594:
43:
fuels, chemical feedstocks, and advanced materials. To date, research in synthetic biology has typically relied on trial-and-error approaches, which are costly, laborious, and inefficient. Engineering biology methods include a combination of traditional biological techniques such as bioinformatics,
170:↑ Beal, J., Weiss, R., Densmore, D., Adler, A., Babb, J., Bhatia, S., ... & Loyall, J. (2011, June). TASBE: A tool-chain to accelerate synthetic biological engineering. In Proceedings of the 3rd International Workshop on Bio-Design Automation (pp. 19–21).
75:
Hutchison, C. A., Chuang, R. Y., Noskov, V. N., Assad-Garcia, N., Deerinck, T. J., Ellisman, M. H., ... & Pelletier, J. F. (2016). Design and synthesis of a minimal bacterial genome. Science, 351(6280), aad6253.
142:
Schuergers, N., Werlang, C., Ajo-Franklin, C., & Boghossian, A. (2017). A Synthetic
Biology Approach to Engineering Living Photovoltaics. Energy & Environmental Science. doi:10.1039/C7EE00282C
23:
which have been used to manipulate information, construct materials, process chemicals, produce energy, provide food, and help maintain or enhance human health and environment.
328:
210:
145:
Teague, B. P., Guye, P., & Weiss, R. (2016). Synthetic
Morphogenesis. Cold Spring Harbor Perspectives in Biology, 8(9), a023929. doi:10.1101/cshperspect.a023929
448:
254:
39:. This approach seeks to harness the power of living systems for a variety of manufacturing applications, such as advanced therapeutics,
537:
203:
650:
171:
196:
598:
564:
136:
149:
44:
molecular biology, and wet cell biology, as well as conventional engineering practices such as design and computation.
655:
625:
640:
569:
505:
552:
512:
630:
247:
645:
635:
517:
490:
418:
620:
527:
522:
495:
379:
453:
362:
357:
234:
219:
500:
463:
443:
557:
532:
301:
148:
Kelley, N. J. (2015). Engineering
Biology for Science & Industry : Accelerating Progress.
32:
574:
394:
384:
372:
296:
401:
389:
367:
350:
155:
112:
36:
20:
160:
Kelley, N. J. (2014). The promise and challenge of engineering biology in the United States.
91:"The Engineering Biology Problems Book: Bridging the gap between biomedicine and engineering"
542:
458:
286:
264:
102:
172:
http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.467.7189&rep=rep1&type=pdf
411:
313:
274:
176:
Schrödinger, E. (1946). What is life?: the physical aspect of the living cell. Cambridge.
77:
35:
biological organisms have advanced a new engineering discipline, commonly referred to as
547:
323:
318:
281:
269:
242:
137:
https://www.congress.gov/congressional-record/2022/03/17/senate-section/article/S1237-5
40:
150:
http://nancyjkelley.com/wp-content/uploads/Meeting-Summary.Final_.6.9.15-Formatted.pdf
614:
579:
345:
291:
90:
483:
335:
306:
183:
64:
478:
473:
406:
438:
340:
116:
107:
468:
259:
188:
165:
179:
19:
is the set of methods for designing, building, and testing engineered
154:
H.R.591. - Engineering
Biology Research and Development Act of 2015.
192:
156:
https://www.congress.gov/bill/114th-congress/house-bill/591
59:
Endy, D. (2005). Foundations for engineering biology.
431:
233:
226:
329:Strategies for engineered negligible senescence
204:
8:
593:
230:
211:
197:
189:
89:Klabukov, I.D.; Baranovskii, D.S. (2023).
106:
132:H.R.4521 - America COMPETES Act of 2022
52:
449:Differential technological development
7:
255:Aldehyde-stabilized cryopreservation
538:Future-oriented technology analysis
14:
180:Engineering Biology Problems Book
31:Rapid advances in the ability to
592:
95:Biomedical Research and Therapy
1:
565:Technology in science fiction
78:doi:10.1126/science.aad6253
672:
570:Technology readiness level
506:Technological unemployment
588:
553:Technological singularity
513:Technological convergence
166:doi:10.1089/ind.2014.1516
248:Microgravity bioprinting
162:Industrial Biotechnology
108:10.15419/bmrat.v10i8.821
518:Technological evolution
491:Exploratory engineering
419:Whole genome sequencing
65:doi:10.1038/nature04342
651:Appropriate technology
528:Technology forecasting
523:Technological paradigm
496:Proactionary principle
380:Robot-assisted surgery
63:, 438(7067), 449-453.
