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Rotaxane

A rotaxane is a mechanically interlocked molecular architecture consisting of a dumbbell-shaped molecule, featuring a linear axle threaded through one or more macrocyclic rings, with the rings prevented from dissociating by bulky stopper groups at each end of the axle. This structure relies on mechanical bonds rather than covalent linkages, enabling relative motion between components, such as shuttling of the ring along the axle. Rotaxanes are classified by the number of interlocked units, with rotaxanes denoting one ring and one axle, while higher-order variants like polyrotaxanes involve multiple rings on extended polymer chains. The concept of rotaxanes emerged in the 1960s, with the first synthesis reported in 1967 by Gottfried Schill and Hubertus Zollenkopf, who constructed a threaded onto a linear aromatic moiety capped by bulky ends through a multistep covalent approach yielding low quantities. Early efforts by researchers like Edwin Wasserman and T. Harrison also explored statistical threading methods, but yields remained below 1% due to the challenges of precise interlock formation. Breakthroughs in template-directed synthesis came in the 1980s and 1990s; Jean-Pierre Sauvage demonstrated copper(I)-mediated assembly of catenanes in 1983, paving the way for rotaxane construction via metal-ligand coordination. In 1991, J. advanced the field by developing rotaxanes using π-donor-acceptor interactions between crown ethers and tetracationic cyclophanes, enabling higher yields and functional designs. Their contributions to mechanically interlocked molecules were recognized with the 2016 , shared with Bernard L. Feringa for work on . Rotaxanes have found applications in for constructing artificial , such as shuttles, elevators, and muscles that respond to stimuli like , light, or changes. In , polyrotaxanes enable tough, self-healing gels and responsive polymers due to their sliding ring dynamics. Biologically, cyclodextrin-based rotaxanes serve as vehicles, leveraging their and ability to encapsulate guests for controlled release. As of 2025, ongoing research has advanced rotaxane synthesis through methods like boronic ester templating and expanded applications to stretchable MXene films for and enantioselective catalysis for chiral recognition.

Definition and Structure

Molecular Architecture

A rotaxane is a mechanically interlocked consisting of at least one component threaded by a linear dumbbell-shaped component, with bulky end-groups known as stoppers that prevent unthreading of the . This interlocking creates a non-covalent , where the components are topologically constrained without direct chemical linkage between the ring and the thread. The resembles a encircling an , with the stoppers acting as barriers larger than the 's internal , ensuring kinetic stability under typical conditions. The fundamental components of a rotaxane include the , the , and the stoppers. The is a linear featuring an extended region suitable for threading, flanked by voluminous termini that serve as stoppers, such as dendritic groups or triisopropylsilyl moieties. The is a cyclic , often composed of aromatic or heteroatomic units, that encircles the portion of the . These elements together form a structure where the is free to translate or rotate along the but cannot escape due to the steric bulk of the stoppers. In terms of basic topology, a rotaxane comprises one interlocked with one , establishing the simplest nontrivial linkage in this class. Higher-order variants, such as rotaxanes, incorporate multiple threaded onto a single , expanding the architectural complexity while maintaining the core principle of . This topological description underscores the rotaxane's distinction from covalently bonded systems, emphasizing reliance on spatial constraints for integrity.

Types and Variations

Rotaxanes are classified based on the number of interlocked components, with rotaxanes denoting structures comprising n total parts, including at least one linear threaded by one or more , secured by bulky stoppers to prevent dethreading. The simplest form, the rotaxane, consists of a single encircling a dumbbell-shaped with two stoppers at its ends, allowing controlled motion of the along the while maintaining . Rotaxanes extend this architecture to include two on a single or a branched structure with multiple axles, introducing greater complexity in dynamics and potential for cooperative interactions between wheels. Pseudorotaxanes represent non-covalent variants of rotaxanes lacking bulky end-groups, permitting reversible dissociation of the from the under appropriate conditions, such as changes in or temperature. These assemblies are valuable for studying threading equilibria and transient bonds, often serving as precursors to stable rotaxanes. Polyrotaxanes feature polymeric s threaded by numerous , forming extended structures with high degrees of interlockage. Cyclodextrin-based polyrotaxanes, pioneered with α-cyclodextrin wheels on threads capped by bulky groups as first reported by Harada, , and Kamachi, exemplify this class, offering biocompatibility and solubility for applications in . These structures can accommodate dozens of per chain, enhancing properties like elasticity through sliding motions. Beyond basic configurations, oriented rotaxanes incorporate directional threading, where the encircles the in a specific due to asymmetric interactions, such as the "endo-alkyl rule" in wheels with axles. Chiral rotaxanes derive stereogenic units from the mechanical bond itself, including planar chirality from asymmetric wheel placement or in threaded assemblies, enabling enantioselective recognition without traditional chiral centers. Metallorotaxanes integrate metal ions into the or , often via coordination sites in phenanthroline or wheels, to confer activity or catalytic function while preserving the interlocked topology. Structural modifications further diversify rotaxanes by functionalizing components for targeted interactions. Threads can include recognition sites, such as units for charge-transfer complexation, while wheels like crown ethers facilitate ion binding or π-π stacking in tetracationic cyclophanes. Cyclodextrins, with their hydrophobic cavities, enable host-guest inclusion of hydrophobic guests on hydrophilic threads, expanding utility in supramolecular assemblies.

