“Molecular machine”的意思、由来-开放百科全书

A molecular machine, nanite, or nanomachine,^[1] refers to any discrete number of molecular components that produce quasi-mechanical movements (output) in response to specific stimuli (input).^[2] In biology, macromolecular machines frequently perform tasks essential for life such as DNA replication and ATP synthesis. The expression is often more generally applied to molecules that simply mimic functions that occur at the macroscopic level. The term is also common in nanotechnology where a number of highly complex molecular machines have been proposed that are aimed at the goal of constructing a molecular assembler.

For the last several decades, chemists and physicists alike have attempted, with varying degrees of success, to miniaturize machines found in the macroscopic world. Molecular machines research is currently at the forefront with the 2016 Nobel Prize in Chemistry being awarded to Jean-Pierre Sauvage, Sir J. Fraser Stoddart and Bernard L. Feringa for the design and synthesis of molecular machines.^[3]^[4]

Types

Molecular machines can be divided into two broad categories; artificial and biological. In general, artificial molecular machines (AMMs) refer to molecules that are artificially designed and synthesized whereas biological molecular machines can commonly be found in nature.^[5]

Artificial

A wide variety of artificial molecular machines (AMMs) have been synthesized by chemists which are

The first AMM, a molecular shuttle, was synthesized by Sir J. Fraser Stoddart. ^[6]

A molecular shuttle is a rotaxane molecule where a ring is mechanically interlocked onto an axle with two bulky stoppers. The ring can move between two binding sites with various stimuli such as light, pH, solvents, and ions. ^[7] As the authors of this 1991 JACS paper noted: “Insofar as it becomes possible to control the movement of one molecular component with respect to the other in a [2]rotaxane, the technology for building molecular machines will emerge.”, mechanically interlocked molecular architectures spearheaded AMM design and synthesis as they provide directed molecular motion. ^[8] Today a wide variety of AMMs exists as listed below.

Molecular motors

Single bond rotary motors ^[13] are generally fueled by chemical reactions whereas double bond rotary motors ^[14] are generally fueled by light. The rotation speed of the motor can also be tuned by careful molecular design. ^[15] Carbon nanotube nanomotors have also been produced. ^[16]

Molecular propeller

A molecular propeller is a molecule that can propel fluids when rotated, due to its special shape that is designed in analogy to macroscopic propellers. ^[17] ^[18] It has several molecular-scale blades attached at a certain pitch angle around the circumference of a nanoscale shaft. Also see molecular gyroscope.

Molecular switch

A molecular switch is a molecule that can be reversibly shifted between two or more stable states. ^[19] The molecules may be shifted between the states in response to changes in pH, light, temperature, an electric current, microenvironment, or the presence of a ligand. ^[19] ^[20] ^[21]

Molecular shuttle

A molecular shuttle is a molecule capable of shuttling molecules or ions from one location to another. ^[22] A common molecular shuttle consists of a rotaxane where the macrocycle can move between two sites or stations along the dumbbell backbone. ^[22] ^[6] ^[23]

Nanocar

Nanocars are single molecule vehicles that resemble macroscopic automobiles and are important for understanding how to control molecular diffusion on surfaces. The first nanocars were synthesized by James M. Tour in 2005. They had an H shaped chassis and 4 molecular wheels (fullerenes) attached to the four corners. ^[24] In 2011, Ben Feringa and co-workers synthesized the first motorized nanocar which had molecular motors attached to the chassis as rotating wheels. ^[25] The authors were able to demonstrate directional motion of the nanocar on a copper surface by providing energy from a scanning tunneling microscope tip. Later in 2017, worlds first ever Nanocar race took place in France.

Molecular balance

A molecular balance^[26]^[27] is a molecule that can interconvert between two and more conformational or configurational states in response to the dynamic of multiple intra- and intermolecular driving forces, such as hydrogen bonding, solvophobic/hydrophobic effects,^[28] π interactions,^[29] and steric and dispersion interactions.^[30]

Molecular tweezers

Molecular sensor

A molecular sensor is a molecule that interacts with an analyte to produce a detectable change.^[34] ^[35] Molecular sensors combine molecular recognition with some form of reporter, so the presence of the item can be observed.