454:Disruptive innovation
363:Regenerative medicine
358:Personalized medicine
220:Emerging technologies
501:Technological change
444:Collingridge dilemma
184:10.2139/ssrn.2898429
558:Technology scouting
533:Accelerating change
302:Genetic engineering
17:Engineering biology
656:Artificial objects
626:Molecular genetics
575:Technology roadmap
395:Synthetic genomics
385:Relational biology
373:Tissue engineering
297:Generative biology
164:, 10(3), 137–139.
33:genetically modify
21:biological systems
641:Synthetic biology
608:
607:
427:
426:
390:Synthetic biology
368:Stem-cell therapy
351:engineered uterus
265:Artificial organs
37:synthetic biology
663:
596:
595:
543:Horizon scanning
459:Ephemeralization
287:Brain transplant
231:
213:
206:
199:
190:
121:
120:
110:
101:(8): 5801–5803.
86:
80:
73:
67:
57:
671:
670:
666:
665:
664:
662:
661:
660:
631:Systems biology
611:
610:
609:
604:
584:
423:
412:Oncolytic virus
314:Head transplant
222:
217:
129:
124:
88:
87:
83:
74:
70:
58:
54:
50:
29:
12:
11:
5:
669:
667:
659:
658:
653:
648:
646:Biocybernetics
643:
638:
636:Bioinformatics
633:
628:
623:
613:
612:
606:
605:
603:
602:
589:
586:
585:
583:
582:
577:
572:
567:
562:
561:
560:
555:
550:
545:
540:
535:
525:
520:
515:
510:
509:
508:
498:
493:
488:
487:
486:
481:
476:
471:
461:
456:
451:
446:
441:
435:
433:
429:
428:
425:
424:
422:
421:
416:
415:
414:
404:
399:
398:
397:
387:
382:
377:
376:
375:
370:
360:
355:
354:
353:
343:
338:
333:
332:
331:
324:Life extension
321:
319:Isolated brain
316:
311:
310:
309:
299:
294:
289:
284:
282:Biofabrication
279:
278:
277:
272:
270:Organ printing
262:
257:
252:
251:
250:
243:3D bioprinting
239:
237:
228:
224:
223:
218:
216:
215:
208:
201:
193:
187:
186:
177:
174:
168:
158:
152:
146:
143:
134:
133:
128:
125:
123:
122:
81:
68:
51:
49:
46:
28:
25:
13:
10:
9:
6:
4:
3:
2:
668:
657:
654:
652:
649:
647:
644:
642:
639:
637:
634:
632:
629:
627:
624:
622:
621:Biotechnology
619:
618:
616:
601:
600:
591:
590:
587:
581:
580:Transhumanism
578:
576:
573:
571:
568:
566:
563:
559:
556:
554:
551:
549:
546:
544:
541:
539:
536:
534:
531:
530:
529:
526:
524:
521:
519:
516:
514:
511:
507:
504:
503:
502:
499:
497:
494:
492:
489:
485:
482:
480:
477:
475:
472:
470:
467:
466:
465:
462:
460:
457:
455:
452:
450:
447:
445:
442:
440:
437:
436:
434:
430:
420:
417:
413:
410:
409:
408:
405:
403:
400:
396:
393:
392:
391:
388:
386:
383:
381:
378:
374:
371:
369:
366:
365:
364:
361:
359:
356:
352:
349:
348:
347:
346:Organ culture
344:
342:
339:
337:
334:
330:
327:
326:
325:
322:
320:
317:
315:
312:
308:
305:
304:
303:
300:
298:
295:
293:
292:De-extinction
290:
288:
285:
283:
280:
276:
273:
271:
268:
267:
266:
263:
261:
258:
256:
253:
249:
246:
245:
244:
241:
240:
238:
236:
232:
229:
225:
221:
214:
209:
207:
202:
200:
195:
194:
191:
185:
181:
178:
175:
173:
169:
167:
163:
159:
157:
153:
151:
147:
144:
141:
140:
139:
138:
131:
130:
126:
118:
114:
109:
104:
100:
96:
92:
85:
82:
79:
72:
69:
66:
62:
56:
53:
47:
45:
42:
38:
34:
26:
24:
22:
18:
597:
484:Robot ethics
336:Nanomedicine
307:Gene therapy
182:. 2016. DOI:
161:
135:
127:Bibliography
98:
94:
84:
71:
60:
55:
30:
16:
15:
548:Moore's law
479:Neuroethics
474:Cyberethics
407:Virotherapy
341:Nanosensors
41:sustainable
615:Categories
439:Automation
235:Biomedical
48:References
469:Bioethics
402:Tricorder
117:2198-4093
260:Ampakine
27:History
464:Ethics
432:Topics
227:Fields
115:
61:Nature
599:List
275:Womb
113:ISSN
103:doi
617::
111:.
99:10
97:.
93:.
212:e
205:t
198:v
119:.
105::
Text is available under the Creative Commons Attribution-ShareAlike License. Additional terms may apply.