History and Development

Early Discoveries

The concept of mechanically interlocked molecules, including rotaxanes, emerged in the early 1960s as part of the nascent field of . In 1960, Edwin L. Wasserman at Bell Laboratories proposed the synthesis of a —a pair of interlocked rings—using a statistical cyclization approach during an acyloin condensation, marking the first claim of such a structure without direct structural proof but establishing the idea of non-covalent mechanical bonds in molecules. This work inspired further theoretical exploration, culminating in the 1961 paper by H. L. Frisch and E. Wasserman, which formalized by analyzing the topological isomers of cyclic molecules, including catenanes and rotaxanes, and predicting their unique stereochemical properties such as arising from interlocking. The first confirmed synthesis of a rotaxane occurred in 1967, when Ian T. Harrison and Shuyen Harrison reported a rotaxane formed by statistically threading a macrocyclic onto a dumbbell-shaped capped with trityl groups, yielding about 6% of the interlocked product after repeated threading-followed-by-capping reactions. Independently, Gottfried Schill and Hubertus Zollenkopf described a multistep covalent construction of a rotaxane in 1969, involving directed cyclization and deprotection to thread a onto an aromatic with bulky stoppers. These pioneering efforts demonstrated the feasibility of rotaxanes but were hampered by inefficient statistical or laborious covalent methods, resulting in yields below 10% and limited scalability due to the low probability of precise molecular entanglement without guiding interactions. A transformative advance arrived in 1983 with Jean-Pierre Sauvage's group at the , who synthesized the first templated using copper(I) ions to coordinate phenanthroline units, directing the double ring closure with 42% yield and proving the efficacy of metal templating for controlled interlocking. This strategy, which relied on reversible coordination bonds to preorganize components, directly influenced subsequent rotaxane syntheses by addressing the threading inefficiency of earlier approaches. In the ensuing years, pioneers such as advanced pseudorotaxane complexes with cyclodextrins in the early 1990s, while David Leigh contributed early experimental catenanes and rotaxanes through hydrogen-bonding templates in the early 1990s.

Key Milestones and Nobel Recognition

In the , J. Fraser Stoddart's group achieved a breakthrough in rotaxane by exploiting π-donor-acceptor interactions between electron-rich dumbbell components and the electron-poor cyclobis(paraquat-p-phenylene) (CBPQT⁴⁺) , enabling high-yield template-directed assembly of rotaxanes with efficiencies up to 70%. This approach, first demonstrated in the early , transformed rotaxanes from low-yield curiosities into accessible molecular entities, exemplified by the of a degenerate rotaxane acting as a molecular shuttle, where the CBPQT⁴⁺ ring dynamically translocates between two recognition sites at rates exceeding 1,000 times per second in solution. These developments laid the foundation for switchable systems, including the 1994 acid/base-controllable rotaxane with the ring preferentially occupying a station under neutral conditions. The 2000s saw further innovation with the introduction of active template synthesis by David A. Leigh's group in 2007, which integrated metal to simultaneously direct threading and stopper formation, yielding rotaxanes in up to 90% without relying solely on passive non-covalent templation. This Cu(I)-catalyzed azide-alkyne cycloaddition method, applied to bipyridine-based , enabled the rapid construction of functional rotaxanes and expanded to diverse topologies, including molecular shuttles with switchable dynamics. By the 2010s, these techniques fueled the expansion of rotaxanes into , such as Stoddart's 2015 artificial molecular pump that unidirectionally threads multiple CBPQT⁴⁺ rings onto a chain using redox-driven radical mechanisms, performing measurable mechanical work. The culmination of these efforts was recognized by the 2016 , awarded jointly to Jean-Pierre Sauvage, J. , and Bernard L. Feringa for the design and synthesis of , with rotaxanes central to Stoddart's and Sauvage's contributions in creating controllable shuttles, muscles, and lifts based on interlocked architectures. Recent progress through 2025 has shifted focus toward applications, including polyrotaxanes for ; for instance, aminated cyclodextrin-based polyrotaxanes have been developed as versatile carriers for nucleic acids and proteins, offering pH-responsive release and in biomedical contexts. In 2025, publications highlighted amphoteric rotaxanes incorporating chalcogen- and halogen-bonding motifs for selective sensing, demonstrating anion/cation recognition via switchable non-covalent interactions in a single host system. This evolution has driven a transition from fundamental curiosity to practical utility, evidenced by over 10,000 peer-reviewed publications on rotaxanes and mechanically interlocked molecules by 2025.