Molecular logic gate

A molecular logic gate is a molecule that performs a logical operation on one or more logic inputs and produces a single logic output. ^[36] ^[37] Unlike a molecular sensor, the molecular logic gate will only output when a particular combination of inputs are present.

Molecular assembler

A molecular assembler is a molecular machine able to guide chemical reactions by positioning reactive molecules with precision.^[38]^[39]^[40]^[41]^[42]

Molecular hinge

Biological

The most complex macromolecular machines are found within cells, often in the form of multi-protein complexes.^[46] Some biological machines are motor proteins, such as myosin, which is responsible for muscle contraction, kinesin, which moves cargo inside cells away from the nucleus along microtubules, and dynein, which moves cargo inside cells towards the nucleus and produces the axonemal beating of motile cilia and flagella. "[I]n effect, the [motile cilium] is a nanomachine composed of perhaps over 600 proteins in molecular complexes, many of which also function independently as nanomachines...Flexible linkers allow the mobile protein domains connected by them to recruit their binding partners and induce long-range allostery via protein domain dynamics. "^[1] Other biological machines are responsible for energy production, for example ATP synthase which harnesses energy from proton gradients across membranes to drive a turbine-like motion used to synthesise ATP, the energy currency of a cell.^[47] Still other machines are responsible for gene expression, including DNA polymerases for replicating DNA, RNA polymerases for producing mRNA, the spliceosome for removing introns, and the ribosome for synthesising proteins. These machines and their nanoscale dynamics are far more complex than any molecular machines that have yet been artificially constructed.^[48]

These biological machines might have applications in nanomedicine. For example,^[49] they could be used to identify and destroy cancer cells.^[50]^[51] Molecular nanotechnology is a speculative subfield of nanotechnology regarding the possibility of engineering molecular assemblers, biological machines which could re-order matter at a molecular or atomic scale. Nanomedicine would make use of these nanorobots, introduced into the body, to repair or detect damages and infections. Molecular nanotechnology is highly theoretical, seeking to anticipate what inventions nanotechnology might yield and to propose an agenda for future inquiry. The proposed elements of molecular nanotechnology, such as molecular assemblers and nanorobots are far beyond current capabilities.^[52]^[53]

Research

The construction of more complex molecular machines is an active area of theoretical and experimental research. A number of molecules, such as molecular propellers, have been designed, although experimental studies of these molecules are inhibited by the lack of methods to construct these molecules.{{citation needed|date=February 2018}} In this context, theoretical modeling can be extremely useful{{cn|date=September 2018}} to understand the self-assembly/disassembly processes of rotaxanes, important for the construction of light-powered molecular machines.^[54] This molecular-level knowledge may foster the realization of ever more complex, versatile, and effective molecular machines for the areas of nanotechnology, including molecular assemblers.

Although currently not feasible, some potential applications of molecular machines are transport at the molecular level, manipulation of nanostructures and chemical systems, high density solid-state informational processing and molecular prosthetics.^[55] Many fundamental challenges need to be overcome before molecular machines can be used practically such as autonomous operation, complexity of machines, stability in the synthesis of the machines and the working conditions.^[5]

In 2018, an international team of researchers, led by researchers from the University of Osaka, Japan, created a molecular machine in which elements of a mechanical ratchet were used. The main advantage of this machine is that it provides movement in only one direction. In addition, some features of the structure of the molecular machine provide the best balance between the produced motion and chemical reactivity of the molecules that make up it, that is a problem in itself.^[56]

