where good manufacturing practice compatibility is of paramount imp

198 ith (18)F-FDS synthesized using current good manufacturing practice, could rapidly differentiate true

199 linical trial evaluating the effects of good manufacturing practice-artesunate in patients with traum

200 linical trial evaluating the effects of good manufacturing practice-artesunate in patients with traum

201 PIV3-specific T cells produced with our Good Manufacturing Practice-compliant manufacturing process,

202 patients with RDEB were transduced with good manufacturing practice-grade retrovirus carrying full-le

203 challenged by the high cost of current Good Manufacturing Practices (cGMP) production.

204 even centers using, and one developing, Good Manufacturing Practices (GMP) processes were surveyed as

205 ed ex vivo gene transfer in a dedicated Good Manufacturing Practices facility, limiting availability.

206 This paves the way for proposed good manufacturing practices manufacture and clinical trials

207 multistep continuous-flow CGMP (current good manufacturing practices) process that produced 24 kilogr

208 on set samples were tested with current good manufacturing practices-manufactured reagents after assa

209 Although manufacturing problems for generic pharmaceuticals exist

210 f TMUPS, its adoption has been challenged by manufacturing problems, such as compromised integrity of

211 a could be very interesting to know the best manufacturing procedure to prepare blueberry-derived pro

212 is present in most samples due to imperfect manufacturing procedures.

213 This report describes the manufacturing process for 75 PHPI clinical lots and summ

214 ultimate goal of developing a cost-effective manufacturing process for Si solar cells based on electr

215 s collected from the continuous drug product manufacturing process not only demonstrated the accuracy

216 However, the high cost and complex manufacturing process of tear glucose analyzers combined

217 he different stages of a lab-scale chocolate manufacturing process on the content of oligomeric proan

218 eloped USP 4 method was capable of detecting manufacturing process related performance changes, and m

219 A fully automated additive manufacturing process that produces all-printed flexible

220 Photolithography is an important manufacturing process that relies on using photoresists,

221 acids are likely products or byproducts of a manufacturing process that uses 1,1-difluoroethene, whic

222 1E2 will provide a scalable purification and manufacturing process using protein A/G-based chromatogr

223 th our Good Manufacturing Practice-compliant manufacturing process, in immunocompromised patients wit

224 perovskite-based devices are fabricated by a manufacturing process, which is demonstrated.

225 nted sausages salchichon type throughout the manufacturing process.

226 d the tunability of film porosity during the manufacturing process.

227 optimise cleaning practices for a given food manufacturing process.

228 d can be integrated into existing electronic manufacturing processes and technology.

229 Manufacturing processes for biological molecules in the

230 onent of the control strategy for continuous manufacturing processes for drug products, including det

231 mous progress in the materials, designs, and manufacturing processes for flexible/stretchable system

232 Building robust manufacturing processes from biological components is a

233 ally integrated devices using components and manufacturing processes from the telecommunications indu

234 of waste streams from current or future food manufacturing processes have nutritional value that is w

235 The fabrication and manufacturing processes of industrial commodities such a

236 d the effects of microenvironmental cues and manufacturing processes on cell behavior often inadequat

237 c devices, however, require energy intensive manufacturing processes such as alloying and spark plasm

238 d biomaterials has the potential to generate manufacturing processes that produce standardized cells

239 Emerging manufacturing processes to generate regenerative advance

240 s advances in immunology, synthetic biology, manufacturing processes, and government regulation.

241 pacts on existing melting and solidification manufacturing processes, such as laser welding and addit

242 th the same active ingredients but different manufacturing processes.

243 ity and quantity of DNA left after extensive manufacturing processes.

244 ter lie at the heart of key industrial-scale manufacturing processes.

245 pressed proteins is critical when developing manufacturing processes.

246 ors, produced exclusively using standard PCB manufacturing processes.

247 haracteristics were prepared using different manufacturing processes.

248 harmaceutical drug products can occur during manufacturing, processing, packaging, shipment and stora

249 hese structures is crucial for designing and manufacturing products for emerging applications.