Properties

Mechanical and Dynamic Behavior

Rotaxanes exhibit distinctive mechanical behaviors arising from the mechanical interlock between the macrocyclic and the linear , enabling controlled molecular motions without dissociation. The primary dynamics include translational shuttling, where the slides along the between recognition sites, and circumrotational motion, involving rotation of the wheel around the 's axis. These movements are governed by non-covalent interactions, such as π-π stacking and hydrogen bonding, which define the energy landscape and allow for precise control over the system's co-conformation. The energy barriers for shuttling motion typically range from 10 to 20 kcal/mol, depending on the specific recognition sites and environmental conditions, enabling thermally activated transitions at ambient temperatures. For instance, in bistable rotaxanes featuring tetrathiafulvalene (TTF) and 1,5-dioxynaphthalene (DNP) stations with a tetracationic wheel, the barrier for ring translation between stations is approximately 16 kcal/mol in , facilitating shuttling rates on the order of seconds. These barriers arise from the desolvation and disruption of stabilizing interactions during transit, with hydrogen bonding or π-π stacking at the stations lowering the ground-state energy relative to the . Directional control is achieved through differential affinities: electrostatic repulsion or steric hindrance can bias the wheel toward one station, creating a preferred co-conformation that can be modulated by external stimuli. Compared to their free components, rotaxanes display restricted due to the mechanical bond, which confines the wheel to the and prevents translational or rotational . This interlock enhances overall molecular stability by reducing loss upon association and shielding reactive sites from exposure, while still permitting internal essential for functional behavior.

Chemical Stability and Interactions

Rotaxanes exhibit notable , often resisting at elevated temperatures due to the interlock that prevents slippage of the from the . For instance, polyyne-based rotaxanes demonstrate remarkable ambient , with structures revealing close interchain interactions that enhance endurance compared to their non-interlocked counterparts. Similarly, certain metal-organic rotaxane frameworks show no up to 300°C via , underscoring their robustness under high heat. In squaraine rotaxanes, encapsulation within a shields the dye from nucleophilic attack and degradation, with free squaraine dyes beginning to decompose around 100°C while the rotaxane form remains stable above 250°C. Photochemical is also pronounced in these interlocked structures, conferring resistance to ; squaraine rotaxanes display up to 20 times greater photostability than benchmark dyes like Cy5. The chemical stability of rotaxanes is underpinned by non-covalent interactions that stabilize the host-guest between the (wheel) and the axle (thread). In donor-acceptor rotaxanes featuring cyclobis(paraquat-p-phenylene) (CBPQT⁴⁺) rings threaded onto electron-rich axles, such as those with 1,5-dioxynaphthalene units, strong charge-transfer interactions arise from π-π stacking and electrostatic forces, producing characteristic purple coloration from the . These interactions, including hydrogen bonding and hydrophobic effects, contribute to the overall binding affinity, often exceeding 10⁵ M⁻¹ in solution, which prevents unintended dissociation under ambient conditions. Hydrophobic encapsulation in cyclodextrin-based rotaxanes further bolsters stability in aqueous environments by excluding water from the interlocked core. Rotaxanes respond to environmental stimuli like and , which can modulate their stability without breaking the mechanical bond. Redox-active rotaxanes, such as those with tetrathiafulvalene units, undergo reversible that alters co-conformational states, enhancing or diminishing binding energies by up to several orders of magnitude. In pH-responsive systems, of axle recognition sites can trigger macrocycle translocation, temporarily weakening non-covalent interactions while preserving the interlocked . Compared to purely covalent analogs, rotaxanes offer superior resistance to , as the mechanical bond maintains integrity even when chemical linkages on the or are cleaved, enabling orthogonal reactivity. This feature allows selective modifications on either component without disrupting the overall structure, a key advantage in complex molecular designs.