References

1. ^¹{{cite journal | last = Satir | first = Peter |author2=Søren T. Christensen | title = Structure and function of mammalian cilia | journal = Histochemistry and Cell Biology | volume = 129 | issue = 6 | pages = 687–93 | date = 2008-03-26 | url = http://www.springerlink.com/content/x5051hq648t3152q/ | doi = 10.1007/s00418-008-0416-9 | id = 1432-119X | accessdate =2009-09-11 | pmid = 18365235 | pmc = 2386530 }}
2. ^{{cite journal |vauthors=Ballardini R, Balzani V, Credi A, Gandolfi MT, Venturi M | title = Artificial Molecular-Level Machines: Which Energy To Make Them Work? | year = 2001 | journal = Acc. Chem. Res. | volume = 34 | issue = 6 | pages = 445–455 | doi = 10.1021/ar000170g | url=http://pubs.acs.org/cgi-bin/abstract.cgi/achre4/2001/34/i06/abs/ar000170g.html}}
3. ^{{cite news |author=Staff |title=The Nobel Prize in Chemistry 2016 |url=https://www.nobelprize.org/nobel_prizes/chemistry/laureates/2016/press.html |date=5 October 2016 |work=Nobel Foundation |accessdate=5 October 2016 }}
4. ^{{cite news |last1=Chang |first1=Kenneth |last2=Chan |first2=Sewell |title=3 Makers of ‘World’s Smallest Machines’ Awarded Nobel Prize in Chemistry |url=https://www.nytimes.com/2016/10/06/science/nobel-prize-chemistry.html |date=5 October 2016 |work=New York Times |accessdate=5 October 2016 }}
5. ^¹²{{Cite journal|last=Erbas-Cakmak|first=Sundus|last2=Leigh|first2=David A.|last3=McTernan|first3=Charlie T.|last4=Nussbaumer|first4=Alina L.|title=Artificial Molecular Machines|journal=Chemical Reviews|volume=115|issue=18|pages=10081–10206|doi=10.1021/acs.chemrev.5b00146|pmid=26346838|pmc=4585175|year=2015}}
6. ^¹{{cite journal |last1=Anelli |first1=Pier Lucio |last2=Spencer |first2=Neil |last3=Stoddart |first3=J. Fraser |title=A molecular shuttle |journal=Journal of the American Chemical Society |date=June 1991 |volume=113 |issue=13 |pages=5131–5133 |doi=10.1021/ja00013a096|pmid=27715028 }}
7. ^{{cite journal |last1=Bruns |first1=Carson J. |last2=Stoddart |first2=J. Fraser |title=Rotaxane-Based Molecular Muscles |journal=Accounts of Chemical Research |date=30 May 2014 |volume=47 |issue=7 |pages=2186–2199 |doi=10.1021/ar500138u|pmid=24877992 }}
8. ^{{cite journal |last1=Kay |first1=Euan R. |last2=Leigh |first2=David A. |title=Rise of the Molecular Machines |journal=Angewandte Chemie International Edition |date=24 August 2015 |volume=54 |issue=35 |pages=10080–10088 |doi=10.1002/anie.201503375|pmid=26219251 |pmc=4557038 }}
9. ^{{Cite journal|last=Fletcher|first=Stephen P.|last2=Dumur|first2=Frédéric|last3=Pollard|first3=Michael M.|last4=Feringa|first4=Ben L.|date=2005-10-07|title=A Reversible, Unidirectional Molecular Rotary Motor Driven by Chemical Energy|url=http://science.sciencemag.org/content/310/5745/80|journal=Science|volume=310|issue=5745|pages=80–82|doi=10.1126/science.1117090|issn=0036-8075|pmid=16210531|bibcode=2005Sci...310...80F}}
10. ^{{Cite journal|last=Perera|first=U. G. E.|last2=Ample|first2=F.|last3=Kersell|first3=H.|last4=Zhang|first4=Y.|last5=Vives|first5=G.|last6=Echeverria|first6=J.|last7=Grisolia|first7=M.|last8=Rapenne|first8=G.|last9=Joachim|first9=C.|date=January 2013|title=Controlled clockwise and anticlockwise rotational switching of a molecular motor|journal=Nature Nanotechnology|volume=8|issue=1|pages=46–51|doi=10.1038/nnano.2012.218|pmid=23263725|issn=1748-3395|bibcode=2013NatNa...8...46P}}