250 g transition from rapid prototyping to rapid manufacturing prompts new challenges for mechanical engi

251 congruently; the latter is advantageous for manufacturing pure materials in large amounts.

252 These cell products meet current manufacturing quality standards for both mobilized leuka

253 owever, the use of FDM 3D printing in tablet manufacturing requires a large portion of polymer, which

254 These results show that differences in manufacturing resulted in variable BMSC characteristics

255 ainty of build performance in metal additive manufacturing, robust process monitoring systems that ca

256 able structures with desired performance and manufacturing scalability.

257 l monitoring and maintenance activities in a manufacturing setting.

258 The respondents represented 454 different manufacturing sites.

259 ontaminants found often at dye and munitions manufacturing sites.

260 During manufacturing, some ingredients are added in amounts exc

261 t is immunogenic and deployable in regard to manufacturing, stability, and delivery characteristics.

262 sed electronics, with particular emphasis on manufacturing, stability, and health and environmental c

263 ation of MSC mechanisms, therapies, and cell manufacturing strategies.

264 eum substances from four petroleum substance manufacturing streams and evaluated their chemical compo

265 Our finding may provide a new route to manufacturing super-strong steels in a simple and econom

266 plications; however, the development of cell manufacturing systems to enable this promise faces many

267 Further evidence of the flexibility of this manufacturing technique is demonstrated with printed pri

268 des (whole leaf, broken, fannings, dust) and manufacturing techniques (orthodox, "crush, tear, curl")

269 ys beyond the surface, and utilizes additive manufacturing techniques as a tool to create materials w

270 n the other hand, have demonstrated, through manufacturing techniques discovered during the past deca

271 Emerging additive manufacturing techniques enable investigation of the eff

272 ed for decorating historical textiles, their manufacturing techniques have been elusive for centuries

273 Printed circuit board (PCB) manufacturing techniques have several advantages in this

274 The use of extremely affordable manufacturing techniques provides a rapid, sensitive, re

275 results open a new platform for the additive manufacturing techniques, for example, three-dimensional

276 via standardized printed circuit board (PCB) manufacturing techniques.

277 decades, 3D printing (also known as additive manufacturing) techniques have moved beyond their tradit

278 n, simple, inexpensive, and reliable ceramic manufacturing technologies are needed.

279 gy push from better simulation tools and new manufacturing technologies, and on the other hand by a m

280 ine-scale processing approaches, and current manufacturing technology that operates at large scale.

281 strongly required for low-cost and scalable manufacturing technology.

282 synthetic gene cluster (BGC) responsible for manufacturing the antibiotic.

283 sferred into a numerical control machine for manufacturing the personalized titanium plates by 3D pri

284 s the various types of papyri, the method of manufacturing them, and all that concerns writing materi

285 However, due to increased manufacturing, there is concern that human and environme

286 Manufacturing these devices will critically depend on th

287 g-lived persistence, but challenges exist in manufacturing this T-cell subset because they are rare a

288 work demonstrates the potential of additive manufacturing to create alloys with unique microstructur

289 ed therapeutics are promoting pharmaceutical manufacturing to transition from a traditional batch par

290 s, may be released to the environment during manufacturing, transportation, storage, training, and di

291 , estimates the annual releases of ENMs from manufacturing, use, and disposal of a product explicitly

292 lung, gastric, and colorectal cancers, with manufacturing used as the referent occupation or industr

293 ructured ceria, facilitating its large-scale manufacturing using green, economic, non-toxic solvents.

294 riate price reductions were secured; quality manufacturing was improved; a fast-track registration me

295 hilus ACA DC 0022, used in Greek Feta cheese manufacturing, was purified.

296 ups have ongoing or completed GMP-level cell manufacturing, we highlight key clinical translation con

297 g times for productivity streamlining in all manufacturing where interfacial reaction occurs.

298 s study is fully compatible with large-scale manufacturing where the patterning areas are only limite

299 elerate drug screening and enable continuous manufacturing, while enhancing dosage accuracy.Tradition

300 n boundaries, and dislocations formed during manufacturing, while high uniform elongation correlates