Synthesis

Template-Directed Strategies

Template-directed strategies represent a of rotaxane , leveraging non-covalent interactions to pre-organize the linear and macrocyclic into a threaded pseudorotaxane prior to covalent interlocking. These interactions—such as metal-ligand coordination, hydrogen bonding, hydrophobic effects, and π-donor/π-acceptor charge-transfer forces—provide the directional necessary to achieve efficient , mimicking biological processes at the molecular level. By positioning the components in close proximity and correct , templating minimizes entropic penalties and enhances the probability of successful interlock formation, contrasting sharply with undirected statistical approaches that yield interlocked products in less than 1% efficiency. Among the most prominent templates are transition metal ions, particularly Cu(I) coordinated to bidentate phenanthroline ligands, which form stable octahedral or tetrahedral complexes that enforce threading of the macrocycle onto the axle precursor. This metal coordination template, pioneered by Sauvage and colleagues, enables the of rotaxanes with yields often exceeding 70%, as demonstrated in early examples where the pseudorotaxane undergoes end-capping to secure the interlocked . Similarly, π-donor/π-acceptor interactions, exemplified by electron-rich tetrathiafulvalene (TTF) units on the pairing with electron-poor cyclobis(paraquat-p-phenylene) (CBPQT^{4+}) macrocycles, drive spontaneous encirclement through charge-transfer stabilization, achieving up to 90% yields in directed assemblies developed by Stoddart's group. Hydrogen bonding templates, such as or arrays, further contribute by forming multiple [N-H···O=C] motifs that align components, while hydrophobic effects, notably in cyclodextrin-based systems introduced by Ogino, exploit solvophobic inclusion to alkyl chains with selectivities approaching quantitative levels under aqueous conditions. The general scheme of template-directed rotaxane formation begins with the of a pseudorotaxane, where non-covalent binding pre-threads the onto the , followed by a covalent —such as stoppering with bulky groups or macrocyclization—to irreversibly interlock the components and prevent dethreading. This ensures high selectivity by discriminating against non-templated pathways, with overall yields typically in the 70-95% range depending on the strength and conditions, thereby establishing a scalable route to complex mechanically interlocked molecules (MIMs). These principles form the basis for advanced variants, including active strategies that integrate into the templating process.

Capping and Slipping Methods

The capping method for rotaxane synthesis involves the initial formation of a pseudorotaxane, where a macrocyclic threads onto a linear component through non-covalent interactions, followed by the covalent attachment of bulky stopper groups to the axle ends to kinetically trap the interlocked structure and prevent dissociation. This approach relies on template-directed pre-organization to facilitate threading, typically under mild conditions that preserve the pseudorotaxane assembly, and is particularly effective for systems where the axle features reactive end-groups compatible with high-yielding ligation reactions. Common capping strategies include (CuAAC ), which allows efficient installation of triazole-based stoppers, and dendrimer growth from peripheral functional groups on the axle to create sterically demanding termini. Yields for capping reactions often range from 50-80%, benefiting from the orthogonality of click reactions that proceed in aqueous or organic media without disrupting the wheel-axle interactions. For instance, Stoddart and coworkers demonstrated an early capping approach using bipyridinium-based axles threaded with wheels, where bulky aromatic stoppers were attached via or coupling reactions to yield rotaxanes in moderate to good efficiency, highlighting the method's versatility for donor-acceptor systems. In contrast, the slipping method operates under thermodynamic , wherein a pre-stoppered dumbbell-shaped with size-complementary bulky end-groups is combined with the , and the mixture is heated to overcome the energy barrier for the to slip over one stopper onto the . This technique requires precise matching of stopper size to the cavity—sufficiently large to block dethreading at ambient temperatures but small enough to allow slippage at elevated conditions—eliminating the need for additional or reactive end-groups on the . Slipping typically demands high temperatures of 80-150°C to achieve , depending on the system, and is advantageous for producing rotaxanes without covalent modifications post-assembly, though yields can vary based on the for threading. A classic example is the synthesis of polyrotaxanes using α- or γ-cyclodextrin wheels on (PEG) threads capped with trityl or adamantyl stoppers, as pioneered by Harada and coworkers; heating the components in water or DMSO drives multiple wheels to slip onto the polymer , forming threaded structures with up to dozens of interlocked units per chain. Similarly, Stoddart's group applied slipping to crown ether-based systems with bipyridinium s terminated by tetraarylmethane stoppers, achieving rotaxanes in yields exceeding 70% upon heating in , underscoring the method's utility for precise over interlock . Both methods complement template-directed strategies by focusing on post-threading stabilization, with capping offering flexibility in stopper design for functional rotaxanes and slipping providing a reagent-free route ideal for polymeric or high-density interlocks.