11. ^{{Cite journal|last=Schliwa|first=Manfred|last2=Woehlke|first2=Günther|date=2003-04-17|title=Molecular motors|journal=Nature|volume=422|issue=6933|pages=759–765|doi=10.1038/nature01601|pmid=12700770|bibcode=2003Natur.422..759S}}
12. ^{{Cite journal|last=van Delden|first=Richard A.|last2=Wiel|first2=Matthijs K. J. ter|last3=Pollard|first3=Michael M.|last4=Vicario|first4=Javier|last5=Koumura|first5=Nagatoshi|last6=Feringa|first6=Ben L.|date=October 2005|title=Unidirectional molecular motor on a gold surface|journal=Nature|volume=437|issue=7063|pages=1337–1340|doi=10.1038/nature04127|pmid=16251960|issn=1476-4687|bibcode=2005Natur.437.1337V}}
13. ^{{cite journal |last1=Kelly |first1=T. Ross |last2=De Silva |first2=Harshani |last3=Silva |first3=Richard A. |title=Unidirectional rotary motion in a molecular system |journal=Nature |date=9 September 1999 |volume=401 |issue=6749 |pages=150–152 |doi=10.1038/43639|pmid=10490021 }}
14. ^{{cite journal |last1=Koumura |first1=Nagatoshi |last2=Zijlstra |first2=Robert W. J. |last3=van Delden |first3=Richard A. |last4=Harada |first4=Nobuyuki |last5=Feringa |first5=Ben L. |title=Light-driven monodirectional molecular rotor |journal=Nature |date=9 September 1999 |volume=401 |issue=6749 |pages=152–155 |doi=10.1038/43646|pmid=10490022 |url=https://pure.rug.nl/ws/files/3616669/1999NatureKoumura.pdf }}
15. ^{{cite journal |last1=Vicario |first1=Javier |last2=Meetsma |first2=Auke |last3=Feringa |first3=Ben L. |title=Controlling the speed of rotation in molecular motors. Dramatic acceleration of the rotary motion by structural modification |journal=Chemical Communications |date=2005 |issue=47 |pages=5910–2 |doi=10.1039/B507264F|pmid=16317472 |url=https://www.rug.nl/research/portal/en/publications/controlling-the-speed-of-rotation-in-molecular-motors-dramatic-acceleration-of-the-rotary-motion-by-structural-modification(002a32ff-d6bf-4078-a546-c2a1ace86aa2).html }}
16. ^{{cite journal |last1=Fennimore |first1=A. M. |last2=Yuzvinsky |first2=T. D. |last3=Han |first3=Wei-Qiang |last4=Fuhrer |first4=M. S. |last5=Cumings |first5=J. |last6=Zettl |first6=A. |title=Rotational actuators based on carbon nanotubes |journal=Nature |date=24 July 2003 |volume=424 |issue=6947 |pages=408–410 |doi=10.1038/nature01823|pmid=12879064 }}
17. ^{{cite journal |last1=Simpson |first1=Christopher D. |last2=Mattersteig |first2=Gunter |last3=Martin |first3=Kai |last4=Gherghel |first4=Lileta |last5=Bauer |first5=Roland E. |last6=Räder |first6=Hans Joachim |last7=Müllen |first7=Klaus |title=Nanosized Molecular Propellers by Cyclodehydrogenation of Polyphenylene Dendrimers |journal=Journal of the American Chemical Society |date=March 2004 |volume=126 |issue=10 |pages=3139–3147 |doi=10.1021/ja036732j|pmid=15012144 }}
18. ^{{cite journal |doi=10.1103/PhysRevLett.98.266102|pmid=17678108|title=Chemically Tunable Nanoscale Propellers of Liquids|journal=Physical Review Letters|volume=98|issue=26|pages=266102|year=2007|last1=Wang|first1=Boyang|last2=Král|first2=Petr}}
19. ^¹{{cite journal |last1=Feringa |first1=Ben L. |last2=van Delden |first2=Richard A. |last3=Koumura |first3=Nagatoshi |last4=Geertsema |first4=Edzard M. |title=Chiroptical Molecular Switches |journal=Chemical Reviews |date=May 2000 |volume=100 |issue=5 |pages=1789–1816 |doi=10.1021/cr9900228|pmid=11777421 |url=https://pure.rug.nl/ws/files/3616486/1996AdvMaterFeringa.pdf }}