Clipping and Snapping Approaches

The clipping approach to rotaxane involves the assembly of an open-chain precursor around a threaded via non-covalent templating interactions, followed by intramolecular cyclization to form the encircling . This method contrasts with strategies using preformed rings by enabling the construction of complex wheel components directly on the dumbbell-shaped thread. Pioneered by Sauvage in the for the synthesis of catenanes through copper(I)-templated ring closure, the technique was subsequently adapted for rotaxanes, allowing for the incorporation of diverse functional groups in the macrocycle. A prominent implementation of clipping utilizes ring-closing metathesis (RCM) to forge the from precursors threaded onto the , often stabilized by hydrogen-bonding or electrostatic interactions. For instance, ruthenium-catalyzed RCM with Grubbs' first-generation catalyst has been employed to generate ammonium-based rotaxanes, achieving yields of up to 73% under dilute conditions to favor cyclization over oligomerization. In cases involving sterically hindered ortho-substituted aryl groups on the thread, yields decrease to around 30%, highlighting the sensitivity to but also the method's versatility for tuning macrocycle size. Another effective clipping variant employs condensation, where dialdehyde and precursors assemble around dialkylammonium template sites on the axle before forming linkages. This dynamic covalent process, often conducted in with , facilitates thermodynamic and has produced rotaxanes in 70% yield, with the imines subsequently reduced to stable amines for kinetic trapping. The approach excels in , enabling the synthesis of oligorotaxanes with up to 11 interlocked rings through iterative templating. One advantage of clipping is its capacity to create intricate macrocycles that would be challenging to preform independently, though it requires precise of reaction conditions to minimize side products like non-interlocked cycles. The snapping method complements clipping by leveraging reversible covalent connections to temporarily "snap" a nearly complete macrocycle onto the thread, followed by end-capping to secure the interlocked structure. This strategy is particularly suited for dynamic combinatorial libraries, where equilibrium drives selective formation of the rotaxane. A key example involves thiol-disulfide interchange, wherein a dumbbell with a central linkage reacts with thiols in the presence of a catalyst like benzenethiol, allowing the macrocycle to form via reversible bond exchange around ammonium templating sites. Optimized conditions, including temperature and concentration adjustments, yield rotaxanes up to 90% and rotaxanes with multiple wheels. The reversibility of bonds enables error correction in complex mixtures, making snapping ideal for generating libraries of interlocked species with minimal purification needs.

Active Template Methodology

The active template methodology represents a catalytic approach to rotaxane , where a metal serves dual roles as a directing and a catalyst for formation to achieve mechanical interlocking. Introduced by and coworkers in 2006, this strategy employs transition metals such as Cu(I) that coordinate to ligands within a , positioning axle precursors for efficient ring closure while accelerating the reaction. Unlike passive templating methods, which rely on non-covalent interactions for preorganization, active templating integrates bond-forming directly into the assembly process, enabling traceless removal of the template post-synthesis. In the mechanism, the metal center—often Cu(I) bound to a phenanthroline or unit in the —facilitates threading of the linear precursor through the ring cavity via coordination to reactive end groups, such as terminal alkynes or azides. This positions the components for catalyzed cyclization to form bulky stoppers; for instance, in Glaser-Hay coupling, Cu(I) promotes oxidative homocoupling of alkynes to generate rigid diyne stoppers, effectively trapping the . Demetallation, typically via ligand exchange with EDTA or acid treatment, liberates the free rotaxane without disrupting the interlocked structure. This process ensures high selectivity for the threaded product, as the metal-directed geometry suppresses non-interlocked side reactions. Key advantages include exceptional yields exceeding 70%—with examples reaching 82% using only 20 mol% —and , as the substoichiometric metal loading minimizes purification challenges compared to stoichiometric templates. The also supports directional , allowing precise over axle and enabling topologies beyond simple rotaxanes. Notable applications in the 2010s include the synthesis of rotaxane-based molecular knots, such as the 2011 active-metal-templated constructed via stepwise Cu(I)-catalyzed azide-alkyne cycloadditions on a phenanthroline-derived building block, achieving 64% yield for the interlocked product. More recent extensions in 2025 have incorporated chalcogen-bonding motifs, using Cu(I)-catalyzed azide-alkyne cycloaddition to assemble rotaxanes with tellurium- and selenium-containing stoppers for amphoteric anion/cation recognition, demonstrating yields up to 75% and enhanced binding affinities.