20. ^{{cite journal |last1=Knipe |first1=Peter C. |last2=Thompson |first2=Sam |last3=Hamilton |first3=Andrew D. |title=Ion-mediated conformational switches |journal=Chemical Science |date=2015 |volume=6 |issue=3 |pages=1630–1639 |doi=10.1039/C4SC03525A|pmid=28694943 |pmc=5482205 }}
21. ^¹²{{cite journal|title=Hünlich base derivatives as photo-responsive Λ-shaped inges|journal=Organic Chemistry Frontiers|date=2017|volume=4|issue=2|pages=224–228|doi=10.1039/C6QO00653A|url=http://pubs.rsc.org/-/content/articlehtml/2017/qo/c6qo00653a | last1 = Kazem-Rostami | first1 = Masoud | last2 = Moghanian | first2 = Amirhossein}}
22. ^¹{{cite journal |last1=Bissell |first1=Richard A |last2=Córdova |first2=Emilio |last3=Kaifer |first3=Angel E. |last4=Stoddart |first4=J. Fraser |title=A chemically and electrochemically switchable molecular shuttle |journal=Nature |date=12 May 1994 |volume=369 |issue=6476 |pages=133–137 |doi=10.1038/369133a0}}
23. ^{{Cite journal|last=Chatterjee|first=Manashi N.|last2=Kay|first2=Euan R.|last3=Leigh|first3=David A.|date=2006-03-01|title=Beyond Switches: Ratcheting a Particle Energetically Uphill with a Compartmentalized Molecular Machine|journal=Journal of the American Chemical Society|volume=128|issue=12|pages=4058–4073|doi=10.1021/ja057664z|pmid=16551115|issn=0002-7863}}
24. ^{{cite journal |last1=Shirai |first1=Yasuhiro |last2=Osgood |first2=Andrew J. |last3=Zhao |first3=Yuming |last4=Kelly |first4=Kevin F. |last5=Tour |first5=James M. |title=Directional Control in Thermally Driven Single-Molecule Nanocars |journal=Nano Letters |date=November 2005 |volume=5 |issue=11 |pages=2330–2334 |doi=10.1021/nl051915k|pmid=16277478 }}
25. ^{{cite journal |last1=Kudernac |first1=Tibor |last2=Ruangsupapichat |first2=Nopporn |last3=Parschau |first3=Manfred |last4=Maciá |first4=Beatriz |last5=Katsonis |first5=Nathalie |last6=Harutyunyan |first6=Syuzanna R. |last7=Ernst |first7=Karl-Heinz |last8=Feringa |first8=Ben L. |title=Electrically driven directional motion of a four-wheeled molecule on a metal surface |journal=Nature |date=10 November 2011 |volume=479 |issue=7372 |pages=208–211 |doi=10.1038/nature10587|pmid=22071765 }}
26. ^{{Cite journal|last=Paliwal|first=S.|last2=Geib|first2=S.|last3=Wilcox|first3=C. S.|date=1994-05-01|title=Molecular Torsion Balance for Weak Molecular Recognition Forces. Effects of "Tilted-T" Edge-to-Face Aromatic Interactions on Conformational Selection and Solid-State Structure|journal=Journal of the American Chemical Society|volume=116|issue=10|pages=4497–4498|doi=10.1021/ja00089a057|issn=0002-7863}}
27. ^{{Cite journal|last=Mati|first=Ioulia K.|last2=Cockroft|first2=Scott L.|date=2010-10-19|title=Molecular balances for quantifying non-covalent interactions|journal=Chemical Society Reviews|volume=39|issue=11|pages=4195–205|doi=10.1039/B822665M|pmid=20844782|issn=1460-4744}}
28. ^{{Cite journal|last=Yang|first=Lixu|last2=Adam|first2=Catherine|last3=Cockroft|first3=Scott L.|date=2015-08-19|title=Quantifying Solvophobic Effects in Nonpolar Cohesive Interactions|journal=Journal of the American Chemical Society|volume=137|issue=32|pages=10084–10087|doi=10.1021/jacs.5b05736|pmid=26159869|issn=0002-7863|hdl=20.500.11820/604343eb-04aa-4d90-82d2-0998898400d2}}
29. ^{{Cite journal|last=Li|first=Ping|last2=Zhao|first2=Chen|last3=Smith|first3=Mark D.|last4=Shimizu|first4=Ken D.|date=2013-06-07|title=Comprehensive Experimental Study of N-Heterocyclic π-Stacking Interactions of Neutral and Cationic Pyridines|journal=The Journal of Organic Chemistry|volume=78|issue=11|pages=5303–5313|doi=10.1021/jo400370e|pmid=23675885|issn=0022-3263}}
30. ^{{Cite journal|last=Hwang|first=Jungwun|last2=Li|first2=Ping|last3=Smith|first3=Mark D.|last4=Shimizu|first4=Ken D.|date=2016-07-04|title=Distance-Dependent Attractive and Repulsive Interactions of Bulky Alkyl Groups|journal=Angewandte Chemie International Edition|volume=55|issue=28|pages=8086–8089|doi=10.1002/anie.201602752|pmid=27159670|issn=1521-3773}}
31. ^{{cite journal |last1=Chen |first1=C. W. |last2=Whitlock |first2=H. W. |title=Molecular tweezers: a simple model of bifunctional intercalation |journal=Journal of the American Chemical Society |date=July 1978 |volume=100 |issue=15 |pages=4921–4922 |doi=10.1021/ja00483a063}}
32. ^{{cite journal |last1=Klärner |first1=Frank-Gerrit |last2=Kahlert |first2=Björn |title=Molecular Tweezers and Clips as Synthetic Receptors. Molecular Recognition and Dynamics in Receptor−Substrate Complexes |journal=Accounts of Chemical Research |date=December 2003 |volume=36 |issue=12 |pages=919–932 |doi=10.1021/ar0200448|pmid=14674783 }}
33. ^{{cite journal |last1=Yurke |first1=Bernard |last2=Turberfield |first2=Andrew J. |last3=Mills |first3=Allen P. |last4=Simmel |first4=Friedrich C. |last5=Neumann |first5=Jennifer L. |title=A DNA-fuelled molecular machine made of DNA |journal=Nature |date=10 August 2000 |volume=406 |issue=6796 |pages=605–608 |doi=10.1038/35020524|pmid=10949296 }}
34. ^{{cite journal |vauthors=Cavalcanti A, Shirinzadeh B, Freitas Jr RA, Hogg T | title = Nanorobot architecture for medical target identification | year = 2008 | journal = Nanotechnology | volume = 19 | issue = 1 | pages = 015103(15pp) | doi = 10.1088/0957-4484/19/01/015103 | url=http://www.iop.org/EJ/abstract/0957-4484/19/1/015103 | bibcode=2008Nanot..19a5103C}}
35. ^{{cite journal |last1=Wu |first1=Di |last2=Sedgwick |first2=Adam C. |last3=Gunnlaugsson |first3=Thorfinnur |last4=Akkaya |first4=Engin U. |last5=Yoon |first5=Juyoung |last6=James |first6=Tony D. |title=Fluorescent chemosensors: the past, present and future |journal=Chemical Society Reviews |date=2017 |volume=46 |issue=23 |pages=7105–7123 |doi=10.1039/C7CS00240H|pmid=29019488 }}
36. ^{{cite journal |last1=Prasanna de Silva |first1=A. |last2=McClenaghan |first2=Nathan D. |title=Proof-of-Principle of Molecular-Scale Arithmetic |journal=Journal of the American Chemical Society |date=April 2000 |volume=122 |issue=16 |pages=3965–3966 |doi=10.1021/ja994080m}}
37. ^{{cite journal |last1=Magri |first1=David C. |last2=Brown |first2=Gareth J. |last3=McClean |first3=Gareth D. |last4=de Silva |first4=A. Prasanna |title=Communicating Chemical Congregation: A Molecular AND Logic Gate with Three Chemical Inputs as a "Lab-on-a-Molecule" Prototype |journal=Journal of the American Chemical Society |date=April 2006 |volume=128 |issue=15 |pages=4950–4951 |doi=10.1021/ja058295+|pmid=16608318 }}
38. ^{{Cite journal|last=Lewandowski|first=Bartosz|last2=De Bo|first2=Guillaume|last3=Ward|first3=John W.|last4=Papmeyer|first4=Marcus|last5=Kuschel|first5=Sonja|last6=Aldegunde|first6=María J.|last7=Gramlich|first7=Philipp M. E.|last8=Heckmann|first8=Dominik|last9=Goldup|first9=Stephen M.|date=2013-01-11|title=Sequence-Specific Peptide Synthesis by an Artificial Small-Molecule Machine|url=http://science.sciencemag.org/content/339/6116/189|journal=Science|volume=339|issue=6116|pages=189–193|doi=10.1126/science.1229753|issn=0036-8075|pmid=23307739|via=|bibcode=2013Sci...339..189L}}