Applications

Molecular Machines and Switches

Rotaxanes play a central role in artificial and switches by enabling controlled, stimulus-responsive mechanical motions at the nanoscale, mimicking biological systems like or . Their interlocked architecture allows the to shuttle along the or rotate relative to it, converting chemical, , or light energy into directed movement for functions such as information processing and transport. The foundational work in this area, recognized by the 2016 Nobel Prize in Chemistry awarded to Jean-Pierre Sauvage, Sir J. Fraser Stoddart, and Bernard L. Feringa, established rotaxanes and related catenanes as key building blocks for these devices through reliable synthesis and actuation strategies. Bistable rotaxanes function as molecular shuttles and switches, where the reversibly translocates between two distinct stations on the dumbbell-shaped in response to external inputs, enabling states for or elements. A seminal example is the redox-active rotaxane developed by Stoddart's group, featuring a tetrathiafulvalene (TTF) unit as one station and a 1,5-dioxynaphthalene (DNP) as the other, encircled by a tetracationic cyclobis(paraquat-para-phenylene) (CBPQT⁴⁺) ring. In the reduced state, the ring prefers the electron-rich TTF due to donor-acceptor interactions; oxidation of TTF to its dication repels the ring to the DNP station, achieving over 90% positional control and supporting operations with . Shuttling dynamics in such systems occur on the to timescale, as observed in laser-pulse-induced experiments, allowing rapid switching for potential electronic applications. Rotaxane-based motors and pumps harness rectified by energy inputs to perform directional work, such as threading or unthreading components. In 2017, David Leigh's group introduced a chemically fueled linear molecular using a rotaxane with blocking groups and a fuel-responsive station; pulses of transiently block reverse motion via an information ratchet, achieving unidirectional loading of up to 1.9 macrocycles onto the axle per fuel aliquot at . Building on this, their 2021 autonomous employs catalysis in an active template rotaxane synthesis cycle, where Fmoc-Cl fuel drives continuous, directional threading of macrocycles from solution onto the axle without manual intervention, pumping up to three rings with >95% efficiency over multiple turnovers. Integration of rotaxanes into catenane-based machines expands functionality, combining linear shuttling with rotary motions like circumrotation (ring orbiting the axle) or pirouetting (tilting). For instance, catenane-rotaxane hybrids enable controlled 360° rotations powered by or chemical fuels, as in Leigh's pulsed-fuel rotary motor where steric blocking and affinity changes drive full unidirectional turns. Feringa's light-driven rotary , though primarily alkene-based, have influenced interlocked designs by demonstrating autonomous, repetitive 360° rotations with quantum yields up to 0.2, inspiring hybrid rotaxane systems for enhanced directionality. These devices exhibit energy efficiencies where chemical fuels or visible light input yields mechanical output with minimal waste, such as 10-20 kJ/ per cycle in Leigh's pumps, underscoring their potential for nanoscale actuation.

Dyes, Sensors, and Detection

Rotaxanes have emerged as promising platforms for developing ultrastable fluorescent dyes, particularly through the encapsulation of squaraine s within macrocyclic hosts, which significantly enhances their photostability compared to free dyes. In the work of Bradley D. Smith and colleagues, squaraine rotaxanes exhibit half-lives approximately 20 times longer than those of Cy5 dyes under similar imaging conditions, attributed to the mechanical interlock that shields the from nucleophilic attack and aggregation. This enhanced stability enables prolonged fluorescence without significant degradation, making these dyes suitable for demanding applications such as live-cell bioimaging, where they demonstrate low and clear visualization of bacterial structures in healthy cells. For instance, deep-red emitting squaraine rotaxanes have been successfully applied in intravital of nude mice, achieving signal intensities over 100 times above for detection of inoculations. In sensing applications, rotaxanes leverage their dynamic threading interactions for selective detection of explosives through mechanisms. A notable example is the cucurbituril (CB)-based rotaxane featuring a thread, which operates on solid substrates to detect trace vapors of nitroaromatic and aliphatic explosives like , , and PETN. The mechanism involves the intercalation of explosive molecules into the CB cavity, disrupting the threaded 's via and confinement effects, resulting in reversible that allows regeneration by simple washing; this thread-wheel dynamic provides between nitrate-based threats and benign vapors. The mechanical bond in such rotaxanes inherently prevents aggregation-induced (AIQ) of the , ensuring reliable signal output even in complex environments. Recent advancements in sensing utilize - and halogen-bonding rotaxanes for selective of anions and cations, exploiting amphoteric interactions for potential optical detection. In 2025 research by and coworkers, rotaxanes incorporating or iodine donors within the demonstrate high-affinity binding to halides (Cl⁻ > Br⁻ > I⁻) and soft metals like Ag⁺ (association constants >10⁵ M⁻¹), where the σ-hole interactions facilitate shuttling and positional changes detectable via NMR titrations; these systems highlight the role of the interlocked structure in enhancing selectivity for ion-pair in aqueous media. The of rotaxanes, as discussed in their , further supports their longevity in sensing environments requiring repeated ion exposures. Rotaxanes also function as molecular logic gates by integrating pH- and redox-responsive shuttling for information processing. A tristable rotaxane with a dibenzo-24-crown-8 and a bearing , bipyridinium, and triazolium stations operates as an , where macrocycle translocation to the neutral station occurs only upon simultaneous ( stimulus) and ( stimulus) of the charged sites, yielding a distinct output . Conversely, it behaves as an when either stimulus alone repositions the macrocycle to intermediate stations, enabling multiple binary outputs; this orthogonal control stems from the precise energy barriers imposed by the mechanical bond, allowing reversible switching without dissociation.

Biomedical and Nanomaterials

-based polyrotaxanes have gained prominence in systems due to their and ability to leverage the sliding motion of rings along polymeric axles for controlled release. In these structures, the rings act as mobile carriers that can encapsulate and transport therapeutic agents, releasing them in response to environmental stimuli such as or light, thereby minimizing premature drug leakage and enhancing targeted efficacy. For instance, α- polyrotaxanes integrated into mesoporous silica nanoparticles function as nanovalves for enzyme-responsive delivery in cancer cells, achieving near-zero premature release while enabling precise activation by nitroreductase enzymes. Recent 2025 advances highlight β- polyrotaxanes as theranostic platforms, combining delivery with photothermal therapy to achieve complete tumor regression in models. Zinc-dipicolylamine (Zn-DPA) rotaxanes serve as targeting agents in biomedical and by selectively to anionic phospholipids on bacterial or apoptotic cell membranes. These multivalent Zn-DPA complexes, often incorporated into liposomes or fluorescent probes, exhibit high affinity for negatively charged surfaces like those on dead cancer cells or pathogens, enabling selective and detection without affecting healthy zwitterionic membranes. A microwave-assisted synthesis of squaraine rotaxane probes with Zn-DPA ligands has demonstrated effective bacterial , highlighting their potential for diagnostics. Zn-DPA-coated liposomes further enhance this targeting, promoting of and selective uptake in apoptotic cells post-chemotherapy. In nanomaterials, rotaxane dendrimers offer promise for gene delivery through their stimuli-responsive architecture, where mechanical interlocking allows reversible size modulation for controlled nucleic acid encapsulation and release. Dual-responsive rotaxane-branched dendrimers up to the third generation, featuring pillararene wheels, contract from 4.51 nm to 2.75 nm upon anion or solvent triggers, facilitating efficient DNA complexation and cellular uptake. Additionally, interlocked polyrotaxane structures enable self-healing polymers by combining dynamic covalent bonds with ring sliding, which dissipates stress and promotes rapid reformation of cross-links. Cross-linked polyrotaxane hydrogels with boronate linkages, for example, heal scratches in semi-dry states via enhanced molecular mobility, supporting applications in durable biomedical coatings. For in , bistable rotaxanes utilize positional states of the along the axle to encode information, achieving densities up to 10¹¹ bits/cm² in molecular devices. In these thread-wheel systems, voltage or stimuli shuttle the wheel between stations, toggling resistance states for read/write operations, as demonstrated in 160-kbit crossbar arrays with switching times below 60 . Recent developments in 2025 emphasize rotaxanes' expanded medicinal roles, including light-responsive systems for reversible drug release and Gd³⁺-modified variants for enhanced MRI contrast with threefold relaxivity improvements, underscoring their versatility in targeted therapies.

Nomenclature and Characterization

Naming Conventions

The of rotaxanes has evolved significantly since the term was first coined in 1961 by Frisch and Wasserman, derived from the Latin words rota (wheel) and (axle) to describe mechanically interlocked structures featuring a ring threaded onto a linear with bulky stoppers. In the and , early syntheses by researchers such as Harrison, Schill, and Ogino relied on descriptive naming, often specifying the components or synthesis method without standardized prefixes, such as "cyclodextrin-based rotaxane" for Ogino's 1981 inclusion complex or compound-specific identifiers in Schill's directional studies. This informal approach facilitated initial communication but lacked uniformity as the field expanded with contributions from Sauvage, , and Vögtle in the and 1990s, who began adopting numerical descriptors like rotaxane to indicate the number of interlocked components. By the early 2000s, Vögtle and colleagues proposed a more systematic framework, culminating in the IUPAC Recommendations of 2008, which established rigorous rules for clarity and precision in scientific literature. The IUPAC nomenclature centers on the root term "rotaxane," prefixed by brackets denoting the total number of components, such as rotaxane for a single macrocycle (wheel) threaded onto one dumbbell-shaped axle (threading component with two stoppers). The full name follows the format (locant prefix)-{[name of threading component(s)]-rotaxa-[name of macrocyclic component(s)]}, where is the overall multiplicity, and specify quantities of each component type, and locants indicate positional isomers (e.g., (1:1)-rotaxane for two axles sharing one wheel). Descriptors for components are included parenthetically or as substitutive names, such as 1,5-naphthyridine-based for a nitrogen-heterocyclic macrocycle or 3,5-dimethylbenzyl-stoppered for the axle's end groups, ensuring the name reflects the chemical identity while emphasizing the mechanical bond. For example, a simple rotaxane might be named as 1rotaxane, integrating the axle's threading segment and the wheel's structure. This system extends to pseudorotaxanes (lacking stoppers) and higher-order variants, promoting unambiguous classification across diverse structural motifs. In practice, many rotaxanes are referred to by common, descriptive names that highlight functional or synthetic features, facilitating concise discussion in research contexts. For instance, "benzylic amide rotaxane" denotes a rotaxane where the macrocycle incorporates groups on benzylic positions for hydrogen-bonding recognition, as pioneered in Stoddart's hydrogen-bonded systems. Similarly, "catenane precursor rotaxane" describes an intermediate rotaxane designed for ring-closing to form interlocked rings, common in templated syntheses. These informal labels, often appended with the prefix, coexist with IUPAC names but prioritize conceptual over exhaustive detail. Topological notation for rotaxanes builds on graphical representations introduced by Sauvage in the , depicting the interlocked architecture as a non-planar : a linear (filament) encircled by a ring, with stoppers visualized as enlarged termini to illustrate mechanical trapping. This schematic approach, akin to the Hopf link for catenanes, uses the rotaxane prefix to quantify components and extends to polyrotaxanes by denoting multiple wheels on a single (e.g., rotaxane for four wheels) or branched variants, aiding of complexity in . Such notations emphasize the topological and isomerism inherent in these structures, influencing naming by incorporating locants for wheel positions along the .