39. ^{{Cite journal|last=De Bo|first=Guillaume|last2=Kuschel|first2=Sonja|last3=Leigh|first3=David A.|last4=Lewandowski|first4=Bartosz|last5=Papmeyer|first5=Marcus|last6=Ward|first6=John W.|date=2014-04-16|title=Efficient Assembly of Threaded Molecular Machines for Sequence-Specific Synthesis|journal=Journal of the American Chemical Society|volume=136|issue=15|pages=5811–5814|doi=10.1021/ja5022415|pmid=24678971|issn=0002-7863}}
40. ^{{Cite journal|last=De Bo|first=Guillaume|last2=Gall|first2=Malcolm A. Y.|last3=Kitching|first3=Matthew O.|last4=Kuschel|first4=Sonja|last5=Leigh|first5=David A.|last6=Tetlow|first6=Daniel J.|last7=Ward|first7=John W.|date=2017-08-09|title=Sequence-Specific β-Peptide Synthesis by a Rotaxane-Based Molecular Machine|journal=Journal of the American Chemical Society|volume=139|issue=31|pages=10875–10879|doi=10.1021/jacs.7b05850|pmid=28723130|issn=0002-7863|url=http://dro.dur.ac.uk/22931/1/22931.pdf}}
41. ^{{Cite journal|last=Kassem|first=Salma|last2=Lee|first2=Alan T. L.|last3=Leigh|first3=David A.|last4=Marcos|first4=Vanesa|last5=Palmer|first5=Leoni I.|last6=Pisano|first6=Simone|date=September 2017|title=Stereodivergent synthesis with a programmable molecular machine|journal=Nature|volume=549|issue=7672|pages=374–378|doi=10.1038/nature23677|pmid=28933436|issn=1476-4687|bibcode=2017Natur.549..374K|url=https://www.research.manchester.ac.uk/portal/en/publications/stereodivergent-synthesis-with-a-programmable-molecular-machine(dd2b7aed-b6ff-455a-8fb7-e31851cea5e6).html}}
42. ^{{Cite journal|last=De Bo|first=Guillaume|last2=Gall|first2=Malcolm A. Y.|last3=Kuschel|first3=Sonja|last4=Winter|first4=Julien De|last5=Gerbaux|first5=Pascal|last6=Leigh|first6=David A.|date=2018-04-02|title=An artificial molecular machine that builds an asymmetric catalyst|journal=Nature Nanotechnology|volume=13|issue=5|pages=381–385|doi=10.1038/s41565-018-0105-3|pmid=29610529|issn=1748-3395|bibcode=2018NatNa..13..381D}}
43. ^Org. Chem. Front. 2017, 4 (2), 224-228 https://doi.org/10.1039/c6qo00653a
44. ^{{Cite journal|date=1991|title=Linear dichroism and trans → cis photo-isomerization studies of azobenzene molecules in oriented polyethylene matrix.|url=|journal=Eur. Polym. J.|volume=27|pages=41–43|via=|doi=10.1016/0014-3057(91)90123-6 | last1 = Uznanski | first1 = P. | last2 = Kryszewski | first2 = M. | last3 = Thulstrup | first3 = E.W.}}
45. ^{{Cite journal|date=2017|title=Design and synthesis of Ʌ-shaped photoswitchable compounds employing Tröger's base scaffold.|journal=Synthesis|volume=49 | issue = 6 |pages=1214–1222|via=|doi=10.1055/s-0036-1588913|last1=Kazem-Rostami|first1=Masoud}}
46. ^{{Cite book|title=Biochemistry|last=Donald|first=Voet|date=2011|publisher=John Wiley & Sons|others=Voet, Judith G.|isbn=9780470570951|edition= 4th|location=Hoboken, NJ|oclc=690489261}}
47. ^{{Cite journal|last=Kinbara|first=Kazushi|last2=Aida|first2=Takuzo|date=2005-04-01|title=Toward Intelligent Molecular Machines: Directed Motions of Biological and Artificial Molecules and Assemblies|journal=Chemical Reviews|volume=105|issue=4|pages=1377–1400|doi=10.1021/cr030071r|pmid=15826015|issn=0009-2665}}