Analytical Techniques

Nuclear magnetic resonance (NMR) spectroscopy is a primary technique for characterizing rotaxane structures, particularly for determining the position and dynamics of the macrocyclic wheel along the . In bistable rotaxanes, for instance, ^1H NMR spectra reveal the preferential localization of the ring on specific recognition sites through distinct changes in proton signals associated with the axle and wheel components. Dynamic ^1H NMR further probes shuttling motions, as seen in degenerate rotaxanes where the tetracationic ring oscillates between hydroquinone units at rates exceeding 1000 s^{-1} in acetone-d_6 at , evidenced by coalescence of signals at elevated temperatures. In non-degenerate systems, variable-temperature NMR quantifies co-conformational populations, such as an 84:16 ratio favoring the over biphenol unit in acetonitrile-d_3. Two-dimensional NMR techniques like COSY and NOESY complement these analyses by mapping through-space interactions and confirming the threaded topology. Ultraviolet-visible (UV-Vis) detects charge-transfer (CT) interactions arising from donor-acceptor pairings between the , providing evidence of mechanical interlocking. In anthracene-containing rotaxanes with bipyridinium cyclophanes, two distinct CT bands emerge in the visible region, absent in non-interlocked model compounds, due to electronic perturbations from π-π stacking and hydrogen bonding. These bands, often appearing around 400-600 nm, intensify with stronger donor-acceptor complementarity, as in tetrathiafulvalene-crown ether systems, and are modulated by or stimuli that alter ring position. UV-Vis experiments thus monitor co-conformational changes, with band shifts or of confirming the interlocked architecture. Electrospray ionization mass spectrometry (ESI-MS), particularly high-resolution variants, verifies the presence of the mechanical bond by observing intact molecular s without fragmentation of the interlock. For crown ether-ammonium rotaxanes, HR-ESI-MS displays a dominant peak at m/z 1279 for the dicationic species after counterion loss, which is absent in equimolar mixtures of the free and , directly proving . Tandem MS/MS further supports this by showing sequential losses that preserve the threaded , distinguishing rotaxanes from non-interlocked precursors. X-ray crystallography provides definitive structural proof of rotaxane topology, resolving atomic positions and intercomponent interactions. In mechanically planar chiral rotaxanes, single-crystal X-ray diffraction reveals diastereoisomeric configurations, such as (d,R_{mp})- and (d,S_{mp})-forms, with precise Cahn-Ingold-Prelog assignments based on the clockwise or anticlockwise orientation of the macrocycle relative to the thread. Key metrics include short CH···N hydrogen bond distances (2.3-2.9 Å), confirming stabilizing non-covalent forces that maintain the interlocked geometry. Atomic force microscopy (AFM) is employed to visualize polyrotaxane architectures and assess threading density in supramolecular assemblies. Tapping-mode AFM images of hydroxypropyl-β-cyclodextrin/Pluronic polyrotaxanes deposited on mica substrates show globular aggregates with heights of 0.5-2 nm and diameters of 47-80 nm, where smaller particle sizes correlate with higher threading efficiencies (e.g., 11 cyclodextrin units per chain). This technique quantifies surface topology influenced by the density of threaded macrocycles, aiding in the evaluation of aggregation behavior and mechanical properties. Characterizing rotaxanes presents challenges, notably in distinguishing them from pseudorotaxanes, which lack end-capping and exhibit reversible dissociation. High-performance liquid chromatography (HPLC) addresses this by separating interlocked species based on retention times; for example, reverse-phase HPLC with methanol-water gradients resolves rotaxanes (e.g., retention ~15-20 min) from pseudorotaxane intermediates (~10-13 min) and byproducts, enabling yield assessments of 52-55% for pure rotaxanes after purification. Quantitative integration of HPLC peaks monitors reaction kinetics and confirms mechanical bond formation, though low yields in complex syntheses often require orthogonal techniques for validation.