48. ^{{cite book |vauthors=Bu Z, Callaway DJ |chapter=Proteins MOVE! Protein dynamics and long-range allostery in cell signaling |volume=83 |issue= |pages=163–221 |year=2011 |pmid=21570668 |doi=10.1016/B978-0-12-381262-9.00005-7 |chapter-url=http://linkinghub.elsevier.com/retrieve/pii/B978-0-12-381262-9.00005-7 |series=Advances in Protein Chemistry and Structural Biology |isbn=9780123812629|title=Protein Structure and Diseases }}
49. ^{{Cite journal | doi = 10.1002/ange.200905200| title = Targeted Optimization of a Protein Nanomachine for Operation in Biohybrid Devices| journal = Angewandte Chemie| volume = 122| issue = 2| pages = 322–326| year = 2010| last1 = Amrute-Nayak | first1 = M. | last2 = Diensthuber | first2 = R. P. | last3 = Steffen | first3 = W. | last4 = Kathmann | first4 = D. | last5 = Hartmann | first5 = F. K. | last6 = Fedorov | first6 = R. | last7 = Urbanke | first7 = C. | last8 = Manstein | first8 = D. J. | last9 = Brenner | first9 = B. | last10 = Tsiavaliaris | first10 = G. }}
50. ^{{Cite journal | doi = 10.1080/10611860600612862| title = Nanorobot: A versatile tool in nanomedicine| journal = Journal of Drug Targeting| volume = 14| issue = 2| pages = 63–7| year = 2006| last1 = Patel | first1 = G. M. | last2 = Patel | first2 = G. C. | last3 = Patel | first3 = R. B. | last4 = Patel | first4 = J. K. | last5 = Patel | first5 = M. | pmid=16608733}}
51. ^{{Cite journal | doi = 10.1002/anie.201100115| title = Micromachine-Enabled Capture and Isolation of Cancer Cells in Complex Media| journal = Angewandte Chemie International Edition| volume = 50| issue = 18| pages = 4161–4164| year = 2011| last1 = Balasubramanian | first1 = S. | last2 = Kagan | first2 = D. | last3 = Jack Hu | first3 = C. M. | last4 = Campuzano | first4 = S. | last5 = Lobo-Castañon | first5 = M. J. | last6 = Lim | first6 = N. | last7 = Kang | first7 = D. Y. | last8 = Zimmerman | first8 = M. | last9 = Zhang | first9 = L. | last10 = Wang | first10 = J. | pmid=21472835 | pmc=3119711}}
52. ^{{cite journal |journal=Journal of Computational and Theoretical Nanoscience |volume=2 |pages=471 |date=2005 |title=Current Status of Nanomedicine and Medical Nanorobotics |first=Robert A., Jr. |last=Freitas|doi=10.1166/jctn.2005.001 |first2=Ilkka |last2=Havukkala |url=http://www.nanomedicine.com/Papers/NMRevMar05.pdf |issue=4|bibcode=2005JCTN....2..471K }}
53. ^Nanofactory Collaboration
54. ^{{cite journal|author1=Tabacchi, G. |author2=Silvi, S. |author3=Venturi, M. |author4=Credi, A. |author5=Fois, E. |journal=ChemPhysChem |year=2016|doi=10.1002/cphc.201501160|pmid=26918775 |title=Dethreading of a Photoactive Azobenzene-Containing Molecular Axle from a Crown Ether Ring: A Computational Investigation |volume=17 |issue=12 |pages=1913–1919}}
55. ^{{Cite journal|last=Coskun|first=Ali|last2=Banaszak|first2=Michal|last3=Astumian|first3=R. Dean|last4=Stoddart|first4=J. Fraser|last5=Grzybowski|first5=Bartosz A.|date=2011-12-05|title=Great expectations: can artificial molecular machines deliver on their promise?|url=http://xlink.rsc.org/?DOI=C1CS15262A|journal=Chem. Soc. Rev.|volume=41|issue=1|pages=19–30|doi=10.1039/c1cs15262a|pmid=22116531|issn=1460-4744}}
56. ^[https://www.ecnmag.com/news/2018/06/ratchet-pressure-molecular-machine-exploits-motion-single-direction "Ratchet Up The Pressure: Molecular Machine Exploits Motion In A Single Direction"] ECN Magazine, June 22, 2018